Chapter 3. Antidepressants

 

 

INTRODUCTION

Antidepressants remain among the most common agents used in medicine. Despite a drop in

antidepressant prescriptions from 2003 to 2005, commonly attributed to the U.S. Food and Drug

Administration (FDA) black box warning on pediatric suicide risk, the number of antidepressant

prescriptions appears to be rebounding. The increasing availability of relatively inexpensive generic

antidepressants is likely to continue the trend toward more antidepressant prescriptions in the coming

years. In fact, 9 of the 10 most commonly prescribed antidepressants either are now generically

available or will be generically available by 2012.

Selective serotonin reuptake inhibitors (SSRIs) remain the dominant class of antidepressants. Their

ease of use, versatility, and safety have favored the SSRIs in both psychiatric and general medical

practice. Fluoxetine, citalopram, paroxetine, and sertraline are now available generically. Only

escitalopram currently has a patent extending to 2012. Although not all SSRIs are approved in all

anxiety disorders, the SSRIs have emerged as the first-line treatment for generalized anxiety disorder

(GAD), posttraumatic stress disorder (PTSD), panic disorder, and obsessive-compulsive disorder

(OCD). Most recently, escitalopram received an FDA-approved indication for GAD, but the

manufacturer did not receive approval for indications for panic and social anxiety. Despite this

nonapproval, the data supporting the use of escitalopram for the treatment of anxiety beyond GAD

appears substantial.

The serotonin-norepinephrine reuptake inhibitors (SNRIs) venlafaxine and duloxetine have also

become common first- or second-line agents and appear to be more useful than SSRIs in treating

neuropathic pain conditions. There has been the suggestion that the SNRIs may be more effective than

SSRIs in treating patients to remission, but the data are controversial and inconclusive in this regard.

Bupropion, which appears to have both noradrenergic and dopaminergic properties, became available

in a sustained-release formulation (Wellbutrin SR) in 1998 and a once-a-day XL preparation in 2004. In

addition, bupropion received an FDA indication for smoking cessation under the trade name Zyban.

Bupropion remains the most commonly added agent in the augmentation of serotonergic

antidepressants among partial responders. Findings from studies such as STAR*D (Sequenced

Treatment Alternatives for Resistant Depression; Trivedi et al. 2006) appear to support the

effectiveness of adding bupropion to an SSRI, but STAR*D also suggested that the much less

commonly used buspirone might be about as effective.

The use of other agents, such as mirtazapine, has flattened in their growth. Mirtazapine was

increasingly used in combination with other antidepressants for treatment-resistant depression and in

the treatment of depression in the elderly. It is now off patent. Nefazodone is more rarely used now,

since it has a black box warning of the risks of hepatoxicity, and is available on a more limited basis

(only available as a generic formulation). Along with bupropion, nefazodone and mirtazapine, unlike

virtually all other antidepressants, share a low proclivity for sexual side effects.

The FDA, following the lead of European regulatory agencies, recommended labeling changes for

SSRIs, venlafaxine, bupropion, nefazodone, and mirtazapine. The labels of these antidepressants now

advise close monitoring of pediatric patients for worsening depression and increased suicidality and

potentially will also soon warn about use in young adults (ages 18–25 years). This has been a

controversial recommendation. While there had been reports of increased suicidality associated with

Page 1 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterthe SSRIs since the early 1990s, it had been difficult to discern an antidepressant-induced effect on

suicidal thoughts versus a progression of the underlying illness. Suicidality is often vaguely defined in

clinical trials, and the risk of suicidality in these studies is difficult to interpret. In studies in children, no

suicides have actually been observed. While effective antidepressant therapy is associated with the

reduction of suicidal ideation in most patients, there may be a few patients who are at risk for

worsening suicidality. These include partial responders who become energized enough with

antidepressant therapy to act on suicidal impulses. Patients with a latent bipolar disorder may also

worsen while taking an antidepressant alone without a mood stabilizer. Finally, it has been argued that

some patients may develop akathisia while taking serotonergic antidepressants, and this could lead to

suicidal ideation and a worsening course. Close monitoring of patients while they are taking

antidepressants is never a bad idea. However, the FDA recommendation has dissuaded some patients

or families from pursuing a needed therapy.

A recent analysis of manufacturers’ databases regarding adults revealed an increase in suicidal-like

activity in patients 18–25 years of age taking active medication compared with placebo. Other adult

age groups did not show a similar increased risk while taking the medication. In fact, the elderly (>65

years of age) demonstrate a significant decrease in suicidal activity.

The older antidepressants, the tricyclic antidepressants (TCAs) and the monoamine oxidase inhibitors

(MAOIs), continue to have an important but more limited role in modern clinical practice. There are

patients who respond to these older antidepressants who do less well with SSRIs or newer drugs. The

debate continues as to whether the TCAs and other agents with complex pharmacologies, such as

venlafaxine, are more effective than the SSRIs for more serious forms of depression or for depression

in elderly persons. Still, the TCAs and MAOIs are now considered second-line, or more commonly third

line, agents because of their potential drug interactions, toxicity, and difficulty in titration. Although

drug costs for the TCAs and MAOIs are generally much less than for newer drugs, these drugs still tend

to be less cost-effective overall because of the need for more frequent visits, additional laboratory

tests, morbidity of overdoses, and more frequent discontinuation secondary to adverse effects.

A number of antidepressants have been under recent investigation. These include the first transdermal

antidepressant, transdermal selegiline (Emsam), which was approved for the treatment of major

depressive disorder in February 2006. Transdermal selegiline is an MAOI that is applied via a patch.

The absorption of the drug through the skin obviates to some extent a number of the problems

associated with traditional oral MAOIs, including tyramine-induced hypertension and reduced

bioavailability from first-pass effects. In the pivotal trials, transdermal selegiline also appears to have

lower rates of sexual side effects, weight gain, and orthostatic hypotension than was commonly seen

with oral MAOIs. Another SNRI currently being investigated in the treatment of fibromyalgia in the

United States is milnacipran. Milnacipran has been shown to be effective as an antidepressant in a

number of trials and is on the market in France and Japan. If milnacipran is approved for the treatment

of fibromyalgia, it will represent an off-label option in the treatment of depression. Gepirone is a

serotonin 5-HT1A partial agonist that appears to be somewhat effective in the treatment of depression.

It lacks significant sexual side effects and, therefore, could be a useful alternative for the many

patients who cannot tolerate the side effects of SSRIs. However, the FDA decided not to approve

gepirone for major depression. Desmethylvenlafaxine, the major metabolite of venlafaxine, is currently

in development and could be released in 2007. It remains unclear what benefits in efficacy or side

effect profile it may have over venlafaxine. Agomelatine is perhaps the most novel antidepressant in

current development. It is a serotonin 5-HT2C antagonist and a melatonin MT1 and MT2 agonist.

Studies in Europe suggest antidepressant and anxiolytic benefits with a favorable side-effect profile.

Phase III trials are under way in the United States.

HISTORY

The modern antidepressants were discovered serendipitously. In the early 1950s, investigators noted

that tuberculosis patients showed prolonged elevation of mood when treated with iproniazid (Marsilid),

Page 2 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapteran MAOI thought to be an antituberculosis agent. Iproniazid proved ineffective for tuberculosis, but its

impact on mood led to some of the earliest double-blind studies in psychopharmacology,

demonstrating that MAOIs were effective antidepressant agents. The biological and pharmacological

observations that MAOIs were antidepressants and that monoamine oxidase degraded norepinephrine

and serotonin (5-HT) became cornerstones of the so-called biogenic amine theories of depression.

Iproniazid was taken off the U.S. market some time ago because of fear that it causes hepatic

necrosis. For many years the use of other MAOIs declined, partly because of the introduction of TCAs

and partly because of the occurrence in patients of significant hypertensive crises.

The TCAs were also discovered serendipitously. The first reports on TCA efficacy in depression came

from Professor Kuhn (1958) in Switzerland, who astutely noted that a three-ringed compound,

imipramine, which was being investigated as a treatment for schizophrenia, appeared to elevate mood

even though it did not relieve psychosis. The drug was similar in structure to the phenothiazines, but a

simple substitution of nitrogen for sulfur in the central ring appeared to confer unique antidepressant

properties.

Two antidepressants with a four-ringed structure, maprotiline and amoxapine, have pharmacological

effects similar to those of the more traditional TCAs. These effects are not unexpected, because the

development of many of the earlier antidepressant compounds was based on the similarity of their

activity in certain animal models to that of prototypical TCAs—a similarity that led some to call them

“me-too drugs.” However, there are both subtle and pronounced differences among many of the so

called me-too drugs. For example, amoxapine is a potent 5-HT2 antagonist.

The success of traditional antidepressants in treating depression led to a search in the pharmaceutical

industry for compounds that would have the efficacy of the TCAs without many of the adverse effects,

such as cardiotoxicity. In 1972, a research team composed of Bryan Malloy, Dave Wong, and Ray

Fuller synthesized an agent at Eli Lilly labeled LY86032 that possessed these properties. This

compound was altered somewhat to produce fluoxetine hydrochloride (Prozac). After an initial release

in Belgium and South Africa, fluoxetine was released to the U.S. market in 1988. The first serotonergic

agent, trazodone, had been released in 1981, but it did not have nearly the impact of fluoxetine. No

other drug in the history of psychiatry has received as much attention, both positive and negative, as

has fluoxetine. In any case, fluoxetine offered an alternative to traditional agents because it retained

the efficacy of traditional antidepressants but did not have many of their side effects. In addition,

fluoxetine appeared safe in overdose. As a result, fluoxetine and related antidepressants have

supplanted the TCAs as the first-line agents in the treatment of major depression. Sales for fluoxetine

alone topped $2 billion in 2000 in the United States. (Fluoxetine went off patent in mid-2001.) This

success prompted other pharmaceutical companies to investigate agents that selectively enhance 5 HT

function, and several other new agents were later released.

The search for selective medications has also led to the introduction of new classes of antidepressants.

Venlafaxine, which is a selective serotonin-norepinephrine reuptake inhibitor (SSNRI), appears to

possess much of the efficacy of TCAs without the overdose risks and the myriad side effects of the

TCAs. Mirtazapine appears to increase norepinephrine release by blocking presynaptic 2 receptors.

This release also appears to, in turn, stimulate serotonin release. Selegiline, a selective monoamine

oxidase B (MAO-B) agent at low oral doses, circumvents some of the problems of traditional MAOI

when given transdermally or, for that matter, sublingually. Selective and reversible inhibitors of

monoamine oxidase A (RIMAs) represent another attempt to render difficult-to-tolerate MAOIs in a

more manageable form.

Despite the tremendous success of the newer classes of antidepressants in enhancing safety and

tolerability, there has been no appreciable success in improving the efficacy and the latency of onset of

the antidepressants. As with the traditional agents, no more than 50%–65% of patients with major

depression will respond to any given trial with a newer antidepressant, and no agent has been able to

Page 3 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterreduce reliably the 3 weeks or longer it appears to take for the drugs to work. Reducing the latency of

antidepressant effects and enhancing efficacy will be important foci of future research efforts.

GENERAL PRINCIPLES OF ANTIDEPRESSANT USE

Although the antidepressants vary considerably in their mechanisms of action, toxicity, dosing, and

potential for drug interactions, some clinical decisions apply to the use of all antidepressants. These

include the criteria for choosing an antidepressant, deciding what dose is adequate, and determining

the optimal duration of treatment.

Choosing an Antidepressant

As the number of antidepressants available has steadily increased, choosing an agent has become

somewhat more difficult. Although side-effect profile is generally mentioned as the primary factor in

choosing an antidepressant, optimally matching an antidepressant to a specific patient is as much art

as science. Patient parameters, including subtype of depression, age, sex, and medical status, are

matched with drug parameters such as side effects, safety, and cost.

The general wisdom is that all antidepressants on the market are equally efficacious in the treatment

of depression. This is unlikely. Depression is much too heterogeneous to suggest that agents with

diverse actions all work equally well for all types of depression.

The notion that antidepressants are equally efficacious is based on the fact that it has not been

possible to show that any antidepressant is reliably more than 50%–70% effective in a given clinical

trial. In contrast, placebos tend to be about 30% effective in outpatient trials. Efficacy is usually

defined as a 50% improvement on a standard depression rating scale such as the Hamilton Depression

Rating Scale (HDRS). When remission, rather than more general improvement, is the criterion for

efficacy, differences between antidepressants may begin to emerge. There had been some speculation

that antidepressants with more complex neurotransmitter effects, such as the TCAs, venlafaxine,

duloxetine, mirtazapine, and MAOIs, may achieve more complete remissions than SSRIs, and this

hypothesis has been investigated. Some, such as the meta-analysis by Thase et al. (2001), indicated

that venlafaxine was significantly more likely to effect a remission than were the SSRIs with which it

was compared. However, this area is controversial. The FDA has chided Wyeth for using the Thase

study in their marketing, pointing out that venlafaxine superiority may only be inferred against

fluoxetine. Indeed, a more recent meta-analysis by Nemeroff et al. (2003) of an additional 20 studies

failed to show superiority of venlafaxine over paroxetine. One major problem is that the original

venlafaxine studies were not designed to compare maximum doses over time or to treat to remission.

When subtypes of depression such as atypical, melancholic, and psychotic depressions are evaluated,

differences between antidepressant classes appear. Atypical depressions, which are characterized by

mood reactivity along with reverse vegetative symptoms such as increased sleep and appetite, have

long been shown to respond better to MAOIs than to TCAs. Since atypical depression may also respond

well to SSRIs and bupropion, these agents still would be first-line agents in the treatment of this

subtype. However, it may be quite reasonable to consider an MAOI for a patient with treatment

resistant depression with atypical features. The availability of transdermal selegiline, with its favorable

side-effect profile and lack of dietary restrictions, should probably now be the first MAOI that is

considered in either atypical or treatment-resistant depression.

There continues to be a debate as to whether melancholic or psychotic depression responds better to

TCAs or SNRIs than to SSRIs. Although most studies of antidepressant efficacy in these subtypes have

involved TCAs, prospective, head-to-head comparisons have never been done, and the literature

remains inconclusive. Melancholic depression clearly appears to respond to TCAs, and it may be more

reasonable to start with venlafaxine or mirtazapine, which are TCA-like in their dual actions, than with

an SSRI. Likewise, psychotic depression has responded to electroconvulsive therapy (ECT);

amoxapine, which is a tetracyclic agent; or the combination of a TCA and an antipsychotic. There are

Page 4 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chaptersome recent controlled data showing that the combination of fluoxetine and olanzapine is also

effective, and this would be the recommended first-line strategy because of safety and ease of use.

The age of the patient is an important consideration in antidepressant choice. In geriatric patients,

toxicity is more likely because of the number of concurrent medications they are taking, increased fat

to-muscle ratios, and reduced hepatic function and renal clearance. Among the SSRIs, escitalopram,

citalopram, and sertraline appear to be among the best tolerated and the least likely to have serious

pharmacokinetic interactions. Likewise, venlafaxine and mirtazapine have a low risk of interactions in

geriatric patients. However, there has been some concern about the safety of venlafaxine in frail

nursing home patients (Oslin et al. 2003). TCAs and MAOIs tend to be more poorly tolerated in

geriatric patients and would be second- or third-line agents in this population, although some

geriatricians still emphasize nortriptyline for elderly melancholic patients, and isocarboxazid was well

tolerated in geriatric studies done some years ago.

Gender is also an important factor in tolerability and efficacy of a given antidepressant class.

Substantial evidence suggests that men may respond to and tolerate the TCAs better than do women.

Conversely, premenopausal women appear to do better with serotonergic agents than do men. Thus,

men may be better treated with venlafaxine, duloxetine, or a TCA, and women may be better treated

with an SSRI or a 5-HT2 antagonist. Although clinicians would generally be advised not to start with a

TCA because of safety concerns, it may be better to start male patients with a more noradrenergic

agent than with an SSRI. Again, head-to head comparison studies are needed before clearer

recommendations can be made, and this area is still controversial.

The medical status of the patient is an important consideration in choosing an antidepressant. Patients

with pain conditions may do better with duloxetine, venlafaxine, or a TCA than with other agents.

There is some evidence that duloxetine, venlafaxine, and TCAs may be effective in treating both

depression and some types of pain conditions. Patients with a history of a seizure disorder, stroke, or

head trauma are more safely treated with an SSRI or venlafaxine than with a TCA or bupropion.

Likewise, patients with a history of arrhythmia or coronary artery disease are more safely treated with

serotonergic agents than with TCAs or MAOIs. Caution should be used in prescribing nefazodone for

AIDS patients who are taking protease inhibitors, since it may increase toxicity of the protease

inhibitors through pharmacokinetic interactions.

The primary drug parameters in choosing an antidepressant are side effects and safety. These are the

considerations that have made the SSRIs the most popular antidepressant choice for most clinicians.

The SSRIs are relatively safe in overdose and better tolerated than the TCAs and MAOIs for most

patients. From safety alone, it is difficult to justify using a TCA or an MAOI as a first treatment option.

Most of the SSRIs are given once per day, and the starting dose is sometimes the therapeutic dose.

Thus, the SSRIs are also among the easiest agents to use. Recently, the British equivalent of the FDA

warned that overdoses with fluoxetine were more likely to be lethal than overdoses with other SSRIs.

They advised against first-line use of the drug. The FDA has not agreed with this position.

Side effects differ considerably from class to class. Among the more important long-term side effects

that influence compliance are weight gain and sexual dysfunction. The TCAs, MAOIs, and mirtazapine

are probably the most problematic agents for weight gain, whereas fluoxetine and bupropion may be

the least problematic. Sexual dysfunction is common to most antidepressants, especially the MAOIs,

clomipramine, and the SSRIs. A number of agents are less likely to cause sexual side effects; these

include nefazodone, bupropion, and mirtazapine. In addition, novel antidepressants such as

agomelatine and transdermal selegiline also appear to have low risk for sexual side effects.

Another common approach to choosing an antidepressant is to target specific symptoms of a

depressive episode. For example, a patient with depression characterized by insomnia might benefit

from a sedating agent such as mirtazapine or a tertiary-amine tricyclic. Patients with significant anxiety

tend to be treated with an SSRI or SNRI. Patients with insomnia or anxiety may also be treated with

Page 5 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterthe combination of an SSRI or SNRI and a hypnotic or benzodiazepine. Alternatively, many clinicians

will choose a more stimulating antidepressant such as bupropion or transdermal selegiline in treating

patients who are experiencing hypersomnia and fatigue. Patients with significant cognitive deficits or

executive functioning problems might be treated with a noradrenergic agent such as bupropion or

atomoxetine. This targeted approach to the treatment of depression is intuitively sound but not

necessarily supported by empirical data.

Thus, although there are many considerations in optimizing the choice of antidepressants, it is evident

that the SSRIs and newer antidepressants remain the first-line agents for most patients. However,

TCAs and MAOIs still have a role in selected populations of depressed patients and continue to

represent an important option.

Dosage and Administration

The optimal dose of an antidepressant is the smallest efficacious dose that has the least side effects.

The decision about how much to push the dose of an antidepressant always comes down to balancing

efficacy and side effects. If, with a given dose of antidepressant, there are no signs of improving

symptoms after 4 weeks, the chances are very small that that dose will ever be effective (Quitkin et al.

1996). On the other hand, partial response in the first 4 weeks predicts more complete response over

the next 8 weeks, even if the dose is held constant. If a given dose is tolerated and not producing

partial benefits at 4 weeks, the dose should be increased rather than the medication switched.

Generally, increasing the dose every 2 weeks gives some opportunity for the clinician to assess the

benefits and side effects of a given dose. If the increase in dose is tolerated and less than complete

remission is observed, the dose should be gradually increased to the maximum recommended dose.

Duration of Treatment

Although standard antidepressant trials in the 1960s and 1970s were often 4 weeks, 6- to 12-week

trials are the current standard. It is difficult to assess the efficacy of an antidepressant in less than 4

weeks. Furthermore, it is unlikely that 4 weeks will be adequate to assess higher doses in a tolerant

patient. Quitkin et al. (1984), in reviewing a large series of depressed patients who were treated with

traditional TCAs, concluded that relatively few patients demonstrated significant improvement after

only 2 weeks of therapy and that many required as long as 6 weeks to respond. Years ago, our group

(Schatzberg et al. 1981) reported that patients with slow response to maprotiline and those with rapid

response could be identified biologically by their pretreatment urinary levels of 3-methoxy-4-

hydroxyphenylglycol (MHPG), which are indicative of norepinephrine function. Patients with low MHPG

levels demonstrated rapid responses (in less than 14 days), and those with very high MHPG levels

needed 4–6 weeks of treatment. More recent reviews by Nierenberg et al. (1995), (2000) have also

suggested that failure to improve while taking a given dose of fluoxetine for 4 weeks predicts failure to

respond at 8 and 12 weeks.

All patients who respond to a given dose of an antidepressant should be maintained at that dose for at

least 6–12 months. The continuation of all antidepressants studied to date appears to substantially

reduce the risk of relapse. In a major National Institute of Mental Health collaborative study (Prien et

1. 1984), imipramine was generally more effective than placebo or lithium in preventing relapse of

major depression over a 2-year maintenance period. In contrast to that study, two earlier major

studies, one in the United States and the other in the United Kingdom, found lithium to be as effective

as TCAs in preventing relapses in patients with unipolar depression. In the U.S. study by Prien et al.

(1984), the overall relapse rate in the unipolar group was relatively high (64%; 49% in the imipramine

group), and the authors argued for the need to develop newer, alternative strategies, perhaps with

drugs other than TCAs. (For further discussion of maintenance therapy in affective disorders, see

Chapter 4: “Antipsychotic Drugs.”) In the first edition of this manual, we indicated that after receiving

maintenance therapy for some 3–4 months at the doses at which they responded, many patients can

be maintained at lower doses (½ to ¾ that of the original dose) for the remaining months. However,

Page 6 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterthe results of Frank et al. (1990) suggest that full doses are needed for successful maintenance

therapy. These investigators found that 80% of patients with recurrent depression were free from

relapse or recurrence for 3 years when full doses of imipramine (average of 200 mg/day) were

maintained. We second the recommendations of Frank and colleagues that patients be maintained at

their therapeutic dosage levels unless pronounced side effects are present. However, low versus high

doses of SSRIs in maintenance therapy have not been compared, so we do not know whether lower

doses of SSRIs are effective for maintenance. Since depression is a recurrent illness, long-term

maintenance therapy should be considered for anyone who has had three or more serious depressive

episodes or two episodes in the past 5 years.

Long-term treatment with antidepressants can represent a challenge for the patient in adhering to the

prescribed regimen. Several interventions can increase compliance. It is helpful to educate the patient

and family about the course of depressive illness, the length of time it takes for antidepressants to

work, and the need to continue treatment when the patient is feeling better. Reviewing potential side

effects is also helpful. Asking for feedback and answering any questions the patient may have allows

the clinician to check the patient’s understanding of the prescribed treatment. Instructing the patient

to not change the dosage or discontinue the medication without consulting his or her physician is often

helpful as well.

SELECTIVE SEROTONIN REUPTAKE INHIBITORS

Although the TCAs were the dominant class of antidepressants worldwide for more than 30 years, the

SSRIs overtook them in popularity in just a decade. Currently, this class includes fluoxetine,

paroxetine, sertraline, fluvoxamine, citalopram, and escitalopram (Figure 3–1). Fluvoxamine does not

have an FDA-approved indication for the treatment of depression. However, the drug is marketed in

many countries as an antidepressant. Unlike the TCAs or any other group of prescribed psychotropic

agents, the SSRIs, particularly fluoxetine, have had tremendous exposure in the scientific literature.

Figure 3–1.

Page 7 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterThese drugs have been both vilified and praised in the lay press, but the popularity of the SSRIs

among patients and physicians has remained quite consistent. The enormous popularity of these

agents is due in no small part to their favorable safety and side-effect profile relative to the MAOIs and

the TCAs. The SSRIs have also proved to have a broad spectrum of activity in a variety of psychiatric

disorders, and they have an additional advantage in that it is easier to attain the optimal therapeutic

dose. However, not all patients tolerate or respond to the SSRIs, and, as suggested earlier (see

“Choosing an Antidepressant” subsection earlier in this chapter), they may not be as effective as the

more traditional antidepressants for some disorders.

Chemical structures of selective serotonin reuptake inhibitors (SSRIs).

Selective serotonin reuptake inhibitors (SSRIs): overview

Efficacy First-line treatment in

MDD (FDA approved for all except fluvoxamine), dysthymia

PD (FDA approved for fluoxetine, paroxetine, and sertraline)

OCD (FDA approved for all except citalopram and escitalopram)

Page 8 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterPharmacological Effects

As the name of this class of antidepressants indicates, the SSRIs selectively block the reuptake of 5-HT

through their inhibiting effects on the Na+/K+ adenosine triphosphatase (ATPase)–dependent carrier in

presynaptic neurons. Compared with a standard TCA such as amitriptyline, which has about an equal

tendency to block neuronal reuptake of 5-HT and norepinephrine, fluoxetine is 200 times more

selective in blocking the reuptake of 5-HT than of norepinephrine. Fluoxetine is approximately 4 times

as potent a 5-HT reuptake inhibitor in vitro as is amitriptyline, and paroxetine is approximately 80

times as potent an inhibitor as amitriptyline. Of the five currently available SSRIs, paroxetine and

citalopram appear to be the most potent 5-HT uptake blockers.

Social anxiety disorder (FDA approved for sertraline and paroxetine)

PTSD (FDA approved for sertraline and paroxetine)

Bulimia (FDA approved for fluoxetine)

GAD (FDA approved for paroxetine and escitalopram)

PMDD (FDA approved for fluoxetine [Sarafem only], paroxetine [controlled

release only], and sertraline)

Side effects GI side effects (nausea, diarrhea, heartburn)

Sexual dysfunction ( libido, delayed orgasm)

Headache

Insomnia/somnolence

Safety in overdose Generally safe in overdose to 30–90 days’ supply; manage with vital sign

support, lavage

Seizures/status epilepticus (rare)

Dosage and

administration

Citalopram, paroxetine, fluoxetine: qd dosing, starting at 10–20 mg, increasing

to a maximum of 40 mg (citalopram), 50 mg (paroxetine), and 80 mg

(fluoxetine).

Escitalopram: qd dosing, starting at 10 mg, increasing to 20 mg after minimum

of 1 week.

Sertraline: starts at 25–50 mg and is increased, as needed, to 200 mg

maximum.

Full benefits in 4–8 weeks

Discontinuation Paroxetine, fluvoxamine, sertraline: discontinuation associated with

parasthesias, nausea, headaches, flulike symptoms 1–7 days after sudden

discontinuation

Drug interactions MAOI (contraindicated): serotonin syndrome

TCA levels (paroxetine, fluoxetine)

Carbamazepine, phenobarbital, phenytoin levels

Haloperidol, clozapine levels (fluvoxamine)

Theophylline levels (fluvoxamine)

Encainide, flecainide levels (avoid)

Note. FDA = U.S. Food and Drug Administration; GAD = generalized anxiety disorder; GI =

gastrointestinal; MAOI = monoamine oxidase inhibitor; MDD = major depressive disorder; OCD =

obsessive-compulsive disorder; PD = panic disorder; PMDD = premenstrual dysphoric disorder; PTSD

= posttraumatic stress disorder; TCA = tricyclic antidepressant.

Page 9 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterHowever, selectivity is a relative term. Although the SSRIs are more selective than, say, the TCAs, all

the SSRIs impact other neurotransmitter systems, at least modestly. For example, there is in vitro

evidence that paroxetine at high dosages (>40 mg/day) may be as much, if not more, of a

norepinephrine reuptake blocker as is venlafaxine. Sertraline also appears to block the reuptake of

dopamine and may be more potent in this regard than bupropion. Likewise, paroxetine may have as

strong of an anticholinergic effect as desipramine.

The reuptake-blocking properties of the SSRIs enhance general serotonergic tone in at least two

distinct steps. Initially, the SSRIs contribute to a significant increase in the availability of 5-HT in the

synaptic cleft. However, it is unlikely that this effect has any bearing on antidepressant efficacy,

because the SSRIs share the delayed onset of action typical of all antidepressants. With recurrent

administration of the drugs, however, there is a reduction in the sensitivity of the somatodendritic and

terminal 5-HT1A autoreceptors, and the time course of this effect is associated more closely with

antidepressant response.

Unlike the TCAs, the SSRIs have relatively little affinity for histaminic (H1 , H2 ), muscarinic, or 1 –

adrenergic receptors. Although sertraline may have 25% of the in vitro affinity for 1 -adrenergic

receptors that imipramine has, this finding is of little clinical relevance. On the other hand, paroxetine

has weak but somewhat clinically meaningful antimuscarinic activity. The anticholinergic affinity for

paroxetine is roughly equivalent to that for desipramine. In general, however, the selective nature of

the SSRIs results in the very favorable side-effect profile and the large therapeutic index possessed by

these drugs.

The SSRIs are extensively metabolized by hepatic enzymes, especially the cytochrome P450 2D6

enzyme (Table 3–1). Sertraline is also metabolized via the cytochrome P450 3A3/4 enzyme. Only

fluoxetine and sertraline have pharmacologically active metabolites (Table 3–2). Fluoxetine is

demethylated to norfluoxetine, and sertraline is metabolized to N-desmethylsertraline and a

hydroxyketone. As a result, the functional half-lives of fluoxetine and sertraline are considerably longer

than those of paroxetine and fluvoxamine. Fluoxetine has a half-life of about 34 hours; the half-life of

norfluoxetine is at least 1 week. Sertraline has a half-life of about 26 hours, and the half-lives of its

metabolites tend to range from 48 to 72 hours. Both paroxetine and fluvoxamine have half-lives that

average under 20 hours, whereas citalopram has a half-life of around 35 hours. With repeated

administration of the drugs, the half-lives of all of the SSRIs, but particularly paroxetine and fluoxetine,

increase substantially, because the drugs appear to inhibit their own metabolism. Thus, the functional

half-lives of fluoxetine and norfluoxetine, with continued use, are closer to 2–3 weeks. Plasma level

monitoring of the SSRIs has not proved clinically useful. The variability of SSRI plasma levels among

individuals is so great that it has been nearly impossible to correlate efficacy or toxicity with plasma

levels.

Table 3–1. Inhibition of cytochrome P450 enzymes by antidepressant

Enzyme Drugs metabolized Antidepressant inhibitors

2D6 TCAs (hydroxylation) fluoxetine (norfluoxetine)

bupropion sertraline (desmethylsertraline)

venlafaxine paroxetine

thioridazine fluvoxamine and citalopram (weakest)

1C antiarrhythmics

-blockers

paroxetine

risperidone

Page 10 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chaptercodeine

haloperidol

clozapine

benztropine

perphenazine

1A2 caffeine fluvoxamine

theophylline

phenacetin

TCAs (demethylation)

clozapine

diazepam

3A3/4 alprazolam fluoxetine

triazolam sertraline

TCAs (demethylation) fluvoxamine

terfenadine nefazodone

astemizole

carbamazepine

erythromycin

dexamethasone

citalopram

escitalopram

2C19 TCAs (demethylation) fluoxetine

warfarin fluvoxamine

tolbutamide sertraline

phenytoin

diazepam

Note. TCA = tricyclic antidepressant.

Table 3–2. Pharmacokinetics of selective serotonin reuptake inhibitors (SSRIs)

Ssri Half-life

(hours)

Metabolite and its half-life Peak plasma level

(hours)

% Protein

bound

fluoxetine 24–72 norfluoxetine, 7–14 days 6–8 94

sertraline 25

N-desmethylsertraline, 2–3

days

6–8 95

paroxetine <20 NA 2–8 99

fluvoxamine 15 NA 2–8 77

citalopram 35 NA 4–6 91

escitalopram 32

S-demethylcitalopram 5 56

Page 11 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterIndications

The SSRIs are indicated primarily for the treatment of major depression, and numerous studies have

supported this use. A large number of double-blind, placebo-controlled studies have established that

the SSRIs are useful in the treatment of mild to moderate major depression in outpatients (Rickels and

Schweizer 1990). The SSRIs are effective in atypical depression, in combination with standard

antipsychotics in the treatment of psychotic depression, and in the maintenance therapy of recurrent

depression in trials lasting 1 year. The SSRIs are also useful in the treatment of chronic major

depression with dysthymia. Some clinicians have come to regard these agents as the treatments of

choice for these disorders.

However, there is ongoing debate about the role of the SSRIs in more serious forms of depression,

including melancholia. Large meta-analyses and reviews have failed to show a significant difference in

efficacy between SSRIs and TCAs in the treatment of severe depression (Hirschfeld 1999; Nierenberg

1994). Still, relatively few studies of SSRIs have involved more severely depressed inpatients, and

some of the studies that did involve such patients did not directly compare the SSRIs with older agents

such as the TCAs. Some studies that made these direct comparisons suggested that paroxetine was

inferior to clomipramine in inducing remission in melancholic inpatients (Danish University

Antidepressant Group 1990) and that fluoxetine was much less effective than nortriptyline in treating

melancholic elderly cardiac patients who were hospitalized for depression (Roose et al. 1994). These

studies defined response not as a reduction in overall severity but rather as virtual remission. Other

studies have failed to find any difference in efficacy between the TCAs and SSRIs in more severely

depressed inpatients. This debate about the efficacy of the SSRIs in more severe depression is likely to

continue. The available data suggest that the SSRIs may not be quite as effective in treating some

seriously depressed elderly inpatients but that they do have a more favorable side-effect profile than

the TCAs.

The second indication for the SSRIs is the treatment of OCD. The utility of clomipramine (a

serotonergic TCA) in the treatment of OCD was first noted in 1968. Since that time it has become clear

that other serotonergic agents are also useful in the treatment of this historically difficult-to-treat

disorder (Chouinard et al. 1990; Tollefson et al. 1994). Fluvoxamine, fluoxetine, sertraline, and

paroxetine all have an FDA indication for the treatment of OCD, but all the SSRIs have demonstrated

efficacy in treating the disorder. SSRI doses for the treatment of OCD are usually higher than those

required for the treatment of depression, and the latency to response is usually longer.

A third indication for the SSRIs, and a fairly well studied one, is the treatment of eating disorders,

particularly bulimia nervosa. Fluoxetine has been shown to have a positive effect on the binge-purge

cycle in some bulimic patients (Fluoxetine Bulimia Nervosa Collaborative Study Group 1992). The

SSRIs may also ameliorate the carbohydrate craving and mood disturbance associated with bulimia

nervosa and obesity. Fluoxetine and sertraline have been shown to have a modest effect on weight and

food intake in obese patients. Unfortunately, most patients who lose weight in the course of therapy

with an SSRI gain it back over time. There are few data on the use of the SSRIs to treat classic

anorexia nervosa, but one report suggested that fluoxetine may be useful for this condition (Kaye et al.

1991). The largest controlled study to date of fluoxetine in the prevention of relapse in anorexic

patients failed to show any benefit for fluoxetine in preventing relapse relative to placebo (Walsh et al.

2006). However, this study involved adults with a more chronic form of the illness, and there may be

subsets of anorexic patients who appear to do better while taking an SSRI.

Finally, there appears to be a role for the SSRIs in the treatment of most other anxiety disorders,

including panic disorder, social phobia, GAD, and PTSD. Although patients with panic disorder may be

sensitive to the activating effects of some SSRIs, most are able to tolerate a slow titration of dosage

upward. For example, some reports indicate that although some patients do not tolerate an initial

Note. NA = not applicable.

Page 12 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterdosage of 20 mg/day of fluoxetine, many patients are able to benefit if the starting dosage is 5 mg/day

(Schneier et al. 1990).

The SSRIs, including citalopram and fluvoxamine, all appear, on the basis of published data, to be

effective in treating panic disorder. Paroxetine, sertraline, and fluoxetine have received an FDA

approved indication for the treatment of panic disorder.

In 1999, paroxetine received an FDA-approved indication for treating social phobia, and preliminary

data support the use of other SSRIs in the treatment of this disorder. A number of double-blind studies

indicate that paroxetine at dosages of 20–50 mg/day is more effective than placebo in alleviating

symptoms, including undue fear and avoidance of interpersonal interaction. Further, paroxetine

appears to reduce the significant disability associated with more severe forms of this disorder (Stein et

1. 1998).

Posttraumatic stress disorder is associated with a variety of comorbid conditions, especially depression

and substance abuse. SSRIs have been used since the late 1980s to treat some of the symptoms of

PTSD, including depression, insomnia, hyperarousal, and agitation. There is substantial evidence that

fluoxetine, paroxetine, and sertraline help alleviate these symptoms and may even impact comorbid

substance use. In 1999, sertraline became the first drug to be approved by the FDA for the treatment

of PTSD. Many PTSD patients treated with sertraline appear to require doses above 100 mg/day of

sertraline for maximum effects. With paroxetine, a dosage of 20 mg/day appears to be about as

effective as 40 mg/day in treating PTSD.

The SSRIs should help with GAD, and paroxetine and escitalopram have received FDA approval for this

indication. Paroxetine, at dosages of 20–50 mg/day, was effective in reducing anxiety by 60% on the

Hamilton Anxiety Rating Scale. Large-scale studies of escitalopram have also shown benefit in the

treatment of generalized anxiety.

Premenstrual dysphoric disorder (PMDD) is a very disruptive monthly occurrence for about 3% of the

female population. In 1995, in the first large study of fluoxetine in the treatment of PMDD (Steiner et

1. 1995), 20- and 60-mg doses were more effective than placebo for treating symptoms over six

consecutive menstrual cycles. The effect was seen as early as the first cycle after initiation of the

medication. Since then, a number of studies have supported the use of SSRIs, especially fluoxetine and

sertraline, in treating this disorder. Both of these drugs have also been used as intermittent treatment

in the luteal phase of the cycle and appear to be effective (Jermain et al. 1999). In 1999, fluoxetine

(Sarafem) became the first medication approved for the treatment of PMDD.

The list of disorders in which the serotonergic system plays a part is long, and the potential role for the

SSRIs is continually expanding. The SSRIs appear to be useful in treating the anger or impulsive

aggression associated with some personality disorders (Kavoussi et al. 1994; Salzman et al. 1995) and

perhaps certain pain disorders such as diabetic neuropathy and fibromyalgia (Wolfe et al. 1994),

although here the mixed norepinephrine-serotonin reuptake blockers appear to be far more effective.

Side Effects

As noted previously, the SSRIs tend to be safer and better tolerated than their predecessors. There

have been many overdoses in clinical practice with the SSRIs, but these have rarely been eventful. In

fact, a review of 234 fluoxetine overdose attempts, with doses up to 1,500 mg, failed to reveal any

fatalities, and more than half the patients were completely asymptomatic (Borys et al. 1992). Nothing

more than supportive care was required for any patient. Moderate overdoses (5–30 times the total

daily dose) are rarely serious. Fatal overdose with any of the SSRIs is at least theoretically possible but

has been rare. The usual cause of death appears to be complications of seizures or status epilepticus

and typically involves ingesting thousands of milligrams (Barbey and Roose 1998). There is no question

that the SSRIs offer a significant safety advantage over the TCAs and MAOIs.

In early clinical studies, approximately twice as many patients were likely to drop out because of

Page 13 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapteradverse effects of TCAs as because of adverse effects of SSRIs. The SSRIs are largely devoid of the

anticholinergic side effects that plague the TCAs. Furthermore, orthostatic hypotension does not

typically occur with SSRI use. That is not to say that all people tolerate the SSRIs better than the

TCAs. Emerging data suggest that men may tolerate and respond to TCAs better than do women. The

basis for this finding has not been elucidated. However, even greater tolerability, if substantiated,

would not make TCAs safer, and they are still second-line agents.

The most common reasons patients discontinue the SSRIs early in treatment are gastrointestinal (GI)

side effects. These include nausea, diarrhea, cramping, heartburn, and other symptoms of GI distress.

The gut is lined with 5-HT receptors, including 5-HT3 , which appear to be responsible for SSRI-induced

GI distress. Whereas the earliest reports suggested that approximately 20%–30% of patients treated

with fluoxetine developed GI side effects, the incidence in clinical practice has been much lower. In

early studies, the dosage was often started at 20 mg/day but reached 60 mg/day by the end of the

first week. In clinical practice, the starting dosage of 20 mg/day is maintained for 3 weeks, and nausea

is both less common and less severe. Furthermore, the GI side effects tend to diminish over the first

2–4 weeks of treatment.

Several strategies may be useful in reducing SSRI-induced GI distress. The first is a slow titration of

the medication. Starting at half, or less than half, of the usual starting dose and moving the dose up

slowly in sensitive patients allows adaptation to occur. Another strategy is instructing patients to take

their medication with meals. A full stomach appears to mitigate some GI distress. Finally, there is a

case report on the use of cisapride, a 5-HT3 antagonist, 5 mg bid, to reduce SSRI-induced GI distress

(Bergeron and Blier 1994). Unfortunately, cisapride was removed from the market in 1999 because of

the risk of arrhythmia. Other 5-HT3 antagonists, such as dolasetron (Anzemet) and ondansetron

(Zofran), are also clearly helpful but are too expensive to use routinely. Mirtazapine (Remeron) is a

moderately potent 5-HT3 antagonist and could potentially be used in combination with SSRIs.

Another group of side effects commonly encountered with SSRIs is related to central nervous system

(CNS) activation. At least 10%–20% of patients receiving SSRI therapy complain of insomnia,

jitteriness, and agitation in the course of treatment. These side effects are not particularly surprising,

given the selective, but not specific, effect of SSRIs on CNS serotonergic transmission. That is, the

SSRIs affect diffuse serotonergic pathways, and some of these pathways contribute to CNS arousal.

For this reason, fluoxetine, which has a reputation for activating properties, should be taken in the

morning, when it is less likely to interfere with sleep. Likewise, if patients develop insomnia with other

SSRIs, it is often effective to have the patients take the dose earlier in the day. Occasionally, patients

require modest doses of a benzodiazepine (e.g., clonazepam 0.5 mg bid, lorazepam 0.5 mg bid,

alprazolam 0.25 mg bid) early in the course of therapy to help with agitation and sleep. Trazodone is

another commonly used agent shown to be helpful at doses of 50–100 mg at bedtime for SSRI-induced

insomnia. A number of case reports also suggest that trazodone may augment response in the SSRIs.

Conversely, some patients may become sedated on SSRIs. This effect is seen mostly with paroxetine.

When sedation occurs, taking the dose at about 8:00 P.M. is useful for matching the peak blood level

with the optimal time of sedation (about 2:00 A.M.). Some patients taking other SSRIs experience the

emergence of a numbed or anergic feeling in the context of a euthymic mood. Donald Klein has

recommended low dosages of bromocriptine (2.5 mg qd or bid) or stimulants to counteract this effect.

Modafinil (Provigil) has been applied to counteract antidepressant-induced hypersomnia. Modafinil is a

stimulant with low abuse potential and is FDA approved for the treatment of narcolepsy and idiopathic

hypersomnia. We have found that doses of 100–200 mg in the morning are helpful in alleviating

treatment-emergent somnolence (DeBattista et al. 2003).

In recent years, it has become clear that treatment-emergent sexual dysfunction is a much bigger

problem with SSRI treatment than was previously recognized. Premarketing studies suggested that the

incidence of sexual dysfunction—including delayed ejaculation, anorgasmia, impotence, and diminished

libido—was less than 4%. However, more recent reports suggested that the incidence may be closer to

Page 14 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapter30%–40% for all of the SSRIs. Although accommodation to sexual side effects does occur in some

patients, such improvement may take months or even years. Holding the dose of shorter-acting SSRIs,

such as paroxetine and sertraline, for 24 hours prior to anticipated sexual activity has been anecdotally

reported to be helpful in some 50% of patients. The long half-life of fluoxetine makes this approach

ineffective.

A number of interventions to counteract treatment-emergent sexual dysfunction have been described

(Table 3–3), but most have not been well studied. Virtually all the reported benefits of adjunctive

agents for treatment-emergent sexual side effects are based on case reports or open-label studies. A

few controlled studies have been completed, but their findings are not conclusive. In one of the few

double-blind studies of sexual dysfunction antidotes to be published, buspirone, a partial agonist of the

5-HT1A receptor, was shown to be useful in treating SSRI-induced sexual dysfunction in some patients

at dosages of 20–60 mg/day (Landen et al. 1999). However, another double-blind study of buspirone

in the treatment of SSRI-induced sexual side effects did not find buspirone to be useful in this regard

(Michelson et al. 2000). Mirtazapine was also ineffective in a controlled trial, although olanzapine, a 5-

HT2 /D2 antagonist, was significantly more effective than placebo (Michelson et al. 2002). Switching to

bupropion (Walker et al. 1993) or adding bupropion at dosages of 75–150 mg/day to the SSRI regimen

(Ashton and Rosen 1998; Hirschfeld 1999; Labbate and Pollack 1994) has proved useful in some

cases. We completed a double-blind study of bupropion as an add-on therapy (DeBattista 2001) and

found it helpful for mood but not for sexual performance at a fixed dosage of 150 mg/day (DeBattista

et al. 2004). Bupropion was found to be only marginally effective at increasing sexual arousal;

however, a dose of 300 mg or more may be needed to improve sexual function. Clayton and colleagues

(2004) found that bupropion at a dosage of 150 mg bid improved desire and interest in sexual activity

on some measures after 4 weeks.

The use of sildenafil (Viagra) has been reported to be significantly more effective than placebo in men

with SSRI-induced sexual dysfunction (Nurnberg et al. 2001; Fava et al. 2006a). The reported utility of

sildenafil in countering SSRI-induced sexual side effects is somewhat counterintuitive, since the most

common sexual side effects of SSRIs are decreased libido and delayed orgasm rather than erectile

problems. However, sildenafil has been reported to increase overall sexual satisfaction in both men and

women. We have found sildenafil at dosages of 50–100 mg/day to be more helpful with men than with

Table 3–3. Adjunctive agents for selective serotonin reuptake inhibitor (SSRI)–induced

sexual dysfunction

Adjunctive

agent

Dosage Studies

buspirone 20–60

mg/day

Landen et al. 1999; Norden 1994

bupropion 75–150

mg/day

Ashton and Rosen 1998; Labbate and Pollack 1994

sildenafil 50–100 mg

prn

Ashton and Bennett 1999; Gupta et al. 1999; Nurnberg et al.

1999a, 1999b; Fava et al. 2006a

vardenafil 10–209 mg Rosen et al. 2006

Ginkgo biloba

60–240

mg/day

Wheatley 2004

amantadine 100–300

mg/day

Balon 1996; Shrivastava et al. 1995

cyproheptadine 4–12 mg prn Aizenberg et al. 1995; Keller Ashton et al. 1997

yohimbine 5.4 mg tid Jacobsen 1992; Price and Grunhaus 1990

Page 15 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterwomen. Similar agents such as vardenafil also appear to be effective in antidepressant-associated

sexual dysfunction, at least in men (Rosen et al. 2006). Cyproheptadine at dosages of 4–12 mg/day

may reverse some of the dysfunction. Unfortunately, cyproheptadine may also reverse the

antidepressant or antiobsessive effects of the SSRIs and is quite sedating. The -adrenergic agonist

yohimbine helps some patients (Jacobsen 1992) but was ineffective in a controlled trial (Michelson et

1. 2002). Unfortunately, yohimbine can be quite anxiogenic for some patients, and this effect tends to

be counterproductive. Similarly, some case reports have suggested that dopaminergic agents such as

amantadine, amphetamine, and bromocriptine may be helpful for some patients. The ancient herb

Ginkgo biloba has been anecdotally reported to help some patients with SSRI-induced sexual

dysfunction. However, beneficial effects may require a higher dosage (e.g., 240 mg/day) for weeks,

and such dosages have sometimes been associated with GI side effects, increased bleeding, and

confusion in elderly patients. As is often the case, more carefully controlled studies have failed to show

a benefit of Ginkgo biloba in treating antidepressant-induced sexual dysfunction (Wheatley 2004).

Given the lack of evidence supporting ginkgo and the potential for some side effects, we do not

encourage patients to try it.

A number of other adverse effects are associated with the SSRIs, but these occur less consistently.

Headaches may occur early in the course of therapy with some patients. On the other hand, the SSRIs

have shown some utility in the prophylaxis of migraine when used long-term. Autonomic symptoms

such as excessive perspiration and dry mouth are frequently reported. Excessive perspiration is very

problematic for some patients. Anecdotal approaches to the treatment of SSRI-induced perspiration,

such as the use of -blockers and anticholinergic agents, are largely untested. 2 -Adrenergic agents

may be helpful here. Tremor may develop in a dose-related pattern and is often responsive to

propranolol in modest dosages (10 mg tid). Dry mouth is seen in some 20% of patients treated with

paroxetine, reflecting the mild anticholinergic effects of this medication.

The question of whether weight gain is associated with chronic use of SSRIs has become a focus of

interest. In general, it has been difficult to reliably correlate significant weight gain with SSRI

treatment. After a year of treatment, most of the SSRIs are associated with either no weight gain or

modest weight increases. Among the SSRIs, paroxetine may be somewhat more associated with

weight gain and fluoxetine somewhat less.

Teicher et al. (1990) reported the emergence of intense preoccupation with suicide in six patients early

in fluoxetine treatment. This phenomenon may also occur with other antidepressants. Subsequent

studies and analyses of data sets have failed to find any greater proclivity for suicide with fluoxetine

than with other antidepressants (Beasley et al. 1991). In addition, there has been no association of

fluoxetine with suicidality in bulimia (Wheadon et al. 1992) or OCD (Beasley et al. 1992). This suggests

that the phenomenon of treatment-emergent suicidal thoughts may be an artifact of the patient’s

underlying depression rather than the result of the medication. However, fluoxetine is associated with

agitation or perhaps akathisia-like side effects, and it is conceivable that some depressed patients may

become more suicidal when these effects occur (Rothschild and Locke 1991). Rothschild and Locke

(1991) reintroduced fluoxetine in three patients who had previously attempted suicide while taking

fluoxetine. They reported that all three patients developed severe akathisia with the reintroduction. In

two of the three cases, the suicidal distress was relieved by propranolol. Thus, switching to a less

activating antidepressant or using a benzodiazepine such as clonazepam or lorazepam or a -blocker

concurrently with the SSRI may be advisable in cases of treatment-emergent suicidal ideation. Some

patients who experience this phenomenon while taking a TCA may not experience it with fluoxetine.

The second author (J.O.C.) was involved in the Teicher et al. (1990) report on obsessive suicidal

thoughts associated with fluoxetine and still believes he sees in rare cases patients who experience this

phenomenon. Fisher et al. (1992), in a prescription-based survey, found that 0.5% of patients who had

recently filled a fluoxetine prescription called an 800 number to report a new suicidal drive; no patients

who had filled trazodone prescriptions reported such adverse effects. The rare incidence of treatment

Page 16 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapteremergent suicidal thoughts is not a justification for avoidance of SSRIs. The controversial FDA review

of antidepessants and suicidality in children found an increased risk of about 3% with the

antidepressants and 1.5% with placebo. This resulted in a black box warning regarding the risks of all

antidepressants used in adolescents and children. However, this increased risk must be balanced with

the improvement in suicidal ideation that occurs in many more patients while taking antidepressants.

Studies subsequent to the black box warning that have examined the risk of suicidal behavior with

antidepressant use have generally failed to find an association (Hammad et al. 2006a, 2006b; Kaizar et

1. 2006; Simon et al. 2006; Sondergard et al. 2006a, 2006b). Of note was the study by Simon et al.

(2006), in which risk of suicide attempts was highest in the month before initiation of therapy. The

recent FDA-initiated study of 100,000 patients revealed a 2% risk of emergent suicidal-like behavior in

subjects 18–25 years of age versus 1% in subjects receiving placebo. Older patients appeared to not

show such increased risk, and elderly subjects showed a significant decrease. However, as with adults,

there may be small subsets of patients at greater risk for suicidal behavior (e.g., young adults) while

taking antidepressants. These could include patients with latent bipolar disorder, patients who

experience agitation while taking an antidepressant, and patients who become energized enough while

taking an antidepressant to act on suicidal impulses before their mood has substantially improved.

We continue to recommend that these drugs be used in both children/adolescents and adults, but with

appropriate warning and monitoring. In view of the clustering of adverse reports with paroxetine in

children, it does seem wise to use another agent before trying paroxetine in children.

Overdose

The popularity of the SSRIs rests in part on their safety in overdose (Barbey and Roose 1998).

Thousand of overdoses have occurred in the past 15 years, but very few fatalities have resulted from

overdosing on an SSRI alone. Fluoxetine, the first SSRI in the United States and the most commonly

used, has the most fatalities associated with its overdose. Moderate overdoses (at up to 30 times the

common daily dose) tend to be associated with minor symptoms. The most common symptoms of

large overdoses include vomiting, nausea, tremor, and sedation. At very high doses (more than 75

times the common daily dose), more serious adverse events, cardiovascular events, seizures, and

altered or decreased consciousness have been reported.

The most common causes of death in an SSRI overdose are typically complications of status epilepticus

and cardiovascular events such as arrhythmias.

Most fatalities have involved the co-ingestion of other drugs, particularly alcohol or drugs dependent on

the cytochrome P450 2D6 system, such as the TCAs (Dalfen and Stewart 2001).

In general, lavage and supportive care in the emergency room are all that is required in the vast

majority of SSRI overdoses. In severe overdoses or those involving other drugs, cardiac monitoring or

interventions for seizure control may be required.

Drug Interactions

The risk of serious drug interactions is fairly limited with SSRIs. However, several types of drug

interactions may occur. The most serious of these is the interaction with the MAOIs. Several fatalities

have been reported from serotonin syndrome when SSRIs were used in close proximity to MAOIs, even

if the drugs were not used concurrently. In two of these cases, fluoxetine had been stopped but an

MAOI had been started promptly thereafter. Therefore, an adequate washout must occur after the

SSRIs are discontinued before an MAOI is initiated (see “Discontinuation” subsection). Serotonin

syndrome has proved difficult to treat. The most important interventions in treating this syndrome are

stopping the offending agents and initiating medical support, including lowering of body temperature, if

needed. Beyond that, cyproheptadine at a dosage of 16 mg/day may be helpful in less severe cases in

which myoclonic jerking is present. Dantrolene may also be helpful (see Chapter 10: “Emergency

Room Treatment”).

Page 17 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterAnother type of potential drug interaction occurs as a result of the tendency of the SSRIs to

competitively inhibit enzymes of the cytochrome P450 system (Table 3–1). The inhibition of the 2D6

enzyme by the SSRIs is perhaps the best understood. Many drugs are metabolized by this enzyme,

including the TCAs, type 1C antiarrhythmic agents, some -blockers, benztropine, and many

antipsychotic medications. Most of the SSRIs are capable of inhibiting the 2D6 enzyme, leading to

increased plasma levels of other agents. For example, fluoxetine may be associated with up to an

eightfold increase in TCA plasma levels when the two drugs are used concurrently. On a molar basis,

fluoxetine, paroxetine, and sertraline are fairly equal in their proclivity to competitively inhibit the 2D6

enzyme, whereas citalopram (and escitalopram) and fluvoxamine do not significantly inhibit this

enzyme. Sheldon Preskorn at the University of Kansas reported that 20 mg of fluoxetine raises

desipramine levels several times higher than does 50 mg of sertraline. However, other studies indicate

that higher dosages of sertraline (e.g., 150 mg/day) can produce significant increases in desipramine

levels. Fluvoxamine is about 10 times less potent a competitive inhibitor of the 2D6 enzyme than the

other SSRIs, yet it was associated with a twofold increase in amitriptyline levels in two patients and a

sevenfold increase in clomipramine levels in a third patient (Bertschy et al. 1991). Fluvoxamine has

also been associated anecdotally with significantly increasing clozapine levels, probably through its

inhibition of the cytochrome P450 1A2 enzyme. Thus, caution should be exercised when combining any

of the SSRIs with drugs predominantly dependent on the 2D6 enzyme, because the risk of toxicity

from the concurrent drug will be enhanced. For example, it is prudent to monitor TCA serum levels and

electrocardiograms (ECGs) when any of the TCAs are used in combination with an SSRI. However, in a

geriatric study, Murphy et al. (2003) failed to find a relationship between specific cytochrome P450

2D6 alleles and the risk of dropping out due to adverse events, even though patients were taking a

variety of medical drugs that were known substrates for the 2D6 enzyme.

Although the 2D6 enzyme is the best characterized of the cytochrome P450 enzymes, there are at

least five others, and the SSRIs may be associated with the competitive inhibition of some of them as

noted above. Fluvoxamine is known to inhibit the 1A2 enzyme, which is responsible for the metabolism

of theophylline, caffeine, certain benzodiazepines, and haloperidol. It would therefore be prudent to

use lower doses of theophylline when treating asthmatic patients with fluvoxamine. In addition,

fluoxetine and fluvoxamine are capable of inhibiting the 3A3/4 enzyme, which degrades such common

drugs as triazolo compounds, including alprazolam, triazolam, and trazodone. Increased drowsiness

has been reported in patients treated concurrently with SSRIs and alprazolam, but no serious reactions

have been reported. However, lower doses of the concomitant drugs may be required. At one point, H2

blockers were thought to be particularly problematic vis-à-vis untoward interactions, but this has not

been borne out.

Among the SSRIs, citalopram and escitalopram currently exhibit the least potential for pharmacokinetic

interactions. Citalopram and escitalopram are weak inhibitors of not only cytochrome P450 2D6 but

also 3A3/4, 1A2, and 2C19. With venlafaxine, citalopram shares a low risk of drug interactions, which

has made it popular in the treatment of geriatric patients.

Dosage and Administration

Among the factors that have contributed to the enormous popularity of the SSRIs is that the starting

dose of the drug is frequently the optimal dose as well (Table 3–4). Given the already lengthy latency

of onset of antidepressant action, the SSRIs typically do not require a prolonged titration period in

which to achieve a therapeutic dose, as is common with the TCAs and the MAOIs.

Table 3–4. Selective serotonin reuptake inhibitors (SSRIs) and other available

antidepressants: names, formulations and strengths, and dosages

Generic name Brand name

Formulationsa and

strengths

Usual therapeutic

dosage (mg/day)b

SSRIs

Page 18 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterFluoxetine is usually initiated at 20 mg/day, and the maximum recommended dosage is 80 mg/day. A

citalopram Celexa Tablets: 10, 20, 40 mg 20–40

Oral solution: 10 mg/5 mL

(240-mL bottle)

escitalopram Lexapro Tablets: 5, 10, 20 mg

Oral solution: 5 mg/5 mL (240-

mL bottle)

fluoxetine Prozac Capsules: 10, 20, 40 mg

Capsule (weekly): 90 mg

Oral solution: 20 mg/5 mL

(120-mL bottle)

Tablets: 10, 20 mg

20–60

fluvoxamine Luvox Tablets: 25, 50, 100 mg 100–200

paroxetine Paxil Tablets: 10, 20, 30, 40 mg

Oral suspension: 10 mg/5 mL

(250-mL bottle)

20–50

Paxil-CR (controlled

release)

Tablets: 12.5, 25, 37.5 mg

sertraline Zoloft Tablets: 25, 50, 100 mg

Oral concentrate: 20 mg/mL

(60-mL bottle)

50–200

5-HT2

antagonists

nefazodone Generic only Tablets: 50, 100, 150, 200,

250 mg

300–500

trazodone Desyrel and generic

Tablets: 50, 100, 150,c 300c

mg

150–300

Other

bupropion Wellbutrin and generic

Wellbutrin SR

(sustained-release)

Wellbutrin XL

(extended-release)

Tablets: 75, 100 mg

Tablets: 100, 150, 200 mg

Tablets: 150, 300 mg

200–450

mirtazapine Remeron Tablets: 7.5, 15, 30, 45 mg

Soltabs: 15, 30, 45 mg

15–45

venlafaxine Effexor

Effexor-XR (sustained

release)

Tablets: 25, 37.5, 50, 75, 100

mg

Capsules: 37.5, 75, 150 mg

75–375

duloxetine Cymbalta Capsules: 20, 30, 60 mg 60–120

Note. 5-HT2 = serotonin2 receptor.

aNot available in an injectable form.

bDosage ranges are approximate. Many patients will respond at relatively low dosages (even dosages

below those in ranges given above); others may require higher dosages.

cTrazodone also available in 150- and 300-mg divided-dose formulations.

Page 19 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterreview of the efficacy data from double-blind studies of the use of fluoxetine in the treatment of major

depression revealed that fluoxetine produced maximal benefits at 20–40 mg/day, with lesser benefit

noted at 60 mg/day. In fact, 60 mg/day appeared to be less effective and to have more side effects

than did 20–40 mg/day. Because 20 mg was often effective and the drug has a long half-life, the

manufacturer finalized the recommended initial dosing at 20 mg/day for 3 weeks, with subsequent

increases to 40–80 mg/day if indicated. Patients with significant psychomotor retardation often seem

to require at least 40 mg/day. In other patients, 10 mg/day may be effective. The drug is currently

available in 10-mg, 20-mg, and 40-mg capsules, as well as in 10- and 20-mg tablets and in a

suspension. Dosages as low as 2 mg/day can be obtained with the suspension, and this is particularly

useful in patients who cannot initially tolerate higher dosages. Patients who have failed to respond to a

lower dosage (20 mg) may subsequently improve if the dosage is increased to 40–60 mg/day (Fava et

1. 1994).

A few years ago a 90-mg, once-weekly form of fluoxetine was introduced. This form was designed to

be an alternative to daily treatment with fluoxetine at 20 mg/day and is meant for use in the

maintenance phase of treatment only. There are patients who prefer taking one capsule weekly rather

than daily. Taking one capsule every 3 days appears roughly equivalent to 40 mg/day. Some patients

take two capsules per week on the same day to achieve the equivalent of 40 mg/day. (It is unclear

whether taking two 90-mg capsules equals 40 mg/day.) However, staggering the dose every 3 days

decreases side effects. Dosing the weekly form of fluoxetine every 3 days appears to be well tolerated.

Dosing of paroxetine is much like that of fluoxetine, with an initial dosage of 20 mg/day. The

immediate-release form of the drug is currently available in 10-mg, 20-mg, 30-mg, and 40-mg tablets.

The tablets are scored, and patients intolerant of a full tablet can have the dose reduced to a half

tablet for 2–3 weeks. If no response is seen, the dosage may then be increased each week by 10–20

mg/day until a maximum dosage of 50 mg/day is achieved. Data suggest that patients with more

serious depressions require higher dosages (30–50 mg/day). Controlled-release (CR) paroxetine is

currently available in 12.5-mg, 25-mg, and 37.5-mg tablets, which are equivalent to the 10-mg, 20-

mg, and 30-mg immediate-release tablets, respectively. (At one point since the last edition, the CR

formulation was taken off the market because of quality control issues during the manufacturing.)

Citalopram is dosed at 20–60 mg/day. The new version of citalopram, escitalopram (Lexapro), is more

potent and is generally dosed at 10–20 mg/day. The side effects of escitalopram at 20 mg/day roughly

equal those seen with citalopram at 40 mg/day.

The dosage range for sertraline is somewhat wider than that for fluoxetine, paroxetine, and citalopram.

In addition, a more linear dose-response curve separates sertraline from the other SSRIs, which have

a relatively flat dose-response curve. Therapy is usually initiated at 50 mg/day, although, as with the

other SSRIs, a lower starting dosage is sometimes required. The 50-mg dose may be continued for 2

weeks, and if no response is seen, the dosage may then be increased weekly by 50 mg/day until a

maximum dosage of 200 mg/day is achieved. Sertraline is available in 25-mg, 50-mg, and 100-mg

tablets as well as a concentrate. The different tablet strengths are priced similarly. Thus, it is typically

more economical to prescribe the scored 100-mg tablets and instruct patients to break them in half to

achieve a dosage of 50 mg/day.

Fluvoxamine has a wider dosage range. It is usually initiated at 50–100 mg/day. Because of

fluvoxamine’s short half-life, dosages higher than 100 mg/day require divided doses in order to

optimize drug availability. In premarketing studies, most patients with major depression required

dosages in the range of 100 to 200 mg/day. However, some patients required a dosage as high as

300 mg/day.

Discontinuation

Discontinuation symptoms may be less common with the SSRIs than with the TCAs. However, a

number of case reports and double-blind studies do indicate that a discontinuation syndrome may

Page 20 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapteroccur with the sudden discontinuation of some SSRIs, especially the shorter-acting agents paroxetine,

sertraline, and fluvoxamine.

The most common presentation of an SSRI discontinuation syndrome is a flulike condition with

malaise, nausea, and headaches occurring within 2–7 days of stopping an SSRI. Paresthesias,

dizziness, agitation, and rebound depression have also been reported when the drugs are suddenly

discontinued. The mechanism underlying these symptoms is unclear. Because of paroxetine’s greater

effect at the serotonin transporter, shorter half-life, and anticholinergic properties, discontinuation

symptoms may be more common with this agent than with the other SSRIs. Fluoxetine’s very long

half-life and citalopram’s medium half-life may diminish the risk of discontinuation symptoms with

these drugs. Of the SSRIs, fluoxetine may be stopped abruptly without much risk of difficulty.

However, for the shorter-acting SSRIs, it may be prudent to taper the drugs over several weeks,

particularly if the patient required a prolonged titration upward as a result of adverse effects. Tapering

by 25% of the dose per week for doses greater than 30 mg of paroxetine, 100 mg of sertraline, and

150 mg of fluvoxamine is quite reasonable if it is practical to do so. In trials of 4 weeks or less, faster

taper schedules can be tried, and most patients will not require a taper.

If discontinuation symptoms occur, the first step may be to increase the dose to the previous dose and

taper more gradually. Often, resuming the previous dose will resolve the discontinuation symptoms

within 48 hours. Occasionally, clinicians have substituted a longer-acting agent such as fluoxetine for a

shorter-acting agent such as paroxetine in patients with substantial discontinuation symptoms.

However, there are no good data on the safety or efficacy of this approach.

In starting an MAOI after discontinuing an SSRI, a safe washout period depends on the half-life of the

drug and its metabolites. For fluoxetine, the manufacturer has recommended waiting 5 weeks when

changing from fluoxetine to an MAOI. This period is five times the half-life of the active metabolite of

fluoxetine, norfluoxetine. It is conceivable that a shorter period (e.g., 3 weeks) may suffice, but no

data are available. The other SSRIs are shorter acting than fluoxetine, and a 2-week washout appears

adequate. When going from an MAOI to an SSRI, a period of 2 weeks of no MAOI is recommended

before starting the SSRI.

A common question in clinical practice is, Does it make sense to switch from one SSRI to another if

one is not working? Although the practice of switching from one SSRI to another is common, very few

prospective, controlled data are available to support the practice. Clearly, however, patients who are

intolerant of one SSRI may achieve benefit by being switched to another. Brown and Harrison (1995)

reported that patients may respond to sertraline after not responding to fluoxetine. The largest study

to date to examine the question of switching to another SSRI after failing the first is STAR*D (Rush et

1. 2006). In that study, 727 patients who failed to achieve remission while taking citalopram were

switched to either sertraline, venlafaxine, or bupropion. The remission and response rates when

patients were switched to sertraline were about the same as those for when patients were switched to

venlafaxine or bupropion. While this open study design may contribute to one-comparison agents

tending to consistently look similar in outcome, the study does support that switching within the class

of SSRIs may be as good as switching outside the class. Thase and colleagues (1997) found that

patients who had a poor response to an initial trial of sertraline often achieved a good response when

switched to fluoxetine. As many as 50% of patients who do not respond to one SSRI may respond to

another. However, melancholic inpatients who do not respond to an adequate trial of an SSRI appear

to have a much lower chance of responding to another SSRI. Along the same lines, Sacchetti et al.

(1994) found that patients with recurrent major depression were far more likely to respond to the

same SSRI they had responded to in a previous episode than they were to respond to a different SSRI.

For example, if a patient had responded to fluoxetine in the index depressive episode, he or she had

about a 90% chance of responding to fluoxetine in a subsequent episode but only a 50% chance of

responding to fluvoxamine. It is unclear from the report whether patients were blinded to the

challenge. It is evident that many patients in clinical practice who start off taking one SSRI will end up

Page 21 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chaptertaking another agent. In a retrospective review, at least 25% of patients treated with one SSRI

subsequently ended up taking another SSRI (Nurnberg et al. 1999c). The authors concluded that the

SSRIs were not interchangeable, since patients who discontinue one SSRI because of either lack of

efficacy or lack of tolerability may do well with another agent. Likewise, in another study, 91% of

patients who were intolerant to fluoxetine tolerated sertraline (Brown and Harrison 1995).

5-HT

2 RECEPTOR ANTAGONISTS (TRAZODONE AND NEFAZODONE)

Another class of antidepressants act as 5-HT2 antagonists (Figure 3–2; Table 3–5) and have a number

of other direct effects on 5-HT receptors that distinguish these agents from the SSRIs. The class

currently includes the phenylpiperazine nefazodone and the triazolopyride trazodone. Trazodone was

synthesized in Italy in the mid-1960s and eventually released to the U.S. market in 1981. It

represented the first 5-HT-specific agent in the United States. Nefazodone was synthesized in the

1980s by Bristol-Myers Squibb (BMS) with the specific intent of improving the side-effect profile of

trazodone. Nefazodone became available in the United States in 1995. In December 2001, the FDA

issued a “black box” warning about the risk of hepatoxicity associated with nefazodone, In late 2003,

BMS withdrew Serzone from markets in the United States and Canada, but nefazodone is still available

generically.

Pharmacological Effects

The pharmacology of the 5-HT2 antagonists is somewhat more complex than the name implies, and

questions still remain. The principal effect of both trazodone and nefazodone appears to be antagonism

of the postsynaptic 5-HT2A and 5-HT2C receptors. Nefazodone is the more potent antagonist. This

antagonism causes a paradoxical downregulation of 5-HT2 sites, which may explain the antidepressant

effects of such 5-HT2 antagonism. The 5-HT2 receptor is also linked with other receptors, including the

5-HT1A receptor, which is thought to be important in depression, anxiety, and violent behavior. There

Table 3–5. The serotonin

2 (5-HT2 ) antagonists

Drug Starting dosage(mg/day) Maximum dosage (mg/day)

trazodone (Desyrel) 50–100 600

nefazodone (Serzone) 50–100 600

Figure 3–2.

Chemical structures of serotonin2 (5-HT2 ) antagonists.

Page 22 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapteris growing evidence that both nefazodone and trazodone stimulate the 5-HT1A site, possibly through

antagonizing the 5-HT2 receptor. In addition to their effects as 5-HT2 antagonists, both trazodone and

nefazodone block the reuptake of 5-HT to some extent. Although the inhibition of the 5-HT transporter

with these two drugs is weak in comparison to that of the SSRIs, it may be clinically significant.

Finally, m-chlorophenylpiperazine (m-CPP), a major active metabolite of both nefazodone and

trazodone, is a potent direct agonist of 5-HT, mostly at the 5-HT2C receptor, which may contribute

both to the efficacy of the drugs and to their side effects.

Indications

The primary indication for both trazodone and nefazodone is major depression. There are more than

two dozen double-blind, placebo-controlled studies of trazodone and at least eight double-blind studies

of nefazodone that establish the efficacy of these drugs in the treatment of major depression. Most of

these studies suggest that trazodone and nefazodone are as effective as comparison drugs, primarily

the TCAs, in the treatment of major depression. However, many of the controlled studies have involved

outpatients with mild to moderate major depression, and there have been persistent questions about

the efficacy of trazodone in the treatment of more severely depressed patients. Some investigators

have suggested that trazodone is not particularly helpful for retarded depressions. However, a review

of efficacy studies (Schatzberg 1987) found that there appeared to be no difference between TCAs and

trazodone in the treatment of depressed inpatients and of those with more classic endogenous

features. Interestingly, the studies that reported the poorest results with trazodone used aggressive

dosing, with dosages that reached a total of 300–450 mg in the first week of treatment. Thus,

trazodone may be effective and is better tolerated at lower rather than higher doses, particularly at

first. At least one study has also concluded that nefazodone is effective in the treatment of more

severely depressed inpatients (Ansseau et al. 1994).

Both trazodone and nefazodone appear to be effective anxiolytic agents. The antianxiety effects of the

drugs are often evident earlier than the antidepressant effects. A comparison of low-dose trazodone

with chlordiazepoxide for general anxiety suggested that the two agents had equal efficacy (Schwartz

and Blendl 1974). Likewise, one study suggested that trazodone compared favorably to imipramine

and diazepam in the treatment of GAD (Rickels et al. 1993). In depressed patients, anxiolytic effects of

nefazodone were noted at dosages less than 250 mg/day (Fontaine et al. 1994), but trazodone, an

antidepressant, has shown significant utility as a hypnotic at doses of 25–100 mg at night. Because

trazodone is quite sedating and does not have an addiction potential, it offers a safe alternative to the

benzodiazepines. Likewise, trazodone has been used successfully to treat SSRI- and MAOI-induced

insomnia.

Next to depression, the best-studied disorder treated with nefazodone is PTSD. Currently, nefazodone

is among the more common agents prescribed in treating PTSD because of the sleep disturbance,

agitation, and comorbid problems of substance abuse and depression. At least six open-label studies of

nefazodone in the treatment of PTSD suggested that the drug can help ameliorate nightmares and

hyperarousal and decrease anger (Hidalgo et al. 1999). Dosages ranging from 300 to 600 mg/day

appear to be efficacious, and large controlled trials are under way to determine their efficacy.

Nefazodone does not share trazodone’s utility as a hypnotic, because the former is generally less

sedating. However, preliminary data (Armitage et al. 1994) suggested that nefazodone, unlike many

psychotropics, may enhance rapid eye movement (REM) sleep and therefore may increase restful sleep

in some patients.

Case reports suggest a number of other potential roles for nefazodone. Nefazodone has been reported

to be useful in the treatment of social phobia, panic disorder, and PMDD and as an adjunctive agent in

the treatment of negative symptoms of schizophrenia.

Side Effects

Page 23 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterAlthough the 5-HT2 antagonists are 5-HT-specific agents, they differ from the SSRIs in mechanism of

action and thus in side-effect profile as well (Table 3–6). One common side effect of all currently

available serotonergic antidepressants is GI upset. The incidence of nausea with trazodone and

nefazodone is less than that found with the SSRIs. However, it was still the leading cause for

discontinuation of nefazodone in prerelease trials. Higher doses of trazodone, particularly when taken

on an empty stomach, may also be correlated with nausea. As with the SSRIs, the GI side effects of

these drugs are lessened by taking them with food.

As reported, neither trazodone nor nefazodone has particularly strong anticholinergic effects. They can,

however, produce dry mouth because of their 1 -adrenergic receptor blockade. (Salivation is controlled

by both the acetylcholinergic and the noradrenergic systems.) The 1 -adrenergic blockade may also

result in significant orthostasis with trazodone, especially in elderly persons. Dizziness and even frank

syncope may occur in patients taking large doses of trazodone on an empty stomach, as well as in

some elderly patients taking nefazodone. It is therefore useful to monitor blood pressures for

orthostasis with vulnerable patients and to encourage proper hydration. Support stockings may also be

helpful. The incidence of orthostasis with nefazodone is thought to be lower than with trazodone.

However, orthostasis has been reported with higher doses of nefazodone and in vulnerable patients.

Trazodone also differs from nefazodone in the amount of sedation it produces. As described, trazodone

is very sedating and is useful as a hypnotic at modest doses. Nefazodone may produce daytime

somnolence, but this usually occurs at higher doses. Shifting the bulk of the dose to bedtime will

mitigate this problem.

CNS activation is generally reported not to be a problem with either drug. However, patients who are

deficient in the cytochrome P450 2D6 enzyme or who are taking SSRIs may experience activation

secondary to the effects of the metabolite m-CPP, which is cleared by this enzyme. We have also seen

some patients develop dysphoric activation on nefazodone, even without recent exposure to the SSRIs.

Therefore, starting nefazodone at lower doses appears prudent.

Table 3–6. Common or troublesome side effects of trazodone and nefazodone

Gastrointestinal

Nausea

Dyspepsia

Liver failure (nefazodone—rare)

Adrenergic blockade

Orthostasis (trazodone >> nefazodone)

Dizziness

Neurological

Headaches

Visual trails (nefazodone > trazodone)

CNS depression

Sedation (trazodone >> nefazodone)

CNS activation

Restlessness (nefazodone > trazodone)

Sexual

Priapism (trazodone)

Note. >> = much greater than; CNS = central nervous system.

Page 24 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterMore than 200 cases of priapism have been reported in males treated with trazodone. Although rare,

priapism—with an incidence of 1 per 6,000 patients—is very problematic. Risk of trazodone-associated

priapism is thought to be higher in younger males with prolonged erections in the morning upon

awakening or who can have frequent erections over a relatively short period (several hours). Some

patients may require surgical intervention. The acute treatment involves injection of an -adrenergic

receptor agonist (e.g., epinephrine) into the penis. If not treated promptly, priapism may result in

permanent impotence. Male patients should thus be warned to stop the drug immediately if they

experience any symptoms suggestive of priapism (occasional erections are not problematic) and to

seek emergency room treatment if the erection persists longer than 1 hour. At least one case of clitoral

priapism has also been reported (Pescatori et al. 1993).

Since priapism is mediated via adrenergic pathways, nefazodone is thought to present less of a

problem than trazodone in this regard. There have been no reports of nefazodone-induced priapism,

but there have been isolated reports of prolonged erections in men and reports of increased nocturnal

penile tumescence. A case of clitoral engorgement, but not priapism, with nefazodone has also been

reported.

Sexual side effects generally appear to be rare with nefazodone. In fact, it is difficult to demonstrate

that the rate of sexual dysfunction with nefazodone treatment is any higher than with placebo

treatment. Feiger and colleagues (1996) found that sertraline and nefazodone were comparable in

antidepressant efficacy. However, sertraline had negative effects on sexual function, whereas

nefazodone had none.

Visual side effects may also occur in up to 12% of patients taking nefazodone. These side effects often

take the form of an afterimage during tracking of moving objects. Interestingly, the afterimage during

tracking may be a serotonin-enhancing effect, because other agonists, such as lysergic acid

diethylamide (LSD), also produce this effect. Patients should be told that the visual side effects

generally improve with time.

In 1999, there was an isolated report at one center of three patients being treated with nefazodone

who sustained liver failure. The patients were all women between the ages of 16 and 57 who were

treated with 200–400 mg of nefazodone for a period averaging several months (Aranda-Michel et al.

1999). All patients showed significant hepatocellular damage, and two of the three underwent liver

transplants. The third recovered without transplantation. In at least one of the patients, a concomitant

medication could have contributed to hepatotoxicity. Since that first report, a number of other cases

have emerged that led the FDA to advise BMS that they must include a black box warning in the

package insert that alerts the public about the risk of severe liver toxicity. The risk is estimated at

about 1/250,000 for every patient-year of treatment with nefazodone. In other words, if a quarter

million patients were taking nefazodone for a year, one patient would be expected to develop

potentially severe liver damage. While these odds are very small, this is about three to four times the

background rate for severe liver damage, and use of nefazodone dropped dramatically with the black

box warning. BMS voluntarily removed Serzone from the market, but nefazodone is still available

generically. Many antidepressants, including TCAs, have rarely and idiosyncratically been associated

with fulminant hepatic failure. There do not appear to be clear demographic variables that predict

hepatic toxicity from a given antidepressant. However, in any patient with a history of hepatic

difficulties, it is prudent to obtain baseline liver enzymes and monitor these periodically. Nefazodone

should not be prescribed in any patient with a history of liver disease. We are frequently asked

whether a patient who has done well while taking nefazodone should continue the medication. We have

not routinely taken patients who have responded to the drug off the medication. If there is a

reasonable alternative to nefazodone, it should be considered. If alternatives have been unsuccessful

or poorly tolerated, it may be particularly reasonable to continue the nefazodone while informing the

patient of the known risk. Patients should also be educated about symptoms of liver illness, including

jaundice, anorexia, GI disturbance, and malaise, and the drug should be discontinued if there are any

Page 25 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chaptersymptoms suggesting toxicity.

Overdose

Trazodone and nefazodone appear to have a wide safety margin in cases of overdose. Doses as high as

10 g of trazodone have been taken without untoward incidents. The lethal dose in animals averages

500 mg/kg.

Although the risk of fatal overdoses with nefazodone or trazodone is very small, a number of reports

suggest that the combination of trazodone and other CNS depressants, such as alcohol, can be lethal

when taken in overdose. The usual cause of death is respiratory depression. Although a trazodone

overdose alone can result in a seizure or respiratory arrest, the lethal dose in animals approaches half

of body weight, or about 500 mg/kg. Nefazodone has been taken in overdoses of up to 12 g, or 20

times the maximum daily dose, without serious effects.

Drug Interactions

The 5-HT2 antagonists are fairly safe in terms of drug interactions. Trazodone may potentiate the

effects of other CNS depressants and lead to excessive sedation. Similarly, the postural hypotension

associated with trazodone is exacerbated by concurrent antihypertensive agents, and such

combinations should be monitored with frequent checks of orthostatic blood pressure. Because both

the 5-HT2 antagonist drugs have proserotonergic effects, there is a theoretical risk of precipitating a

serotonin syndrome with the MAOIs, particularly at higher doses. However, neither trazodone nor

nefazodone is a potent catecholamine reuptake inhibitor (although nefazodone has some reuptake

inhibition); therefore, the risk of hypertensive crises with concurrent use of 5-HT2 antagonists and

MAOIs is low.

Nefazodone is a potent inhibitor of the cytochrome P450 enzyme 3A3/4. As stated previously, this

enzyme is responsible for the metabolism of such common drugs as the triazolobenzodiazepines

alprazolam and triazolam, ketoconazole, erythromycin, and carbamazepine. The combination of

nefazodone and anti-arrhythmics, pimozide, or ziprasidone may enhance cardiac toxicity. Concurrent

use of nefazodone with these agents may raise serum levels, and clinicians should exercise caution in

combining these drugs.

Occasionally, switching from the SSRIs to 5-HT2 -antagonist drugs, particularly nefazodone, may be

problematic. One of the metabolites of nefazodone is m-CPP, which is metabolized via the cytochrome

P450 2D6 enzyme. Increased serum levels of m-CPP have been associated with dysphoric agitation.

Thus, simultaneous use of an SSRI and nefazodone, either current or recent (before the washout

period has ended), may be poorly tolerated in some patients. Fluoxetine can contribute to elevated

levels of m-CPP for 4–5 weeks after it is discontinued, and the other SSRIs may have this effect for 1–

2 weeks after they are discontinued. Therefore, it would be useful, ideally, to have a washout period

between stopping an SSRI and starting nefazodone. However, an alternative strategy is to allow no

washout period but start with smaller dosages of nefazodone (50–100 mg/day) and titrate upward

more gradually after discontinuing the SSRI.

Dosage and Administration

The manufacturer recommends starting trazodone at 150 mg/day and then increasing the dosage up to

600 mg/day (Table 3–5). Our experience has been that the drug is quite sedating, and we begin

patients at 50 mg/day and increase the dosage to 150 mg/day by day 7. Thereafter, each week, we

increase the daily dosage by 50–75 mg, up to 300 mg/day. In our experience, patients respond at a

modal dosage of 150–300 mg/day.

Because of trazodone’s short half-life, the optimal dosing for the treatment of depression is in two or

three divided doses a day. The bulk of the dose may be taken at bedtime to mitigate daytime

somnolence.

Page 26 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterSome investigators have proposed that trazodone has a therapeutic window; as with nortriptyline, too

high plasma levels are associated with poor responses. Our experience suggests this may be so, and

several studies have supported a correlation between plasma levels and efficacy (Monteleone and

Gnocchi 1990; Spar 1987). Steady-state trazodone plasma levels above 650 ng/mL may be ideal for

antidepressant response. However, more study is needed to determine whether it is worthwhile to

obtain trazodone plasma levels routinely.

The manufacturer’s recommended starting dosage of nefazodone is 100 mg bid. However, we

recommend starting at 50 mg bid or lower and increasing the dose by 50 mg every 4 days to reach

200 mg/day. Thereafter, each week, the daily dosage may be increased by 100 mg until a therapeutic

dose is achieved. Minimal therapeutic antidepressant dosage is 300 mg/day, and most patients will

require at least 400 mg/day. Thus, it is reasonable to titrate the dosage to 400 mg/day and then

maintain this dosage for 3–4 weeks. If a response is not observed, the dosage may then be further

increased to a maximum of 600 mg/day. The initial dosage in elderly patients should be 50 mg/day.

Some patients may feel too sedated or activated at 100 mg bid, but they are often able to tolerate an

initial dosage of 50 mg bid. Therefore, we have recently come to start all patients routinely at 50–100

mg/day. The manufacturer recommends bid dosing, but some practitioners prescribe the drug to be

administered nightly, and this appears particularly feasible once patients have been on a steady

dosage for a few weeks. A slow-release formulation is being developed that would allow once-a-day

dosing. However, at the time of this writing, a once-a-day formulation is not available.

Discontinuation

Discontinuation syndromes appear uncommon for both trazodone and nefazodone but have been

reported. Some case reports suggested that the rapid discontinuation of trazodone may occasionally

lead to withdrawal symptoms, particularly rebound insomnia (Otani et al. 1994). As with the SSRIs,

there have been reports of paresthesias and dizziness associated with the sudden discontinuation of

nefazodone (Benazzi 1998; Kotlyar et al. 1999; Lauber 1999). Therefore, it is generally prudent to

taper these medications rather than to stop them suddenly. The total daily dose of nefazodone and

trazodone can be decreased by 50–100 mg each week.

SEROTONIN-NOREPINEPHRINE REUPTAKE INHIBITORS

(VENLAFAXINE AND DULOXETINE)

Venlafaxine (Effexor) (Figure 3–3) is a phenylethylamine that was released to the U.S. market in 1994.

In 1998, it became available in an extended-release form (Effexor XR), which is taken once a day.

Along with its FDA indication for the treatment of depression, Effexor XR became the first

antidepressant approved for the treatment of GAD and has also been approved for the treatment of

social anxiety disorder. In the past several years, venlafaxine has been growing in popularity as a drug

with an efficacy and mechanism of action that may be similar to those of TCA drugs without the safety

or side-effect liability of the TCAs.

Figure 3–3.

Chemical structures of the serotonin-norepinephrine reuptake inhibitors venlafaxine and duloxetine.

Page 27 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterDuloxetine (Cymbalta) is an SNRI that was released in 2004 after a long delay. Like venlafaxine, it has

little affinity for other neurotransmitter receptors such as muscarinic or histaminic receptors. However,

it is a relatively more potent norepinephrine reuptake inhibitor (NRI) than is venlafaxine. Whether this

increased potency translates into improved efficacy is unclear. Initially, we see duloxetine as an

antidepressant that will be a first-line agent in depressed patients who have comorbidities such as pain

or stress incontinence. Duloxetine also makes sense as a first-line agent for patients with serious

depressions, including those with melancholic and psychotic subtypes. We suspect it will have an

important role to play in treating resistant depression. Over time, both venlafaxine and duloxetine may

become first-line agents for less severe depression as well.

A third SNRI, milnacipran, is under investigation in the United States for the treatment of fibromyalgia.

Studies overseas have documented the efficacy of milnacipran in depression. While other drugs are

under investigation for the treatment of fibromyalgia, milnacipran is farthest along in development and

most likely to secure the first FDA approval for this condition.

Pharmacological Effects

In contrast to the SSRIs, the potent 5-HT-blocking effects of venlafaxine are complemented by mild to

moderate effects on norepinephrine reuptake. In contrast, duloxetine is a potent 5-HT and

norepinephrine reuptake inhibitor. Several other pharmacological properties distinguish the SNRIs. For

example, the SNRIs promote a rapid downregulation of -adrenergic receptor–coupled cAMP (cyclic

adenosine monophosphate). This effect may correlate with an earlier onset of action for the SNRIs, as

some premarketing studies have suggested. In addition, venlafaxine is more weakly bound to protein

(27%) than are other antidepressants; this weaker binding may decrease the likelihood of displacing

tightly bound drugs, such as warfarin and phenytoin. Venlafaxine shares with citalopram and

escitalopram a very low potential for pharmacokinetic drug interactions because it is not a potent

inhibitor of any cytochrome P450 hepatic enzymes.

Indications

The SNRIs have proved useful in the treatment of both outpatients with major depression and

inpatients with melancholia. Given the ongoing debate about the utility of the SSRIs for more seriously

depressed inpatients, the SNRIs appear to provide a safe and effective alternative to the TCAs in

treating melancholic patients. In one study, venlafaxine appeared to be markedly more effective than

fluoxetine in the treatment of melancholic inpatients (Clerc et al. 1994). In addition, venlafaxine was

shown to be effective in some 35% of patients with treatment-refractory depression (Nierenberg et al.

1994).

Although it has generally been difficult to reliably demonstrate differences between SSRIs and

venlafaxine in overall response rates in individual studies, there may be some differences in overall

remission rates. Thus, a 50% reduction in score on a standard rating scale, such as the HDRS (a

standard measure of efficacy in antidepressant trials), may not reflect differences in remission rates

in a given 6- to 8-week antidepressant trial. A meta-analysis found that venlafaxine was more likely to

result in remission of symptoms than either TCAs or SSRIs (Einarson et al. 1999). In a meta-analysis

by Thase et al. (2001), it was concluded that venlafaxine was significantly more effective than SSRIs in

effecting remission. As indicated previously, a more recent meta-analysis indicated that venlafaxine

may be more effective than fluoxetine but not other SSRIs (Nemeroff et al. 2003).

Like venlafaxine, duloxetine appears to be an effective antidepressant and may be more efficacious on

some measures than are SSRIs. Several but not all double-blind studies have now demonstrated the

utility of duloxetine, particularly at achieving remission of depressive symptoms relative to placebo. In

a 9-week trial, duloxetine 60 mg administered once daily was compared with placebo in treating

patients with major depression. By the end of 9 weeks, 44% of 123 duloxetine-treated patients had

achieved remission, compared with only 16% of the 122 patients receiving placebo (Detke et al.

2002). In a second trial, 173 patients were randomized to treatment with duloxetine up to 120

Page 28 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chaptermg/day, fluoxetine 20 mg/day, or placebo for 8 weeks. Duloxetine appeared to be more likely to

achieve response and remission than either fluoxetine or placebo (Goldstein et al. 2002).

A second FDA indication for Effexor XR is for the treatment of GAD. All five controlled trials of Effexor

XR in the treatment of GAD reported to date have shown superiority to placebo and sometimes to

comparison drugs such as buspirone (Davidson et al. 1999; Diaz-Martinez et al. 1998). Some studies

indicated that relatively low dosages of Effexor XR (75–150 mg/day) are useful in the treatment of

GAD, and most patients obtain some benefit within 2 weeks, with additional improvement often seen

over the next 6 weeks of treatment. Studies out to 6 months have reported significantly greater

efficacy for Effexor XR over placebo, with many patients continuing to improve beyond their acute

responses (Gelenberg et al. 2000). Venlafaxine is approved for the treatment of social anxiety

(Altamura et al. 1999; Lenderking et al. 1999). Likewise, venlafaxine has some demonstrated efficacy

in the treatment of PTSD, including PTSD that has failed to respond to an SSRI (Hamner and Frueh

1998). While the efficacy of duloxetine in the treatment of anxiety disorders is not fully established,

duloxetine would be expected to be of utility in treating the same types of anxiety disorders as is

venlafaxine. However, the noradrenergic effects of duloxetine may be difficult for some anxious

patients to tolerate.

Venlafaxine was approved for the treatment of social anxiety disorder in 2003. As with the SSRIs, the

effects of venlafaxine on social anxiety may be at least as large as its effects in depression and GAD.

Since the mechanism of action of the SNRIs is similar to that of the TCAs, the SNRIs also have utility in

treating some pain conditions. Venlafaxine has been studied in the treatment of neuropathic pain,

fibromyalgia, and other chronic pain conditions (Davis and Smith 1999; Kiayias et al. 2000; Pernia et

1. 2000). Venlafaxine appears to be about as useful as the TCAs and superior to the SSRIs for chronic

pain. Dosages over 150 mg/day are often required. Duloxetine also appears to be useful in the

treatment of some somatic and pain symptoms. In a study by Detke and colleagues (2002),

duloxetine-treated patients had not only an improvement in their depression but a significant reduction

in shoulder pain, back pain, and pain that interfered with daily activities. It is likely that, as with the

TCAs, the improvement in pain was independent of the improvement in depression. Indeed, studies of

duloxetine in the treatment of diabetic neuropathy have shown clear benefit, and duloxetine was

approved for the treatment of neuropathy shortly after it was approved for the treatment of

depression. The drug has also been reported to be effective in treating fibromyalgia.

The SNRIs have been studied for use in other disorders. For example, a number of studies suggest that

venlafaxine may be effective in both childhood and adult attention-deficit/hyperactivity disorder

(ADHD) at dosages of 150–300 mg/day. Like other antidepressants that appear useful in ADHD,

including desipramine and bupropion, venlafaxine lacks disadvantages of drugs such as

methylphenidate that have some potential for abuse and require Drug Enforcement Administration

triplicate forms.

Another condition duloxetine may be valuable in treating is stress urinary incontinence. In fact,

duloxetine is approved outside the United States for treating stress urinary incontinence. In a large

trial involving 533 women, duloxetine at dosages of 20–80 mg/day was superior to placebo in reducing

the frequency of incontinence episodes. Duloxetine-treated patients had up to a 64% decrease in

incontinence episodes, while placebo-treated patients had a 41% decrease (Norton et al. 2002). The

differences from placebo were even greater in patients who had a high baseline frequency of

incontinence episodes.

Side Effects

The SNRIs share many of the side effects of the SSRIs. For example, GI side effects are common with

the SNRIs. In fact, duloxetine and venlafaxine may have a somewhat greater propensity for causing

nausea than do some of the SSRIs. As with the SSRIs, adaptation to this side effect occurs rapidly, in

the first 2–3 weeks of therapy. While some early work suggested a lower rate of sexual side effects

Page 29 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterwith duloxetine than with the SSRIs, this seems doubtful to us. Any potent serotonin reuptake inhibitor

can cause sexual side effects, and both SNRIs are potently serotonergic. It is not likely that the

noradrenergic effects of the drug will mitigate the serotonin-dependent sexual side effects.

One side effect that differs from those of the SSRIs is treatment-emergent hypertension with

venlafaxine. This noradrenergically mediated side effect occurs in about 5% of patients at dosages of

venlafaxine (immediate release) less than 200 mg/day and in 13% of patients at dosages greater than

300 mg/day in venlafaxine-treated patients. The increase in blood pressure is usually modest, with an

an average increase in diastolic blood pressure of about 5–7 mm Hg with venlafaxine at high doses and

about 2 mm Hg with duloxetine. Nonetheless, it is important to monitor blood pressure, particularly in

the first 2 months of treatment at higher doses, particularly with the immediate-release venlafaxine.

We have seen some patients with a rise in blood pressure of 20–30 mm Hg. In general, there is little

evidence that preexisting hypertension predisposes a patient to greater increases in blood pressure

with the addition of venlafaxine (Thase 1998). Reducing the dose is often helpful. If it is not feasible to

do so, clinicians should consider adding a -blocker or an -blocker. The impression is that

hypertension has been less problematic with the extended-release formulation, perhaps reflecting

lower total daily doses or lack of peak effects.

An even less common side effect reported with venlafaxine is syncope. Syncope might reflect a Na

channel effect in genetically susceptible individuals. If syncope occurs, the patient’s medication should

be switched to one outside the class of SNRIs.

The more potent noradrenergic effects of duloxetine also result in a variety of anticholinergic-like side

effects, including dry mouth, constipation, and urinary retention. Elderly males might be particularly

susceptible to retaining urine and should be monitored.

Overdose

Fatal overdoses with venlafaxine, as with the SSRIs, are exceedingly rare but are occasionally

reported. As with the SSRIs, moderate overdoses of less than 30 times the daily dose tend to be more

associated with GI upset than with other symptoms. Gastric lavage is often helpful in these cases of

moderate overdose. More substantial overdoses involving 10 g or more have sometimes resulted in

seizures (Bhattacharjee et al. 2001; Gittelman and Kirby 1993; Mainie et al. 2001) and a serotonin

syndrome (Spiller et al. 1994). In the United Kingdom, there has been considerable concern about the

safety margin of venlafaxine in overdoses (Buckley and McManus 2002). Recently, a warning about risk

for lethality in overdose was added to venlafaxine’s package insert; the mechanism is unclear. There

have been no reported fatal overdoses of duloxetine thus far. Doses up to 1,200 mg have been treated

with lavage and supportive care.

Drug Interactions

The SNRIs can precipitate a serotonin syndrome when combined with the MAOIs, and this combination

is therefore contraindicated. Similarly, 2 weeks should elapse after stopping an MAOI before starting

an SNRI. Because venlafaxine has a short half-life (5 hours for venlafaxine and 11 hours for its major

metabolite, O-desmethylvenlafaxine), a 1-week washout is sufficient before starting an MAOI.

Venlafaxine and duloxetine are weak inhibitors of cytochrome 2D6. Like citalopram and escitalopram,

the SNRIs do not appear to be potent inhibitors of other hepatic enzymes. However, both duloxetine

and venlafaxine are metabolized by the 2D6 enzyme and, to some extent, the 1A2 enzyme as well.

Therefore, cimetidine, paroxetine, or other drugs that inhibit the metabolism of 2D6 could result in a

more pronounced increase in blood pressure or other side effects. Venlafaxine can increase haloperidol

blood levels, but this is not mediated by an effect on the 1A2 or 2D6 enzymes. Rather, it may be an

effect on excretion.

Dosage and Administration

Page 30 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterThe manufacturer recommends that the extended-release formulation of venlafaxine (Effexor XR) be

initiated at 37.5 mg. Thereafter, doses can be increased by 37.5 mg every 3 days or 75 mg per week

until a dosage of 150 mg/day is reached. Beyond that, increases should be at a rate of 75 mg per

week. Although the manufacturer suggests that elderly patients do not require a lower starting dosage,

many geriatric psychiatrists have found that a starting dosage of 37.5 mg/day is better tolerated.

Increase of dosage should be gradual. For the extended-release formulation of venlafaxine, the

maximum recommended dosage is 225 mg/day; for the immediate-release form, it is 375 mg/day. We

recommend using the extended-release formulation. Most depressed outpatients appear to respond to

dosages in the range of 75 to 225 mg/day. Therefore, if no response is seen at the starting dosage for

2 weeks, the dosage may be titrated upward in 37.5-mg increments every 3 days or so, as tolerated.

In premarketing studies, the dosage was sometimes increased rapidly to the maximum dosage in the

first week of treatment. This rapid titration was sometimes associated with a more rapid onset of

action, but it also was poorly tolerated in many cases. Venlafaxine does have a linear dose-response

curve, and higher dosages are associated with greater response (as well as more prominent side

effects). Inpatients with melancholic depression and patients with depression refractory to other

treatments often require dosages closer to the maximum dosage of 375 mg/day (for the immediate

release form) administered in divided doses. On occasion we have used even higher dosages (450–600

mg/day) without problem.

We have tried a variety of doses of duloxetine in clinical trials. In general, starting the duloxetine at 30

mg in the morning with food is a reasonable approach. After 3–7 days, we increase the dosage to 60

mg/day. Some patients have less nausea at 30 mg bid, but most patients can manage 60 mg taken

once daily. It is reasonable to keep the dosage at 60 mg/day for 4 weeks before going up to

90 mg/day and then 120 mg/day in divided doses. However, dosages above 60 mg/day are not

necessarily more effective than 60 mg/day.

A recent trial compared venlafaxine (immediate release) and duloxetine in the treatment of major

depression. Starting dosages were 75 mg/day of venlafaxine and 60 mg/day of duloxetine. Duloxetine

was associated with twice as high a rate of dropout due to side effects as venlafaxine. These data

suggest that 30 mg/day of duloxetine is equivalent to 75 mg/day of venlafaxine. Unpublished data

from Lilly indicate that side effects of duloxetine are reduced dramatically by administering with food.

Discontinuation

The relatively short half-life of venlafaxine may predispose patients to an increased risk of

discontinuation symptoms when the drug is stopped suddenly (Boyd 1998; Dallal and Chouinard 1998;

Macbeth and Rajagopalan 1998). Significant dizziness has been reported with rapid discontinuation, as

have paresthesias and the typical SSRI withdrawal symptoms. Therefore, the manufacturer advises

tapering the dose for any patient who has been taking the drug for longer than 7 days. For patients

taking venlafaxine for more than 2 weeks, a gradual taper over at least a 2-week period is advised,

and some patients may require a 4-week taper or longer. Decreasing the dosage by 37.5 mg every 3

days or 75 mg per week circumvents withdrawal symptoms in many patients. Switching to sertraline

(Luckhaus and Jacob 2001) or supplementing the antiemetic ondansetron (Raby 1998) may also help.

In the double-blind studies of duloxetine, rapid discontinuation was associated with expected

symptoms. Thus a gradual taper schedule with this agent should be routinely instituted.

COMBINED NORADRENERGIC-DOPAMINERGIC ANTIDEPRESSANT

(BUPROPION)

Bupropion (Wellbutrin) is a unicyclic antidepressant (Figure 3–4) that was in the process of being

released in 1986, but its release was delayed pending an evaluation of its risk of inducing seizures. It

was not released until mid-1989, when it became clear that the increased seizure risk was dose related

and tended to occur in specific populations. In 1998, bupropion became available in a sustained

release formulation (Wellbutrin SR) that allows twice-a-day administration and also appears to

decrease the risk of seizures to about that associated with SSRIs. In 2003, bupropion became available

Page 31 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterin an extended-release formulation (Wellbutrin XL) for once-a-day dosing. In 2003, a once-a-day

formulation (Wellbutrin XL) became available.

Pharmacological Effects

Bupropion is not a 5-HT reuptake blocker and does not inhibit monoamine oxidase. Its biochemical

mode of action is not completely clear. It was hypothesized to act via dopamine reuptake blockade;

however, its dopamine-potentiating effects in animals appear to occur at very high dosages and blood

levels, well beyond those routinely used in humans. The dopamine reuptake–blocking properties of

bupropion are an order of magnitude less than those of sertraline. When dopamine effects were

demonstrated in humans in one study, these effects appeared to be related to possible psychotic

reactions to the drug rather than to its antidepressant responses. Nonetheless, the dopaminergic

effects may be important, because the plasma levels of homovanillic acid, the primary metabolite of

dopamine, decrease in patients who respond to bupropion but not in patients who do not respond

(Golden et al. 1988).

In recent years, the noradrenergic effects of bupropion have become increasingly evident. The major

active metabolite of bupropion, hydroxybupropion, does appear to block the reuptake of

norepinephrine in rats. Earlier studies, involving mice, failed to show an effect on norepinephrine, but

this species metabolizes the drug differently. Indirect evidence for an effect on noradrenergic activity

also comes from data showing that the drug decreases 24-hour excretion of norepinephrine

metabolites.

Indications

Bupropion appears to be effective in many types of depression. It has demonstrated utility in

outpatients with mild to moderate depression as well as in inpatients with more severe depression. The

drug appears to be safe in depressed cardiac patients. There have been reports that the drug is less

likely to produce mania or rapid cycling, but episodes of mania on bupropion do occur. Conversely,

bupropion has been reported not to induce rapid cycling in patients with bipolar disorder. Since head

to-head comparisons of bupropion and other antidepressants are lacking in the treatment of bipolar

depression, it is difficult to fully assess bupropion’s proclivity for inducing mania relative to that of

other agents. Still, for the treatment of bipolar depression, bupropion is a reasonable first-line agent in

addition to mood stabilizers.

The second FDA indication for bupropion is in smoking cessation. Two controlled clinical trials indicate

that the sustained-release formulation of bupropion (which is also marketed under the trade name

Zyban) administered at 300 mg/day aids in smoking cessation (Goldstein 1998). More than 3,000

patients were studied in a clinical trial of the sustained-release formulation of bupropion in the

treatment of smoking cessation. As with the treatment of depression, the benefits of sustained-release

bupropion are not immediate and take several weeks or longer to be evident. After 7 weeks of

Figure 3–4.

Chemical structure of bupropion.

Page 32 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chaptertreatment, more than twice as many patients on bupropion 300 mg/day (36%) were abstinent from

nicotine as patients administered placebo (17%). At 26-week follow-up, only 19% of bupropion-treated

patients and 11% of placebo-administered patients remained abstinent from smoking. These results

mirror those commonly seen in smoking cessation studies with nicotine preparations. In a recent trial,

we reported that bupropion was no better than placebo in achieving smoking abstinence in

adolescents. However, bupropion appeared to significantly decrease nicotine use (Killen et al. 2004).

The drug is being studied for appetite suppression.

The most recent indication for bupropion is in the treatment of seasonal affective disorder (SAD). SAD

has historically been treated with phototherapy, antidepressants, and mood stabilizers. However, there

had been no FDA-approved therapy for this disorder until the approval of bupropion XL. Studies

indicate that by starting treatment of bupropion while patients are well, the drug appeared to prevent

relapse and time to onset of new depressive symptoms when compared with placebo (Modell et al.

2005). Since some patients with SAD may have illness that falls in the bipolar spectrum, we have

found that a mood stabilizer such as lamotrigine or lithium can also be helpful, although there are few

empirical data for the use of a mood stabilizer.

Another fairly common use of bupropion is in the treatment of ADHD. Bupropion appears to be

effective in the treatment of ADHD in both adults and children (Cantwell 1998). Since bupropion is

metabolized to a number of amphetamine-like products, it appears to be a safe alternative to

stimulants in the treatment of ADHD. In adolescents who have comorbid substance abuse problems,

bupropion might be the first-line treatment (Riggs et al. 1998).

Two important uses of bupropion are as an adjunct to SSRI treatment to augment the antidepressant

effect and as an adjunct to counteract the sexual side effects of SSRIs. Bupropion does appear to

augment SSRI antidepressant effects and is generally less complicated to use than is either lithium or

thyroid supplements. The STAR*D study found that bupropion added to an SSRI was helpful but that it

was no more helpful than a parallel nonrandomized track in which buspirone was added (Trivedi et al.

2006). (Bupropion augmentation is discussed in greater detail in Chapter 9: “Augmentation Strategies

for Treatment-Resistant Disorders.”)

Bupropion is unique among the antidepressants in that it is probably not effective in the treatment of

anxiety disorders. One pilot study of bupropion in the treatment of panic disorder yielded negative

findings (Sheehan et al. 1983). To our knowledge, no recent studies have examined the efficacy of

bupropion in the treatment of panic disorder. Many anxious patients find bupropion too activating and

prefer other agents.

Bupropion’s metabolism is probably dependent on a number of hepatic enzymes; therefore,

interactions with the SSRIs may be less problematic than once thought. Still, there has been at least

one case report of a seizure being associated with the combination of fluoxetine and bupropion.

Side Effects

Bupropion has a favorable side-effect profile, in part because of its low affinity for muscarinic, –

adrenergic, and histaminic receptors. The only side effects of the sustained-release bupropion that

occurred reliably more commonly than with placebo in clinical trials of 100–300 mg/day were insomnia,

dry mouth, and tremor. The insomnia is best managed by moving the evening dose to earlier in the

afternoon. A separation of at least 8 hours between the morning and evening dose is advised.

Bupropion does not induce orthostatic hypotension or stimulate appetite. Some investigators have

argued that bupropion could be particularly useful in patients who gain weight while taking other

agents. There are reports that patients with sexual dysfunction who are taking other antidepressants

do better with bupropion, and, again, the drug has been reported to counteract SSRI-induced sexual

dysfunction.

Seizures for the immediate-release formulation of the drug have been reported at the rate of 4 per

Page 33 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapter1,000 at dosages less than 450 mg/day; this risk increased to 4 per 100 when the dosage was

increased above 450 mg/day. The sustained-release formulation, which has largely supplanted the

immediate-release formulation, appears to carry a seizure risk of about 1 per 1,000 patients at

dosages less than 400 mg/day. This risk is similar to the seizure risk associated with most

antidepressants. The risk of seizures appears to be enhanced in patients with a prior history of seizure

disorders, head injury, bulimia, and anorexia. Concurrent use of alcohol, stimulants, or cocaine also

enhances the risk of seizures in these patients. The manufacturer also cautions that single doses of the

drug should never exceed 150 mg for the immediate-release formulation and 200 mg for the

sustained-release preparation. The XL formulation may be taken as a single dose of up to 450 mg.

Overdose

Bupropion has proved relatively safe in overdose. However, there have been cases of completed

suicide with bupropion alone (Rohrig and Ray 1992). In some cases, patients who overdosed on

bupropion had significant neurological complications, including seizures and status epilepticus (Spiller

et al. 1994; Storrow 1994). Thus, some caution should be exercised in prescribing large supplies of

bupropion for suicidal patients.

Drug Interactions

Serious drug interactions are uncommon with bupropion. Bupropion is metabolized by the cytochrome

P450 2B6 enzyme, which is responsible for metabolizing very few drugs (orphenadrine and

cyclophosphamide). Thus, potential pharmacokinetic interactions with other antidepressants or general

medicines are unlikely.

Any drug that lowers the seizure threshold should be used cautiously with bupropion. Thus, drugs such

as clozapine, theophylline, and clomipramine should be used cautiously or avoided with bupropion.

Likewise, it may be prudent to avoid the use of bupropion in patients who are dependent on alcohol or

benzodiazepines, since sudden discontinuation of these drugs in the context of concurrent bupropion

use can increase seizure risk.

The use of an MAOI and bupropion is contraindicated. There appears to be an enhanced risk of general

toxicity with phenelzine and bupropion and a greater risk of hypertensive crises.

Dosage and Administration

Bupropion has a relatively wide usual dosage range (i.e., 200–450 mg/day). The modal optimum

dosage range in our experience has been 300 to 400 mg/day. Bupropion is available in an immediate

release formulation (75-mg and 100-mg tablets); in a sustained-release preparation (Wellbutrin SR)

(100-mg, 150-mg, and 200-mg tablets) given twice daily; and in an extended-release once-daily

formulation (150-mg and 300-mg tablets).

MIRTAZAPINE

Mirtazapine (Remeron), which was released in the United States in 1996, is chemically related to

mianserin, a drug that has been used for a number of years in Europe. Mirtazapine is FDA approved for

the treatment of depression but appears to be useful for a variety of other disorders. Although it did

not emerge as among the more popular antidepressants during the late 1990s, mirtazapine has

established important niches in clinical practice.

Pharmacological Effects

Mirtazapine has a tetracyclic chemical structure (Figure 3–5) but is unrelated to the TCAs. Its

mechanism of action is fairly unusual among the available antidepressants. It appears to be an

antagonist of central presynaptic 2 -adrenergic receptors. As an 2 -adrenergic receptor blocker,

mirtazapine acts to increase norepinephrine release. The increased noradrenergic tone results in a

rapid increase in synaptic 5-HT levels by mobilizing 5-HT release secondary to stimulation of 1 –

Page 34 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapteradrenergic receptors on 5-HT cell bodies. Mirtazapine also blocks 5-HT2 and 5-HT3 receptors.

Mirtazapine is not a specific reuptake blocker of any monoamine neurotransmitter. However, it does

appear to be a potent antagonist of H1 receptors—a feature that confers some of the drug’s more

problematic side effects. Mirtazapine does not have particularly strong anticholinergic effects and does

not significantly block postsynaptic -adrenergic receptors. As a result, postural hypotension is

generally not associated with mirtazapine use.

Mirtazapine is available in 7.5-mg, 15-mg, 30-mg, and 45-mg tablets. A quick-dissolving wafer

formulation (Remeron SolTabs) has been released.

Mirtazapine is well absorbed from the GI tract and extensively metabolized to at least four active

products. Each of these metabolites, including the most common, desmethylmirtazapine, is less active

than the parent drug. Mirtazapine is metabolized by cytochrome P450 2D6, 3A3/4, and 1A2 enzymes

but is neither an inducer nor an inhibitor of these hepatic enzymes (Fawcett and Barkin 1998). Thus, it

can be taken safely with other psychotropic agents.

Indications

In premarketing trials of mirtazapine, which involved several thousand patients, the drug appeared to

be as effective as the TCAs amitriptyline and clomipramine. Both outpatients with milder depression

and more severely depressed inpatients respond to mirtazapine. Compared with trazodone,

mirtazapine appears to be superior in the treatment of depressed inpatients (van Moffaert et al. 1995).

Mirtazapine has also been studied in treating brief recurrent depression, which meets all of the DSM-IV

(American Psychiatric Association 1994) criteria for major depression except for the time criterion.

Brief depression lasts less than 2 weeks but tends to recur many times in the course of a year.

Mirtazapine at low doses appears, on the basis of case reports, to effectively treat these depressive

episodes (Stamenkovic et al. 1998). Other subtypes of depression, including atypical depression and

seasonal depression, may also be responsive to mirtazapine (Falkai 1999).

More recent studies have directly compared mirtazapine with SSRIs in the treatment of depression

(Fava et al. 2001; Leiononen et al. 1999; Quitkin et al. 2001; Wheatley et al. 1998). Mirtazapine was

reported to be comparable in efficacy to fluoxetine, paroxetine, and citalopram and in each study was

slightly, though not significantly, more effective. Compared with the SSRIs, mirtazapine may have

more rapid anxiolytic and antidepressant effects (Thompson 1999). With mirtazapine, in contrast to

citalopram and paroxetine, the antidepressant and antianxiety effects are sometimes seen by the

second week. A meta-analysis by Thase (2003) found that mirtazapine was significantly more effective

than SSRIs.

Since mirtazapine, with its greater propensity for sedation and weight gain, is often used after SSRIs,

the STAR*D study evaluated the utility of mirtazapine for achieving remission after the failure of two

Figure 3–5.

Chemical structure of mirtazapine.

Page 35 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chaptertrials (Fava et al. 2006b). Mirtazapine was as effective (or ineffective) as nortriptyline in achieving

remission after two failed antidepressant trials. The remission rate for mirtazapine on the HRSD at this

late stage of the study was only 8%.

Additionally, the dropout rate from adverse effects with mirtazapine appears to be usually similar to

that with the SSRIs.

We reported on a comparison of paroxetine and mirtazapine in elderly depressive patients (Schatzberg

et al. 2002). Mirtazapine was associated with significantly earlier response and fewer dropouts due to

adverse events than was paroxetine.

Preliminary data from open-label trials suggest that mirtazapine is useful for most of the anxiety

disorders that are responsive to SSRIs or venlafaxine. For example, mirtazapine may be useful in the

treatment of panic disorder, with or without concurrent depression (Carpenter et al. 1999b). Patients

with depression and comorbid GAD appear to do well when taking mirtazapine at dosages of 15–45

mg/day (Goodnick et al. 1999). Pilot studies of mirtazapine for PTSD also appear promising (Connor et

1. 1999).

Another potential use for mirtazapine is in augmenting antidepressant effects. Because of its low risk of

pharmacokinetic interaction, mirtazapine should be relatively easy to combine with many

antidepressants. The drug, with its complex pharmacology, may complement antidepressants that act

more specifically. Preliminary data have shown that mirtazapine effectively augments SSRIs (Carpenter

et al. 1999a). In the STAR*D trial, the combination of mirtazapine (average dosage = 36 mg/day) with

venlafaxine (average dosage = 210 mg/day) resulted in remission-level responses in just 13% of

patients who had failed three consecutive antidepressant trials (McGrath et al. 2006). This result was

similar to the remission rate found for tranylcypromine in patients who had failed three trials. However,

the venlafaxine-mirtazapine combination was better tolerated than the tranylcypromine.

Mirtazapine had been reported to help reverse SSRI-induced sexual side effects (Farah 1999), but a

more recent double-blind trial failed to show benefits of mirtazapine in treating sexual side effects

(Michelson et al. 2000). In addition, the drug has been reported to help improve negative symptoms in

schizophrenia (Berk et al. 2001) and to ameliorate antipsychotic-induced extrapyramidal symptoms.

Side Effects

Mirtazapine has generally been well tolerated in clinical studies. The most common side effects are dry

mouth, sedation, somnolence, and weight gain. More than half of all patients treated with mirtazapine,

compared with less than 20% of patients treated with placebo, experienced somnolence. Somnolence

is more evident at lower doses than at higher doses because antihistaminic effects predominate

relative to noradrenergic or serotonergic effects at dosages below 15 mg/day. Thus, vis-à-vis sedation,

a starting dosage of 30 mg/day is often better and usually not more poorly tolerated than a dosage of

7.5 mg/day. A trial in Europe did compare mirtazapine at dosages of 15 mg/day and 30 mg/day and

found no differences in sedation between the two groups.

Weight gain and increased appetite are clear problems for some patients taking mirtazapine. In short

term trials of 6–12 weeks, about 20% of patients treated with mirtazapine reported increased appetite,

and 7.5% of patients had an increase in weight of at least 7%. In our clinical experience, at least 20%

of patients gain weight with long-term use of mirtazapine. The most reliable strategy for controlling

weight when taking mirtazapine is controlling appetite and exercise. The notion that higher doses of

mirtazapine may be less problematic for weight gain is less clear than the effects on somnolence.

Some clinicians anecdotally report that the use of H2 antagonists, such as ranitidine 150 mg bid,

mitigates the weight gain associated with mirtazapine, but this approach is untested. Likewise, some

clinicians use stimulants or sibutramine (Orlistat) to help control weight. However, sibutramine is a

serotonergic drug and may increase the risk of serotonergic side effects, while stimulants generally

require triplicate form prescriptions and have an established abuse potential. Weight gain in the elderly

Page 36 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterappears to be less common.

The effects of mirtazapine on cholesterol and triglycerides have become better recognized in recent

years. About 15% of patients demonstrate a significant (>20%) increase in cholesterol, and 6% of

patients experience a significant increase in triglycerides. It is thus worthwhile to obtain fasting

triglyceride and cholesterol levels at baseline and periodically with treatment, especially for patients

with known hypercholesterolemia or who have a history of high triglyceride levels. Concurrent use of

an HMG-CoA (3-hydroxy-3-methylglutaryl-coenzyme A) reductase inhibitor such as atorvastatin

(Lipitor) has been anecdotally reported to reduce the cholesterol and lipid effects of mirtazapine at

dosages of 10–80 mg/day. Unless the benefits of mirtazapine are substantial, however, it may be

easier to switch to another agent if there are clinically significant increases in cholesterol or triglyceride

levels.

Along with bupropion and nefazodone, mirtazapine is one of the few antidepressants that have limited

sexual side effects. Switching from an SSRI to mirtazapine appears to resolve sexual dysfunction

associated with the use of an SSRI (Koutouvidis et al. 1999). There are case reports that indicate that

adding mirtazapine at dosages of 15–30 mg/day to an SSRI can mitigate SSRI-induced sexual side

effects (Koutouvidis et al. 1999). However, a more recent double-blind trial of mirtazapine in treating

SSRI-induced sexual side effects showed no benefit over placebo (Michelson et al. 2002).

Orthostatic hypotension, or conversely hypertension, is occasionally seen in patients treated with

mirtazapine. About 7% of patients experience significant dizziness, and some of this may be from

postural changes. It is worthwhile to occasionally monitor blood pressure in patients treated with

mirtazapine, particularly elderly patients. Other rare but significant side effects associated with

mirtazapine include elevations in hepatic transaminases in about 2% of patients—a rate similar to that

seen with SSRIs. Worries about agranulocytosis at the time of release of the drug to the market have

not been borne out.

Overdose

Mirtazapine appears to be fairly safe in overdose. We are unaware of fatal overdoses with mirtazapine

in doses of up to 2 g. The most common effect of overdose with mirtazapine is sedation. Gastric lavage

and supportive management have thus far been adequate in dealing with overdoses.

Drug Interactions

As indicated earlier, mirtazapine has a low risk of pharmacokinetic interactions. The most common

interaction is synergism with other CNS depressants. Concurrent benzodiazepines, barbiturates, or

alcohol increases the risk of significant somnolence and sedation. The combination of mirtazapine and

a CNS depressant also has an additive effect on motor impairment.

The proserotonergic effects of mirtazapine impart a potential risk of serotonin syndrome, although this

risk is largely obviated via its blocking 5-HT2 and 5-HT3 postsynaptic receptors. The 2 -noradrenergic

effects pose a risk of hypertensive crises when the drug is used in combination with an MAOI. As a

result, mirtazapine should be discontinued for at least 2 weeks before an MAOI is started and vice

versa.

Dosage and Administration

Although the recommended starting dosage is 15 mg/day, we now advise starting most patients at 30

mg/day. Geriatric patients and those with severe insomnia should be started at 15 mg/day.

Mirtazapine is administered once a day, about 1 hour before bedtime. The dose may then be increased

by 15 mg every 2 weeks to the maximum recommended dosage of 45 mg/day. In Europe, the

maximum dosage of the same drug is 60 mg/day, and we will sometimes push the dose to this level in

patients with treatment-resistant conditions.

NOREPINEPHRINE REUPTAKE INHIBITORS:REBOXETINE AND

Page 37 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterATOMOXETINE

Reboxetine, a selective NRI antidepressant, has been in use for many years in Europe and South

America. Similarly, atomoxetine (Strattera) is an NRI approved for the treatment of ADHD. Neither of

the these agents is approved for the treatment of depression in the United States, but both have been

studied as potential antidepressants here. The American experience with both atomoxetine and

reboxetine as antidepressants or adjunctive treatments to serotonergic antidepressants has been

uneven. Monotherapy trials based in the United States have not been consistent in showing a benefit

for either NRI in the treatment of depression. For reboxetine, a U.S. trial with statistically significant

results was reported, but the effect size was small. Atomoxetine monotherapy trials have generally

failed. Likewise, although some small open-label studies have found benefit of atomoxetine or

reboxetine added to an SSRI in the treatment of resistant depression (Carpenter et al. 2005; Lucca et

1. 2000; Papakostas et al. 2006), a recent study by Michelson et al. (2006) failed to demonstrate

efficacy for atomoxetine augmentation in patients who did not respond to sertraline.

Although neurotransmitter systems are clearly interconnected, it is equally evident that not everyone

who responds to one antidepressant will respond to another. The role of NRIs in the treatment of

depression remains unclear.

Pharmacological Effects

Reboxetine and atomoxetine enhance central norepinephrine neurotransmission by selectively blocking

the reuptake of norepinephrine. They are therefore selective NRIs. There is evidence that reboxetine

directly modulates the activity of the norepinephrine-rich locus coeruleus in the brain.

Alterations in the noradrenergic system have long been noted in depressed patients. For example,

levels of MHPG, the main metabolite of norepinephrine, are often increased in the urine, plasma, and

cerebrospinal fluid of depressed patients relative to control subjects. Abnormalities have been noted in

depressed patients in various norepinephrine receptors, including presynaptic 2 receptors and

postsynaptic 1 and receptors. Most antidepressants, even the SSRIs, are known to have specific

effects on norepinephrine receptors. For example, most antidepressants are known to downregulate

postsynaptic receptors with chronic administration. In fact, this reduction in receptors takes

several weeks and is correlated with the typical lag time of 3–6 weeks needed for antidepressants to

be effective.

Many symptoms of depression may be more closely related to norepinephrine function than to

serotonin function. For example, symptoms such as fatigue, hypersomnia, motoric retardation, and

anhedonia have been hypothesized to be more related to alterations in norepinephrine than to 5-HT,

although both are clearly important (Montgomery 1998). There is a strong interrelationship between

the noradrenergic and serotonergic systems.

Whether a selective NRI is more useful in treating some types of depression than other classes of

agents remains to be seen. However, the selectivity of reboxetine in norepinephrine reuptake makes it

unique among the antidepressants in the United States and Europe.

Indications

The only well-studied indication for reboxetine is for the treatment of major depression. European

studies have compared reboxetine with various antidepressants and placebo. For the treatment of

general depression, reboxetine appeared to be at least as effective as desipramine and fluoxetine

(Massana 1998; Massana et al. 1999). Reboxetine, however, appeared to be superior to fluoxetine in

improving social functioning. In addition, reboxetine was significantly better than fluoxetine in reducing

symptoms of severe depression and melancholic depression. As expected, 1-year data showed that

reboxetine is significantly more effective than placebo in preventing relapse and recurrence.

Although a noradrenergic agent would not necessarily be expected to be an effective treatment for

panic disorder, it is clear that noradrenergic agents such as nortriptyline and desipramine are effective

Page 38 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterantipanic drugs. In double-blind studies comparing reboxetine with placebo in the treatment of panic

disorder, reboxetine appeared to be effective. However, the effects were not seen until after 5 weeks

of continuous treatment, and relatively higher doses of the drug may be required.

Two large-scale U.S. studies produced mixed results. In one, reboxetine had minimal, although

statistically significant, benefit over placebo. Paroxetine appeared to produce greater benefit. In the

other, no difference was seen between reboxetine and placebo. These studies held up expected FDA

approval for reboxetine.

Atomoxetine is approved only for the treatment of ADHD in both children and adults. The

manufacturer, Eli Lilly, studied atomoxetine as a potential antidepressant without demonstrating

consistent benefit. Atomoxetine has also been investigated in the treatment of pediatric enuresis

(Shatkin 2004), Tourette’s syndrome (Niederhofer 2006), and obesity (Gadde et al. 2006).

Side Effects

A specific norepinephrine reuptake blocker would be expected to have a side-effect profile that is

different from those of other classes of antidepressants. Compared with the SSRIs, reboxetine and

atomoxetine are less likely to produce nausea, diarrhea, somnolence, and sexual side effects (Mucci

1997). Unlike the TCAs, reboxetine does not have particularly strong anticholinergic effects. Thus,

relative to the TCAs, reboxetine and atomoxetine are less associated with typical antimuscarinic

effects. However, some common anticholinergic-like side effects, such as dry mouth, are also mediated

by the noradrenergic system. Among the side effects that have been reported more commonly with

reboxetine than with the SSRIs are dry mouth, constipation, urinary hesitancy, and hypotension.

Urinary hesitancy is much more common in males treated with the NRIs than in those treated with

fluoxetine, and caution should be taken in older men. Anecdotally, 1 antagonists such as prazosin and

tamsulosin may reverse the urinary hesitancy associated with the NRIs (Kasper and Wolf 2002). In

rare cases, reboxetine was associated with scrotal shrinkage, reflecting muscle contraction, though this

was not a serious issue with the drug.

The cardiovascular effects of the NRIs appear to be limited, with only 3% of patients reporting

hypertension versus 1% of subjects receiving placebo. Increased heart rate was no more common than

with placebo, but hypotension, although mild, was more common in patients treated with reboxetine

than in those treated with fluoxetine or placebo.

Overdose

Like many of the newer antidepressants, reboxetine and atomoxetine appear to be relatively safe in

overdose. There have been no fatal overdoses attributed to NRI overdose alone at the time of this

writing. However, NRI overdoses are associated with emesis, confusion, and tachycardia.

Dosage and Administration

The starting adult dosage is typically 4 mg bid. For most patients, the starting dose will be the

therapeutic dose. If no response is seen by 3–4 weeks, the dosage may be increased to the maximum

dosage of 10 mg/day. The half-life of the drug suggests bid dosing, although qd dosing can be tried. In

elderly patients, the typical starting dosage is 2 mg bid, with the maximum dosage of 6 mg/day.

Atomoxetine is typically started in adults at 40 mg/day, and the dosage is then increased to 80 mg/day

after at least 3 days at the lower dosage. The usual maximum dosage is 100 mg/day.

Drug Interactions

Because of the lack of significant cytochrome P450 enzyme effects, reboxetine has very little in the

way of pharmacokinetic interactions with other drugs. There may be a synergistic effect in the

combination of NRIs and other stimulating agents such as amphetamine or bupropion. In addition,

there can be synergistic effects of NRIs with a pressor agent or albuterol. The combination of NRIs and

Page 39 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterother antidepressants is largely untested but makes intuitive sense in the treatment of resistant

depression. At least one study of the combination of sertraline and reboxetine in rats indicated that the

combined drugs produced more rapid changes in serotonin and norepinephrine receptors than could be

produced by either drug alone (Harkin et al. 1999).

The use of an NRI with an MAOI is generally contraindicated. Although a serotonin syndrome is

unlikely, it is still possible that an NRI will interact with an MAOI in ways that might be problematic.

There is some speculation that reboxetine might mitigate the hypertensive effects of dietary tyramine

in patients taking MAOIs (Dostert et al. 1997).

Discontinuation

Because of its short half-life, reboxetine may pose a greater risk of causing discontinuation symptoms.

At this time, no specific syndrome has been associated with the abrupt discontinuation of an NRI.

However, given its pharmacokinetic profile, it would be prudent to discontinue the drug gradually. A

suggested taper schedule is to decrease the total daily dose by no more than 2–4 mg each week.

GEPIRONE

Gepirone is an older agent that has been studied in the treatment of anxiety disorders and, more

recently, in depression. Gepirone is in the same chemical class as buspirone but is a more potent 5-

HT1A agonist. An extended-release formulation of gepirone received a nonapprovable letter in 2004 but

could be approved in the future with additional studies. Buspirone, now available generically, was

never fully embraced by psychiatrists as an effective anxiolytic. Nonetheless, the drug was effective for

some patients and was particularly popular in primary care settings. The exact place for gepirone in

psychiatric practice remains to be seen.

In the more than 20 years that gepirone has been studied, its efficacy has been established in

generalized anxiety. More recent studies have suggested that gepirone, compared with placebo, is

effective in the treatment of major depression (Wilcox et al. 1996). It may be as effective as

imipramine in depressed patients (Feiger 1996). Some of the comparisons with placebo have been

significant but not robust. However, gepirone appears to have more robust separations from placebo in

the treatment of atypical depression. In one earlier trial, there was a 62% response rate in patients

with atypical depression treated for 8 weeks with up to 120 mg/day of gepirone versus only a 20%

response rate in placebo-treated patients (McGrath et al. 1994). More recently completed work also

supports the idea that gepirone may be selectively more effective in patients with atypical depression

(Quitkin and Gibertine 2001).

Gepirone has generally been well tolerated in clinical trials. The most common side effect was

dizziness, with some nausea, headache, and lightheadedness reported. Gepirone is probably weight

neutral. The most effective dosage range with the extended-release form for the treatment of

depression has been 40–80 mg/day.

We would consider gepirone as an alternative to bupropion or mirtazapine, in patients concerned about

sexual side effects. In addition, it might be a first-line alternative to the SSRIs in patients with atypical

depression. The role of gepirone as an augmenting agent to the SSRIs has not been assessed but

intuitively makes some sense.

TRICYCLIC AND TETRACYCLIC ANTIDEPRESSANTS

Structures

The chemical structures of TCAs and related compounds are remarkably similar (Figure 3–6).

Desipramine and nortriptyline are demethylated metabolites of imipramine and amitriptyline,

respectively. Amoxapine is a derivative of the antipsychotic loxapine and has an additional fourth ring

off a side chain. Maprotiline is a four-ring compound, with the fourth ring arising perpendicular to the

traditional three rings. Its side chain is identical to that of desipramine.

Page 40 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterTricyclic antidepressants (TCAs): overview

Efficacy Second- or third-line agents for MDD (FDA approved for all)

Panic disorder

OCD (FDA approved for clomipramine)

Pain syndromes

Migraine prophylaxis

Enuresis (FDA approved for imipramine)

Side effects Dry mouth, constipation, urinary retention, blurred vision, confusion

Weight gain

Sedation

Sexual dysfunction

Orthostasis

Tachycardia

Cardiac conduction abnormalities

Dosage and

administration

Individualize with low hs dosing (25–50 mg) for imipramine and amitriptyline.

Increase by 25–50 mg every 3–7 days to target dosage of 150–300 mg/day.

(Nortriptyline should be started at 10–25 mg and increased, as needed, to a

maximum dosage of 150 mg/day.) Monitor levels and ECGs after dose stabilized.

Safety in

overdose

Lethal in overdose (induces arrhythmias).

Lavage and monitor on a cardiac bed for QRS widening.

Discontinuation Flulike and GI symptoms from cholinergic rebound. Reduce by 25–50 mg every 3

days.

Drug interactions CNS depressants: sedation, ataxia

Anticoagulants: warfarin levels

Antipsychotics: TCA and antipsychotic levels

Cimetidine: TCA levels

Clonidine: hypertensive crisis (avoid)

L-Dopa: TCAs absorption

MAOIs: serotonin syndrome (avoid clomipramine; imipramine and amitriptyline

may be used with close monitoring)

Stimulants: TCA levels

Oral contraceptives: TCA levels

Quinidine: arrhythmias (avoid)

SSRIs: TCA levels

Sympathomimetics: arrhythmias, hypertension, tachycardia

Note. CNS = central nervous system; ECG = electrocardiogram; FDA = U.S. Food and Drug

Administration; GI = gastrointestinal; MAOI = monoamine oxidase inhibitor; MDD = major depressive

disorder; OCD = obsessive-compulsive disorder; SSRI = selective serotonin reuptake inhibitor.

Figure 3–6.

Page 41 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterPharmacological Effects

The pharmacological effects of the tricyclic and tetracyclic antidepressants are highly similar. Initially,

particular emphasis was placed on their relative effects in blocking the reuptake of norepinephrine or

5-HT. These differences came to underlie various theories on the biology of depression, particularly the

low-norepinephrine hypothesis versus the low-5-HT hypothesis. In recent years, theories have become

more complex as the pharmacological effects of these drugs have been shown to go beyond their mere

immediate reuptake-blocking effects to include later secondary effects on pre- and postsynaptic

receptors, on second-messenger systems, and on other neurotransmitter systems. Such effects may

account for differences among the various drugs in both their range of efficacy and their side effects.

At one time, the relative effects of norepinephrine reuptake–blocking versus 5-HT reuptake–blocking

were used to explain the relative sedative properties (5-HT) versus activating properties

(norepinephrine) of these drugs. Sedation, which early on was ascribed to serotonergic and

anticholinergic effects, has in part been ascribed to the antihistamine (H1 receptor) actions of TCAs.

Some investigators have argued that weight gain could also be due to H1 receptor–blocking effects.

Chemical structures of tricyclic and tetracyclic antidepressants.

Page 42 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterAnticholinergic effects include dry mouth, constipation, urinary hesitancy, blurred vision, and

confusion. The H2 receptor–blocking effects may play a role in these drugs promoting healing of peptic

ulcers.

The relative norepinephrine reuptake–blocking effects, compared with 5-HT reuptake–blocking effects,

of the non-MAOI antidepressants are summarized in Table 3–7. The relative effects of these agents on

acetylcholine, 1 , H1 , 5-HT1 , and 5-HT2 receptors are summarized in Table 3–8. These potencies

represent best estimates based on receptor-binding and clinical studies. Note that the TCAs currently

available in the United States are relatively weak 5-HT reuptake blockers. Clomipramine is the one

exception to this rule. Indeed, in some in vivo models, TCAs—other than clomipramine—are devoid of

5-HT-blocking effects, as is trazodone. Moreover, recent research points to some of the

antidepressants as having 5-HT receptor–blocking effects, suggesting that some are 5-HT antagonists.

Taken together, laboratory data suggest that the tricyclics—other than clomipramine (see Chapter 6:

“Antianxiety Agents.”)—are weak serotonergic agents. In contrast, the SSRIs are relatively pure 5-HT

reuptake blockers, with little in the way of antagonist effects. Thus, these drugs offer an alternative for

the clinician. The tricyclic and tetracyclic antidepressants are virtually devoid of dopamine reuptake–

blocking effects. Of available antidepressants, only sertraline and bupropion have such effects, and the

effects are somewhat weak. Variations in biological effects help in drug selection, in terms of both

clinical efficacy and side effects. The types of side effects seen with tricyclic and tetracyclic compounds

are summarized in Table 3–9.

Table 3–7. Norepinephrine (NE) and serotonin (5-HT) reuptake–blocking effects of the non

MAOI antidepressants

Antidepressant

Ne 5-HT

amitriptyline

+ ++

amoxapine

++ +

bupropion

+/– 0

citalopram/escitalopram

0 +++

clomipramine

++ +++

desipramine

+++ +

doxepin

+ +

fluoxetine

0 +++

fluvoxamine

0 +++

imipramine

+ ++

maprotiline

++ 0

mirtazapine

+ –

nefazodone

0/+ +

nortriptyline

++ +

paroxetine

+ a

+++

protriptyline

+++ +

sertraline

0 +++

trazodone

0 +

trimipramine

0 0

venlafaxine

+ ++

Page 43 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterNote. Data are approximations of relative activity from in vivo, in vitro, and clinical studies. Data on

clomipramine include results on desmethylclomipramine on both active metabolites with pronounced

effects on noradrenergic systems. In certain in vivo models, the tricyclic antidepressants (other than

clomipramine) and trazodone have been reported not to block 5-HT uptake. MAOI = monoamine

oxidase inhibitor. Strength of effect represented on a scale from 0 (no effect) to +++ (marked effect).

+/– indicates marginal effect.

aEffect at high doses.

Table 3–8. Relative receptor-blocking effects of antidepressants

Antidepressant Ach

1

H

1

5-HT

1

5-HT

2

amitriptyline +++ +++ ++ +/– +/–

amoxapine + ++ + +/– +++

bupropion 0 0 0 0 0

citalopram/escitalopram 0 0 0 0

clomipramine + ++ + 0 +

desipramine + + + 0 +/–

doxepin ++ +++ +++ +/– +/–

fluoxetine 0 0 0 0 +/–

fluvoxamine 0 0 0 0 0

imipramine ++ + + 0 +/–

maprotiline + + ++ 0 +/–

mirtazapine 0 0 +++ + +

nefazodone 0 + 0 + ++

nortriptyline + + + +/– +

paroxetine + 0 0 0 0

protriptyline +++ + + 0 +

sertraline 0 0 0 0 0

trazodone 0 ++ +/– + ++

trimipramine ++ ++ +++ 0 +/–

venlafaxine 0 0 0 0 0

Note. Data are approximations of relative activity from in vivo, in vitro, and clinical studies. ACh =

muscarinic acetylcholine receptor; 1 = 1 -adrenergic receptor; H1 = histamine1 receptor; 5-HT1 =

serotonin1 receptor; 5-HT2 = serotonin2 receptor. Strength of effect represented on scale from 0 (no

effect) to +++ (marked effect). +/– indicates marginal effect.

Table 3–9. Common or troublesome side effects of tricyclic and tetracyclic drugs

Anticholinergic Central nervous system

Dry mouth

Tremor

Constipation

Sedation

Blurred vision

Stimulation

Urinary hesitancy

Myoclonic twitches

Page 44 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterIndications

The principal indication for TCAs and related compounds approved by the FDA for marketing is major

depression. Other FDA-approved indications include anxiety (for doxepin) and childhood enuresis (for

imipramine as an adjunctive treatment). Nonapproved but common uses include insomnia (particularly

for amitriptyline and doxepin), headache (most commonly for amitriptyline, imipramine, and doxepin),

agoraphobia with panic attacks (for imipramine and clomipramine particularly), chronic pain syndromes

(most frequently for doxepin and maprotiline), and bulimia (for imipramine and desipramine).

Imipramine has also been reported to be effective in treating GAD, and trimipramine and doxepin were

once thought to be effective in treating peptic ulcers. The most recently released TCA, clomipramine,

has potent anti–obsessive-compulsive effects, as do the SSRIs, and is FDA approved for that use.

Obviously, these drugs exert rather wide pharmacological effects, which account for their potentially

broad range of actions. (For further discussion of the use of TCAs in the treatment of anxiety disorders,

see the section on antidepressants in Chapter 6: “Antianxiety Agents.”)

Currently, eight tricyclic and two tetracyclic antidepressants are available in the United States. One

tricyclic, clomipramine, is approved for the treatment of OCD but not for depression. It is used

worldwide, however, as a major antidepressant, particularly in cases of refractory depression. Generic

and brand names, formulations and strengths, and therapeutic dosage ranges of the tricyclic and

tetracyclic antidepressants are listed in Table 3–10.

Esophageal reflux

Seizure (maprotiline)

Cardiovascular

Extrapyramidal symptoms (amoxapine)

Orthostatic hypotension

Other

Palpitations

Perspiration

Conduction slowing

Weight gain

Hypertension

Sexual dysfunction

Impotence

Table 3–10. Tricyclic and tetracyclic antidepressants: names, formulations and strengths,

and dosages

Generic name

Brand namea Formulations and strengths Therapeutic dosage range

(mg/day)b

Tricyclics

amitriptyline Elavil Tablets: 10, 25, 50, 75, 100,

150 mg

150–300

clomipramine Anafranil Capsules: 25, 50, 75 mg 100–250

desipramine Norpramin Tablets: 10, 25, 50, 75, 100,

150 mg

150–300

doxepin Sinequan Capsules: 10, 25, 50, 75, 100,

150 mg

Oral solution: 10 mg/mL (120-

mL bottle)

150–300

imipramine Tofranil Tablets: 10, 25, 50 mg 150–300

imipramine

pamoate

Tofranil-PMc

Capsules: 75, 100, 125, 150 mg 150–300

nortriptyline Aventyl, Capsules: 10, 25, 50, 75 mg

50–150

Page 45 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterThe original patents have expired on all of these drugs, and generic preparations are now available

(except for protriptyline). In the United States, use of generic compounds has not been without

controversy. Although generic drugs offered a savings for the consumer, some clinicians questioned

their pharmacological equivalence. One difficulty stemmed from the FDA definition of bioequivalence,

which relies heavily on the demonstration that an identical dosage of a generic preparation produces

blood levels within a specified range (20%–30%) above and below those produced by the original

compound. Even with approved generic preparations, some studies had suggested that they were not

truly equivalent to standard brands. Moreover, pharmaceutical companies were not required to prove

that their generic preparations had equivalence in clinical or biological potency. This area appears to be

less of a problem at present, since generic drug manufacturers have improved their production

methods.

Blood Levels

In past decades, considerable attention has been paid to the use of drug blood levels to monitor

treatment with various psychotropic agents. Currently, blood levels are most commonly used in

patients treated with TCAs, neuroleptics, clozapine, lithium carbonate, and anticonvulsants. Blood

levels have not proved to be useful with the SSRIs and most newer antidepressants. Likewise, blood

levels for benzodiazepines are neither widely available nor commonly used. Drug concentrations are

determined primarily in serum (e.g., for lithium carbonate and anticonvulsants) or plasma (e.g., for

TCAs). In addition to measuring the concentration of neuroleptics in blood, some laboratories measure

the relative binding to dopamine receptors (so-called radioreceptor assays). However, this practice has

not been widely adopted.

Generally, TCA serum levels are determined in blood drawn 8–12 hours after the patient’s last dose, in

an effort to avoid false peaks in blood levels that would occur if blood were drawn immediately after a

patient had taken the medication. Also, plasma levels are most accurate when the blood is drawn after

the patient has achieved steady state—the point at which a specific dose of drug given over a several

day period produces a consistent blood level. For most TCAs, this period is approximately 5–7 days.

Plasma levels can be particularly useful barometers of drug metabolism. There is approximately a 30-

fold difference among human subjects in plasma levels of TCAs produced by a single, fixed milligram

per-kilogram dose of a drug, reflecting the degree to which the slowest and fastest metabolizers differ

in drug absorption and metabolism. The TCAs are metabolized in part via the cytochrome P450 2D6

enzyme. Approximately 5%–7% of the Caucasian population is deficient in this enzyme. In addition,

metabolism of the TCAs is affected by age and by inhibition or activation by other drugs. Obviously,

slow metabolizers (such as elderly persons) are at a higher risk for attaining toxic levels of drugs; fast

Pamelor Oral solution: 10 mg/5 mL

(480-mL bottle)

protriptyline Vivactil Tablets: 5, 10 mg 15–60

trimipramine

maleate

Surmontil Capsules: 25, 50, 100 mg 150–300

Tetracyclics

amoxapine Asendin Tablets: 25, 50, 100, 150 mg 150–400

maprotiline Ludiomil Tablets: 25, 50, 75 mg 150–225

aExcept for imipramine pamoate and protriptyline, all the tricyclic and tetracyclic antidepressants

shown are available generically.

bDosage ranges are approximate. Many patients respond at relatively low dosages (even dosages

below those in the ranges given in table); others may require higher dosages.

cSustained release.

Page 46 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chaptermetabolizers may have difficulty building drug levels. Most patients, however, fall in the middle range

of the normal bell-shaped curve distribution.

The clearest use of TCAs is for patients with more severe major depression. There is little or no

relationship between TCA level and clinical response in patients with nonendogenous depression or in

those with dysthymia. Two types of “positive” relationships between TCA level and clinical response in

endogenously depressed patients have been described in the literature. Glassman et al. (1977)

reported a sigmoidal relationship between response and imipramine plus desipramine levels; clinical

response increases with plasma level up to approximately 250 ng/mL and then levels off thereafter

(Figure 3–7). Glassman et al. reported rates of response of 30%, 67%, and 93% for patients with

plasma levels in the ranges of less than 150, 150–225, and greater than 225 ng/mL, respectively. For

nortriptyline, a curvilinear relationship has been described, as indicated in Figure 3–8. Response

increases with plasma level and then plateaus in the range of approximately 50–150 ng/mL, with a

decrease in response at plasma levels greater than 150 ng/mL. The critical range of 50–150 ng/mL has

been called the “therapeutic window.” Nonresponding patients with plasma levels of approximately 150

ng/mL may respond to a lowering of dosage and plasma level into the window. The decreased

responsivity at levels above the window is not due to side effects. Therapeutic windows have at times

been described for other drugs, but these windows are not as clear as that seen with nortriptyline.

Approximate therapeutic plasma levels for tricyclic and tetracyclic drugs are summarized in Table 3–

11.  

Figure 3–7.

Sigmoidal relationship between clinical response and imipramine plus desipramine plasma levels.

Figure 3–8.

Page 47 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterA number of medications may increase or decrease plasma levels—generally by interfering with or

augmenting liver microsomal enzyme activity. For example, nicotine, barbiturates (including butalbital

[Fiorinal]), chloral hydrate, phenytoin, and carbamazepine induce breakdown of TCAs, and clinicians

should keep this in mind when prescribing TCAs for patients who are taking these compounds. In

contrast, antipsychotics (particularly phenothiazines), the SSRIs, methylphenidate, disulfiram, and

fenfluramine increase plasma levels by slowing drug metabolism in the liver. (Fenfluramine [Pondimin]

was withdrawn from the market in 1997, when “fen-phen” was found to be associated with heart valve

disease.) The SSRIs have become the agents one worries most about, because they are potent

competitive inhibitors of the cytochrome P450 2D6 enzyme and thus may substantially increase TCA

plasma levels. Conversely, TCAs increase phenothiazine plasma levels. Benzodiazepines and

antiparkinsonian medications have little or no effect on TCA levels.

A number of issues arise when one considers plasma level data. For one, studies generally use fixed

milligram-per-kilogram dosing, and consequently it is possible that a patient with a given TCA plasma

level (e.g., 250 ng/mL) taking the drug at a given dosage (e.g., 300 mg/day of imipramine) might well

have responded to a lower dosage and at a lower plasma level. In a sense, then, plasma levels can be

Curvilinear relationship between clinical response and nortriptyline plasma levels.

Table 3–11. Approximate therapeutic serum level ranges for tricyclic and tetracyclic drugs

Drug Serum level (ng/mL)

amitriptyline

100–250a

amoxapine Unknown

desipramine 150–300

doxepin

120–250a

imipramine

150–300a

maprotiline 150–250

nortriptylineb

50–150

protriptyline 75–250

trimipramine Unknown

aTotal concentration of drug and demethylated metabolite.

bHas a clear therapeutic window.

Page 48 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterviewed as barometers of the adequacy of treatment. Patients who are not responding to a 4- to 6-week

trial of imipramine but who have attained a plasma level of 150 ng/mL or less may respond to an

increase in dosage and plasma level to greater than 200 ng/mL. On the other hand, other patients who

are responding at exactly the same dosage and plasma level do not need to have the dosage or plasma

level increased, even if the plasma level is below the therapeutic range. Some investigators have

advocated determining the plasma level for any patient who is responding to a TCA in order to record

that patient’s therapeutic plasma level while taking that drug. This could prove important if the patient

has a recurrence and requires retreatment.

Sometimes a routine check of a TCA blood level in a patient who is clinically much improved and has

only minor side effects reveals a plasma level of greater than 400 ng/mL, and the patient relapses

when the dose is decreased to bring down the plasma level. This result suggests that for that particular

patient, a very high plasma level is necessary for improvement. Indeed, there was a prospective report

that some patients require very high dosages and blood levels for an adequate response, although

there is an inherent risk with this approach.

So far, only amitriptyline shows clear toxicity related to plasma levels around 500 ng/mL. Obviously,

clinical judgment is necessary. An ECG is useful with patients who do well only at very high plasma

levels of the drug, to ensure that cardiac conduction is not seriously affected—that is, to ensure that no

intracardiac conduction slowing takes place.

Formerly, the variation in TCA assays among laboratories was of major importance, because clinicians

were unable to interpret a given value in their laboratories. Major national efforts to cross-validate

results from laboratories have helped, and this problem appears to have resolved.

In summary, plasma levels can provide useful clinical information if the clinician keeps these issues in

mind.

Side Effects

A review in the Physicians’ Desk Reference (PDR) of the package-insert information on each of the

TCAs and related agents indicates their myriad side effects. The side effects can be grouped broadly by

categories: anticholinergic, cardiovascular, and so forth (Table 3–9). This organization is somewhat

artificial, because a single side effect (e.g., sedation) may actually be due to any number of distinct

neurochemical effects (e.g., histamine blockade, increased 5-HT availability, 5-HT2 antagonism) or

combinations of effects. In addition, some side effects may reflect drug action either in the brain or at

the periphery or both (e.g., orthostatic hypotension).

How can clinicians help in the management of side effects? In some patients, particularly those with

complicating medical illness, side reactions may not be entirely controllable or manageable. There are,

however, some things that can be done, particularly for less severe reactions in medically healthy

patients.

One very important issue is attitude. Early on, some psychiatrists commonly had rather negative views

about medication, which were communicated indirectly or overtly to the patient, particularly if the

impetus to try medications had arisen from the patient and not the physician. In our experience, such

attitudes can be troubling to the patient, who must rely on the physician’s belief in the importance of

medication trials and in being able to deal with the side effects. The imperative for clinicians to develop

well-reasoned and balanced views about prescribing drugs has obviated this problem somewhat in

recent years.

A general principle of drug prescribing is that some side effects can be managed by reducing the

dosage or can be avoided by increasing the dosage slowly. In our experience, this is particularly true

for the early emergence of “spaciness,” depersonalization, confusion, orthostatic hypotension, or

marked sedation. If these reactions persist in the presence of more moderate dose escalation, a switch

to another TCA or another class of drug may be necessary. In dealing with anticholinergic side effects

Page 49 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapteror sedation, switching to desipramine seems reasonable. For patients who develop orthostatic

hypotension, nortriptyline is often a useful alternative, because it tends to produce orthostatic changes

at plasma levels above the so-called therapeutic window. Thus, nortriptyline is more easily tolerated

than imipramine, whose orthostatic effects are often produced at low plasma levels (see subsection on

TCA blood levels earlier in this section). Nortriptyline has been used successfully in several studies on

poststroke and geriatric depression.

Peripheral anticholinergic side effects have also been reported as being ameliorated by administering

bethanechol, a procholinergic drug, at dosages of 25–50 mg tid or qid, and generally continuing for as

long as the patient continues to take TCAs. This drug can be particularly helpful to patients with

urinary hesitancy. In cases of anticholinergic deliria, physostigmine (a centrally acting procholinergic

agent) may be administered either intravenously or intramuscularly to clarify the diagnosis.

Blurred vision as a result of TCAs can be treated with 4% pilocarpine drops or with oral bethanechol.

Patients otherwise doing well with maintenance TCA treatment, and therefore likely to be taking the

drug for some time, may require a change in their eyeglass prescription to correct the blurring of

vision.

For severe dry mouth, a 1% pilocarpine solution can be created by mixing the 4% solution available as

eyedrops with three parts water. This solution can be swished around the mouth for a few minutes,

30–60 minutes before an increase in salivation is needed. For example, patients may use this

mouthwash before having to give a lecture. Bethanechol in 5-mg or 10-mg tablets may be

administered sublingually for a similar effect. Although we know of no studies, anticholinergic effects

may be ameliorated with cholinesterase inhibitors.

An important, possibly antihistaminic, side effect of TCAs is weight gain—particularly seen with

amitriptyline and doxepin—which can be difficult to control pharmacologically. Often, patients who

demonstrate this side effect while taking one TCA will continue to gain weight when switched to

another, related drug. In some patients, switching to one of the newer antidepressants may be the

only way to maintain an antidepressant effect and promote weight reduction, because MAOIs also

cause weight gain. Unfortunately, some patients still continue to gain weight while receiving the drug

to which they are showing an antidepressant response. In such cases, support and advice regarding

dieting may be the only recourse. Addition of topiramate may facilitate weight loss.

The two tetracyclic agents, maprotiline and amoxapine, have been reported to produce troublesome

side effects—seizures and extrapyramidal symptoms—that have been less frequently reported with the

standard TCAs. Induced seizures have been reported in a number of single case reports of patients

taking maprotiline. Our group reported on a series of 11 patients with maprotiline-related seizures at

one hospital and a study of all U.S. maprotiline-related seizures (Dessain et al. 1986). In our series,

prolonged treatment (longer than 6 weeks) at high dosages (225–400 mg/day) appeared to be a major

factor. This was confirmed in the U.S. survey. In addition, rapid dose escalation—with the dosage

reaching 150 mg/day within 7 days—was a major factor in the general survey. When these two factors

were eliminated, the risk of seizures appeared to approximate that associated with classic

antidepressants (approximately 0.2%). The manufacturer of maprotiline altered its dosage guidelines,

recommending beginning treatment at 75 mg/day for 2 weeks, a maximum dosage of 225 mg/day for

up to 6 weeks, and maintenance at 175 mg/day or less. The previous dosage schedule was similar to

that of imipramine.

Amoxapine has been reported to produce a number of side effects associated with dopamine receptor

blockade. These side effects are similar to those more commonly found with the neuroleptic loxapine—

for example, galactorrhea, akathisia, and other extrapyramidal symptoms and even a few cases of

dyskinesia. Amoxapine is metabolized to a 7-OH metabolite. In some individuals, alternate

hydroxylation at the 8 position results in the accumulation of a neuroleptic metabolite. Generally

speaking, we recommend tapering or stopping medications if these symptoms occur (see subsection on

Page 50 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterblood levels earlier in this section).

Overdose

Overdoses can result in death. Tricyclics have narrow safety margins, and intracardiac slowing and

arrhythmias may result in death when overdoses are taken. In addition, patients taking overdoses can

demonstrate confusion, deliria, and loss of consciousness.

Dosage and Administration

Having evaluated a depressed patient, the clinician must determine whether TCAs are an appropriate

treatment. In the first edition of this manual, we subscribed to the approach of using a TCA first in the

treatment of endogenous or major depression. As a consequence of the superior safety and tolerability

of the newer agents, particularly the SSRIs, the TCAs were relegated to second-line status in the

second edition. However, some investigators continue to suspect that the TCAs are superior to the

newer agents in the treatment of more serious, melancholic depressive episodes. Although it has been

difficult to demonstrate greater efficacy for TCAs (see “Indications” subsection in section on SSRIs

earlier in this chapter), the jury is still out. Because the vast majority of studies on inpatients and

those with melancholic depression have employed TCAs, these agents still need to be considered early

in the treatment of more serious depression.

The choice of which TCA to use is somewhat a matter of personal preference. There is really

considerable overlap among these various drugs, although some are a bit more stimulating

(desipramine and protriptyline) and others are more sedating (amitriptyline and doxepin). Among the

secondary amines, desipramine and nortriptyline have become two of the most popular TCAs with

which to begin treatment. These two drugs have the most favorable side-effect profiles in the TCA

group. In addition, these two drugs have reliable plasma level data regarding clinical response. On the

other hand, amitriptyline has a very poor side-effect profile secondary to its anticholinergic and

antihistaminic side effects and may not be the best first choice for many patients, especially elderly

ones. With any of these drugs, the clinician is best advised to start with a relatively low dose, which

can then be increased slowly.

For imipramine, the starting doses and regimens vary. One common imipramine regimen is to

prescribe 75 mg/day during week 1 and to increase the dosage weekly, as needed, to 150 mg/day

during week 2, 225 mg/day during week 3, and 300 mg/day during week 4. Another approach is to

start at 50 mg/day, increasing the dosage by 25 mg every few days, as tolerated, to 150 mg/day; and

then, after about 2 weeks, to increase the dosage from 150 mg/day, at a rate of 50 mg every 3 days,

to 300 mg/day. (Similar dosage regimens are recommended for other uses of the drug, such as for

panic and pain.)

In prescribing imipramine for some patients, particularly elderly patients (who may be especially

intolerant or taking other medications), it seems reasonable to begin at 25 mg on day 1 and to

increase to 50 mg on day 2, allowing the patient to become acclimated to a single small dose. We also

advise a more conservative schedule of increases for elderly patients, keeping the dosage at 50

mg/day for 1 week and thereafter increasing it at a rate of 25 mg every 2 days to 150 mg/day. After 7

days at 150 mg/day, the dosage can be increased further as tolerated. Elderly patients present a

somewhat distinctive problem regarding drug-drug interactions (see Chapter 12, “Pharmacotherapy in

Special Situations”). The not uncommon medical problems of elderly persons and their relatively slow

drug metabolism usually dictate conservative management. However, clinicians must be careful: some

elderly patients are not slow metabolizers, but instead require reasonably high dosages and therefore

are at risk of being undertreated. The degree of side effects can be a useful barometer of the ability to

tolerate a given dosage, and plasma levels may aid in prescribing optimal doses (see subsections on

TCA blood levels and side effects earlier in this section).

For doxepin, amitriptyline, and trimipramine, dosage ranges similar to those for imipramine are

Page 51 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterrecommended in both younger and older patients. Trimipramine has a relatively low side-effect profile

in elderly patients and has a rapid effect on promoting sleep.

Protriptyline and nortriptyline are prescribed in rather different ways. For younger patients,

protriptyline is generally started at 15 mg/day (5 mg tid) in week 1, with an increase each week of 5–

10 mg in the daily dose, to a maximum dosage of 60 mg/day. For elderly patients, protriptyline is

generally begun at 10 mg/day, aiming for a maximum dosage of 30–40 mg/day. Nortriptyline, which is

the only TCA that clearly has a so-called therapeutic window, can be ineffective if plasma levels are

either too low or too high. The therapeutic dosage range for nortriptyline in adults is 50–150 mg/day.

We recommend starting at 50 mg/day and weekly increasing the daily dosage by 50 mg to 100

mg/day. (In elderly patients, begin at 25 mg/day and increase the dosage to 50 mg/day after 3–4

days.) After 3 weeks, a decrease in dosage may actually be helpful—a situation rather different from

that of the other TCAs (see subsection on TCA blood levels earlier in this section).

Amoxapine’s starting dosage in healthy adults is 150 mg/day, with a maximum dosage of 400 mg/day.

A few patients have been treated with up to 600 mg/day. However, this dosage increases the risk of

seizures. This drug may be particularly effective in treating psychotic depression (Anton and Sexauer

1983).

Maprotiline’s starting and maximum dosages are 75 and 225 mg/day, respectively. To avoid seizures,

the starting dose of maprotiline should be maintained for 2 weeks, and after 6 weeks of treatment, the

dosage should be reduced to a maximum of 175 mg/day (Dessain et al. 1986).

Discontinuation

In discontinuing or tapering TCAs, it is most prudent to do so at a maximum rate of 25–50 mg every

2–3 days. Many patients will demonstrate symptoms of cholinergic rebound if the TCA is discontinued

too abruptly. These symptoms include nausea, queasy stomach, cramping, sweating, headache, neck

pain, and vomiting. We have observed several patients who experienced intense GI symptoms during

and after TCA withdrawal. For these patients, propantheline bromide (15 mg tid prn) was extremely

helpful. Moreover, Nelson et al. (1983) reported that some patients demonstrate “rebound” hypomania

or mania with sudden cessation of TCAs, an observation confirmed by others.

When the issue of rebound symptoms versus a medical illness or recurrence of psychiatric symptoms is

in doubt, a single dose of the discontinued drug will often relieve the symptoms rapidly, confirming the

diagnosis of a withdrawal syndrome. There is one report in which withdrawal mania responded to

reinstitution of desipramine therapy (Nelson et al. 1983).

MONOAMINE OXIDASE INHIBITORS

Pharmacological Effects

The first-generation MAOIs—isocarboxazid, phenelzine, and tranylcypromine—have few direct effects

on reuptake or receptor blockade. Instead, they inhibit MAO in various organs, exerting greater effects

on monoamine oxidase A (MAO-A)—for which norepinephrine and 5-HT are primary substrates—than

on MAO-B, which acts primarily on other amines (e.g., phenylethylamine) and dopamine. Also, MAO-A

is found in the gut mucosa and is responsible for degrading various amines that can act as false

neurotransmitters and produce hypertensive crises (see later in this section). Isocarboxazid,

phenelzine, and tranylcypromine are so-called irreversible inhibitors. When the enzyme is inhibited by

these agents, protein regeneration is required before MAO enzymatic activity is restored. Selegiline

(Eldepryl), a selective irreversible MAO inhibitor used in the treatment of Parkinson’s disease, exerts its

effects on MAO-B and is generally thought to have a very low risk of producing hypertensive crises.

However, at the low dosages used in treating parkinsonian patients (5–10 mg/day), this drug is a weak

antidepressant, and data from Sunderland et al. (1989) suggested that at higher antidepressant

dosages, the drug affects both MAO-A and MAO-B and thus does not protect against hypertensive

crises. More information on selegiline is provided in the section “Selective and Reversible Monoamine

Page 52 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterOxidase Inhibitors” later in this chapter.

Monoamine oxidase inhibitors (MAOIs): overview

Efficacy Third-line agents for

MDD (FDA approved for resistant depression)

Social anxiety

Panic disorder

Second-line agents for Parkinson’s disease (selegiline has FDA approval)

Side effects Weight gain

Orthostasis

Sexual dysfunction

Dry mouth

Insomnia/somnolence

Headache

Safety in overdose Can be lethal in overdose. Hypertensive crisis, stroke, and myocardial infarction

have been reported. Manage with lavage, emesis induction, and close

management of blood pressure and airway.

Dosage and

administration

Phenelzine: start at 15 mg bid or tid and increase by 15 mg per week to target

dosage of 60–90 mg/day.

Tranylcypromine: start at 10 mg bid or tid and increase by 10 mg per week to

target dosage of 40–60 mg/day.

Isocarboxazid: start at 10 mg bid and increase dosage, if the drug is tolerated, by

10 mg every 2–4 days to 40 mg/day by end of first week. Maximum

recommended dosage is 60 mg/day, administered in divided doses.

Selegiline transdermal system (Emsam): start with 6-mg patch daily for 4 weeks

and then increase to 9-mg patch for 2 weeks, and then 12-mg patch as needed.

No dietary restrictions at 6 mg/day.

Discontinuation Flulike symptoms, hallucinations, hypomania, and dysphoria reported with

sudden dis-continuation. Taper dose by 25% per week.

Drug interactions Foods containing high levels of tyramine (contraindicated) (see Table 3–14):

hypertensive crisis

-Blockers: hypotension, bradycardia

Oral hypoglycemics: hypoglycemic effects

Bupropion (contraindicated): hypertensive crisis, seizure

Carbamazepine (contraindicated): hypertensive crisis

Meperidine (contraindicated): serotonin syndrome

Nefazodone: possible serotonin syndrome

Sympathomimetics: hypertensive crisis

SSRIs (contraindicated): serotonin syndrome

TCAs: clomipramine contraindicated

Note. FDA = U.S. Food and Drug Administration; MDD = major depressive disorder; SSRI = selective

Page 53 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterThere are two structural classes of MAOIs: the hydrazines (i.e., phenelzine) and the nonhydrazines

(tranylcypromine and selegiline) (Figure 3–9; Table 3–12).

Indications

The primary PDR clinical indication for MAOIs is for treatment of depression refractory to TCA therapy.

With so many other safer antidepressants currently available, MAOIs are now typically indicated when

several trials have failed. Still, some patients respond better to MAOIs than to any other class of

agents. Phenelzine has an FDA-approved indication for anxious depression. Although the British had

emphasized frequently that the MAOIs were not particularly helpful in treating the severe forms of

serotonin reuptake inhibitor; TCA = tricyclic antidepressant.

Figure 3–9.

Chemical structures of monoamine oxidase inhibitors (MAOIs).

Table 3–12. Monoamine oxidase inhibitors (MAOIs): names, formulations and strengths,

and dosages

Generic name Brand

name

Tablets and capsules Oral

concentrate

Usual therapeutic

dosage (mg/day)a

phenelzine Nardil Tablet: 15 mg None 45–90

selegiline Eldepryl

Carbex

Emsam

Capsule: 5 mg

Tablet: 5 mg

Patch: 6 mg/24 hr, 9

mg/24 hr, 12 mg/24 hr

None 20–50

tranylcypromine Parnate Tablet: 10 mg None 30–60

isocarboxazid Marplan Tablet: 10 mg None 30–60

aDosage ranges are approximate. Many patients respond at relatively low dosages (even dosages

below those in the ranges given in table).

Page 54 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chaptermajor depression referred to in the past as endogenous, the American experience, including our own,

had been entirely different. These drugs were lifesavers for many severely depressed patients,

particularly those whose depression did not respond to TCAs.

Why the discrepancy? For one, there was little doubt that MAOIs were effective in patients with panic

attacks or with anxious or atypical depression. However, their effectiveness in patients with

melancholic or endogenous depression may require the prescription of considerably higher dosages

than those used in the early British trials, in which relatively low dosages were used. Another difficulty

with determining ranges of efficacy revolves around the occurrence of pronounced obsessionality,

agitation, and anxiety in many endogenously depressed patients, who may have, in the early studies,

been misdiagnosed as only anxiously depressed.

Investigators at Columbia University have attempted to define an atypical depressive syndrome that

preferentially responds to phenelzine and other MAOIs such as moclobemide. Their data suggest that

patients with atypical depression respond better to MAOIs than to TCAs. The SSRIs are also effective in

treating atypical depression. Because the SSRIs are considerably safer than the MAOIs, the use of

MAOIs in the treatment of atypical depression has dropped off considerably since the introduction of

fluoxetine. MAOIs are also effective in the treatment of social phobia.

Side Effects

Common side effects of MAOIs are listed in Table 3–13. Because MAOIs do not block acetylcholine

receptors, they produce less dry mouth, blurred vision, constipation, and urinary hesitancy than do

TCAs. However, we have seen patients who have developed urinary hesitancy, presumably as a result

of an increase in noradrenergic activity. When the problem occurs, a reduction in dosage may help. We

have been less impressed with the adjunctive use of bethanechol with MAOIs than with its use with

TCAs.

The most common side effect of MAOIs is dizziness, particularly of the orthostatic type. This side effect

appears to be somewhat more common with MAOIs than with TCAs. Dose reduction may help; but,

Table 3–13. Common or troublesome side effects of monoamine oxidase inhibitors (MAOIs)

Orthostatic hypotension

Hypertensive crises (interactions with foodstuffsa or medications)

Hyperpyrexic reactions

Anorgasmia or sexual impotence

Insomnia during night

Sedation (particularly in daytime; due to insomnia during night)

Stimulation during day

Muscle cramps and myositis-like reactions

Urinary hesitancyb

Constipationb

Dry mouthb

Weight gain

Myoclonic twitches

Skin irritation at patch site (Emsam)

aSee Table 3–14.

bLess than with tricyclic antidepressants.

Page 55 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapteragain, we have often found reduction in the dose to be problematic, because too great a reduction may

lead to reemergence of depressive symptoms. Alternative approaches include 1) maintenance of

adequate hydration—about eight glasses of fluid a day—and increased salt intake; 2) use of support

stockings, “bellybinders,” or corsets; and 3) addition of a mineralocorticoid (fludrocortisone [Florinef]).

Although this mineralocorticoid has been used in patients with orthostatic hypotension not induced by

medication, we have rarely found it to be helpful in the usual daily dose of 0.3 mg. We have been told

by colleagues that fludrocortisone can be effective at a total daily dose of 0.6–0.8 mg. An intriguing

report appeared before our second edition, pointing to the use of small amounts of cheese to help

maintain blood pressure—a counterintuitive but imaginative solution. However, most clinicians were

wary of the understandable risk of hypertensive crises with cheese, particularly when one did not really

know the tyramine content of the foodstuff. We are not aware of any recent reports on this. Similarly,

one would intuit that adding a stimulant (D-amphetamine or methylphenidate) to an MAOI would result

in marked surges of blood pressure. In fact, however, Feighner et al. (1985) reported that the addition

of stimulants for patients receiving MAOIs or MAOI-TCA combinations normalized blood pressure in

depressed patients with serious orthostatic hypotension or brought out a clinical response in patients

who had previously not had any response. There were no incidents of hypertensive crises; in fact,

several of the patients developed orthostatic hypotension. Daily dosages used were 5–20 mg of D

amphetamine and 10–15 mg of methylphenidate. These authors recommended beginning at a dosage

of 2.5 mg/day of either drug. We have heard of several clinicians in the community who have used

these approaches successfully, but we have also heard of occasional hypertensive crises when

stimulants were used in combination with MAOIs.

Sedation and activation are also potential problems, the latter being more common. Activation takes

two forms: stimulation during the day (particularly with tranylcypromine) and insomnia at night.

Tranylcypromine’s stimulatory effects have been related to its having a structure similar to that of

amphetamines, although this pharmacological link has not been clearly established. Overstimulation

can be ameliorated somewhat by dose reduction, although the side effect is not easily eliminated. If a

dose reduction does not result in a decrease in stimulation, patients may need to be switched to

another medication.

Phenelzine is, overall, far less stimulating and more sedating than tranylcypromine. As such it offers a

major alternative for daytime overstimulation. However, phenelzine may produce both insomnia and

secondary daytime sedation. Oddly, one often encounters insomnia in patients who are nevertheless

showing a good clinical response to the drug, making it a particularly difficult side effect to manage.

Changing the dosage regimen may be helpful. Patients who are not taking phenelzine in the evening

may benefit from switching drug taking to the evening hours. Conversely, patients who are taking

much of the drug in the evening may respond by taking it earlier in the day. These manipulations can

be helpful, although in our experience they are highly variable in their efficacy. Some patients may

ultimately require hypnotic agents to overcome persistent insomnia. By the second edition of this

manual, we had become very impressed with the addition of low doses of amitriptyline, trimipramine,

or trazodone (50–100 mg at bedtime) to counteract MAOI-induced sleep disturbances. Caution should

still be exercised in using trazodone or the TCAs with MAOIs because of the slight risk of developing a

serotonin syndrome. With trazodone, we recommend trying doses of 50–100 mg per night. An increase

to 150 mg hs can be tried if there has been no response at a lower dose and the medication has been

well tolerated.

As the dose of an MAOI is increased to high levels in an attempt to achieve a therapeutic effect,

patients occasionally become “intoxicated”—drunk, ataxic, confused, and sometimes euphoric. This is a

sign of overdose, and the dose should be reduced. Some patients develop muscle pains or

paresthesias—probably the result of the MAOIs interfering with pyridoxine (vitamin B6 ) metabolism.

Pyridoxine administered at dosages of approximately 100 mg/day can be helpful.

A particularly bothersome side effect is anorgasmia, which in some patients lessens over time. We

Page 56 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterhave not been impressed with any pharmacological attempts to counteract this side effect, although

cyproheptadine has been said to be helpful. Agents such as buspirone and bupropion are best avoided

in combination with MAOIs.

Overdose

Overdoses are not necessarily lethal. Patients will show sedation and orthostasis. However, overdoses

commonly involve other medications, resulting in serotonin syndromes or hypertensive reactions.

Drug Interactions

The greatest side-effect problems with MAOIs involve untoward interactions with certain foodstuffs or

cold remedies, which may produce hypertensive crises with violent cerebrovascular accidents, or

serotonin syndromes—consisting of hyperpyrexia, mental status changes, myoclonus, and delirium—

that can lead to coma and death. MAO in the intestinal tract degrades tyramine. When MAO is inhibited

by MAOIs, the individual is at risk for absorbing large amounts of tyramine and probably other

substances (e.g., phenylethylamine), which can act as false neurotransmitters or indirect agonists and

elevate blood pressure. Fortunately, dietary restrictions can markedly reduce the risk (Table 3–14).

Various prohibited foods are included in lists in the PDR. These lists have been reviewed by several

investigators, and relative risks have been attributed to many of the foods. As a general rule, we have

begun to specifically advise patients to avoid eating Chinese food because of the ingredients used

(e.g., soy sauce, sherry).

Table 3–14. Foods to be avoided with monoamine oxidase inhibitors (MAOIs)

Foods definitely to be avoided:

Beer, red wine

Aged cheeses (cottage and cream cheese are allowed)

Dry sausage

Fava or Italian green beans

Brewer’s yeast

Smoked fish

Liver (beef or chicken)

Foods that may cause problems in large amounts but are otherwise less problematic:

Alcohol

Ripe avocado

Yogurt

Bananas (ripe)

Soy sauce

Foods that were thought to be problems but are probably not problematic in usual quantities:

Chocolate

Figs

Meat tenderizers

Caffeine-containing beverages

Raisins

Source. Based on McCabe and Tsuang 1982.

Page 57 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterThe serotonin syndrome is generally not due to interaction with foodstuffs. It represents increased

central 5-HT activity and may be particularly provoked by the addition of certain medications.

In some cases of either hypertensive or hyperpyrexic reactions, the exact cause is not clear. Of

particular importance regarding medication interactions is warning patients to check with their

physician before taking other medications along with the MAOIs. Meperidine (Demerol), epinephrine,

local anesthetics (containing sympathomimetic agents), and decongestants can be particularly

dangerous.

Frequently, we are asked which decongestant or antihistamine can be used with the MAOIs.

Unfortunately, there is little in the way of prospective data. Diphenhydramine is used by many

practitioners, with apparent success. One problem, however, with this approach is that some over-the

counter diphenhydramine elixirs contain pseudoephedrine, and at least one untoward interaction with

the latter agent has been seen by our group. Another option is nasal sprays, but with this form, too,

some patients may show increases in blood pressure.

Another issue has to do with general anesthesia—during ECT or surgery—in patients treated with

MAOIs. Although at first glance this seems a frightening prospect, there have been many patients who

have successfully undergone procedures requiring general anesthesia without consequence. Indeed,

Dr. George Murray informed us, for the second edition of this manual, that Massachusetts General

Hospital had collected reports on some 2,000 such cases. Obviously, anesthesiologists need to be

apprised of a patient’s medications in order to determine the safest approach. To this end, it is

probably wise to have patients taking MAOIs carry a MedAlert Card. Still, in many settings, surgeons

and anesthesiologists advise patients to stop taking MAOIs before undergoing surgery. Further study is

needed to determine the most prudent approach to this knotty problem.

If a patient develops a surge in blood pressure with violent headaches, he or she should be instructed

to go to a local emergency room. Phentolamine (Regitine), a central -blocker, can be administered

intravenously to reverse the acute rise in blood pressure. Years ago, some psychopharmacologists

recommended that patients take oral chlorpromazine when headache occurred. We have stopped this

practice unless patients have not had a documented increase in blood pressure, because some patients

will display marked headaches secondary to a lowering of blood pressure. Instead, we provide our

patients with nifedipine, a calcium channel blocker, in case they experience marked increases in blood

pressure; 10 mg per hour until relief occurs (generally one or two doses) appears to be very helpful.

To enhance absorption, patients should be instructed to bite into the capsule before swallowing. This

approach may prove problematic in elderly patients, because acute lowering of blood pressure and

myocardial infarction have been reported with this approach for these patients.

We advise patients with headaches to have their blood pressure checked. In addition, routine

monitoring of blood pressure with an MAOI, particularly during the first 6 weeks of treatment, seems

prudent (for both the hypotensive and the hypertensive effects of the drug).

Dosage and Administration

The traditional therapeutic dosage ranges of these three MAOIs are as follows: phenelzine, 45–90

mg/day; tranylcypromine, 30–60 mg/day; oral selegiline, 20–50 mg/day. Some patients require

treatment at the higher end of the dosage range. For example, 90 mg/day of phenelzine is commonly

required in a patient with severe depressive illness.

A patient treated with phenelzine should start taking the medication at 30 mg/day, and the dosage

should be increased to 45 mg/day after 3 days. Thereafter, the dosage can be increased at a rate of 15

mg per week to 90 mg/day. We have seen patients who require as much as 120 mg/day; however,

many patients cannot tolerate the orthostatic side effects of these drugs. Some investigators have

recommended a dosage of 1 mg/kg per day of the drug as a guideline for adequacy of treatment.

For tranylcypromine, a starting dosage of 20 mg/day for 3 days seems reasonable. The dosage can

Page 58 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterthen be increased to 30 mg/day for 1 week, with increases of 10 mg per week to 50–60 mg/day. The

manufacturer’s current recommended maximum dosage of the drug is 40 mg/day. One investigator,

Dr. Jay Amsterdam, reported that extremely high dosages of the drug (110–130 mg/day) may help

patients with even the most refractory depression. There is some thought that at such high dosages

the drug is exerting alternative, additional effects—possibly acting as a reuptake blocker (Amsterdam

and Berwish 1989). Once a patient has responded, the medication should be maintained for a length of

time similar to that recommended for the TCAs.

Discontinuation

The currently available MAOIs irreversibly bind MAO to such a degree that it takes approximately 2

weeks after the MAOI is stopped for the enzyme to regenerate. During this time, tyramine and drug

interactions may occur. Thus, it is important to inform patients that they should maintain their dietary

and drug restrictions for 2 weeks after the MAOI is discontinued. In addition, these drugs should be

tapered to avoid rebound hypomania. Rarely, the withdrawal of an MAOI elicits a psychiatric

excitement or psychosis resembling a delirium more than mania. If the clinician wants to switch a

patient from one MAOI to another, care must be taken to avoid drug-drug interactions. The clinician

should taper the first MAOI and allow for a 10 to 14-day drug-free period before beginning another

MAOI. Some patients have experienced severe untoward reactions in switching from one MAOI to

another, particularly from phenelzine to tranylcypromine—perhaps reflecting the latter’s amphetamine

like properties. In general, a good reason to switch from one MAOI to another is intolerance to side

effects. If an adequate trial of an MAOI fails, there is little evidence that switching to another MAOI

helps.

When a transition between a TCA and an MAOI is being made, the PDR recommends that patients stop

taking all medications between trials for 10–14 days. Many clinicians, however, have reported that a

briefer drug-free period (i.e., 1–5 days) is sufficient for the transition from a TCA to an MAOI. For the

transition from an MAOI to a TCA, the 10- to 14-day period is generally recommended. The difference

in these strategies is probably due to the 10- to 14-day period needed to regenerate MAO.

However, patients taking MAOIs should wait 2 weeks before starting fluoxetine. For the transition from

fluoxetine to an MAOI, a 5-week period is recommended by the manufacturer because of the long half

life of the demethylated metabolite norfluoxetine. For the other SSRIs, a 2-week washout is adequate

before starting an MAOI. Likewise, a 1- to 2-week washout should ensue before switching to an MAOI

from venlafaxine and bupropion. The 5-HT2 antagonists nefazodone and trazodone appear to require

very short washouts; 1 week is quite enough.

SELECTIVE AND REVERSIBLE MONOAMINE OXIDASE INHIBITORS

As described earlier, all of the currently available MAOIs at antidepressant doses are nonselective and

irreversible inhibitors of MAO; that is, they irreversibly inhibit both MAO-A and MAO-B, and for enzyme

activity to commence, new MAO must be generated. Drugs that selectively block MAO-B, such as

selegiline, may substantially decrease the risk of hypertensive crises, because they do not substantially

affect MAO in the gut. Similarly, a reversible inhibitor of MAO-A would have a low affinity for MAO and

would be readily displaced by pressor amines, thus reducing the risk of a hypertensive crisis. Two

RIMAs, moclobemide and brofaromine, were under investigation, but interest in marketing these drugs

in the United States has waned considerably.

The FDA approved selegiline in 1991 for use in Parkinson’s disease under the trade name Eldepryl.

Much of the earlier clinical and scientific literature refers to selegiline by its earlier name, L-deprenyl.

Selegiline has proved a useful drug in Parkinson’s disease and may be the only antiparkinsonian drug

that has neuroprotective qualities and modestly affects the progression of the illness. At the dosages

used in Parkinson’s disease, 5–10 mg/day, the drug is a selective but irreversible inhibitor of MAO-B.

Unfortunately, currently available studies of the use of selegiline in depression suggest that dosages of

20–60 mg/day are required to relieve depression. At these higher dosages, both MAO-A and MAO-B

Page 59 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterare inhibited and hypertensive crises following ingestion of tyramine in foods are possible. One such

case, albeit mild, has been reported in a patient treated with 20 mg/day of selegiline.

Over the past several years, a transdermal form of selegiline has also been studied for the treatment of

depression. A selegiline transdermal system, marketed under the brand name Emsam, was approved

by the FDA in February 2006.

There are numerous published clinical studies of the use of selegiline in depression (Agosti et al. 1991;

Mann et al. 1989; Sunderland et al. 1994). These studies can be interpreted as confirming the clear

therapeutic effect of selegiline in patients with atypical and chronic depression and more serious

depression. Furthermore, the Sunderland et al. study suggests that at a dosage of 60 mg/day,

selegiline is useful for and well tolerated by geriatric patients with treatment-resistant depression. The

drug is of substantial clinical interest because its pattern of side effects at dosages up to 40 mg/day

appears quite favorable compared with that of the older MAOIs. Selegiline does not seem to cause

clinically significant orthostatic hypotension or sexual dysfunction, and it may cause less insomnia than

the older drugs. Several patients who were unable to tolerate the side effects of older MAOIs have

tolerated selegiline quite well. It should be noted, however, that most published selegiline trials have

lasted only 4–6 weeks, and some patients treated with the older MAOIs develop clinically intolerable

side effects only after taking the drug for 2–3 months. Psychiatrists already experienced in the MAOI

management of patients may find selegiline worth trying in cases of treatment-resistant conditions.

Patients who have a good antidepressant response to MAOIs but who are experiencing intolerable side

effects may be the best candidates for selegiline.

Oral selegiline is currently not approved for use in depression. But transdermal selegiline is approved

for the treatment of depression. Because selegiline is metabolized to R isomers of amphetamine and

methamphetamine in the body and is a dopamine reuptake inhibitor, we strongly urge a 2-week

interval between stopping an older MAOI and starting selegiline. Patients treated with transdermal

selegiline at dosages higher than 6 mg/day should adhere to the usual restrictions of a low-tyramine

diet.

Three other comments are worth making. First, measuring platelet MAOI in patients who are taking

selegiline is probably not useful, because almost complete inhibition occurs after 1 week at a dosage of

10 mg/day. Second, the drug is very expensive: a local drugstore charges around $5 per 5-mg pill.

Finally, selegiline should not be stopped abruptly, because it is associated with a discontinuation

syndrome consisting of nausea, dizziness, and hallucinations.

At least two studies have demonstrated efficacy of transdermal selegiline against placebo in major

depression (Amsterdam 2003; Bodkin and Amsterdam 2002). Of interest is that in patch delivery,

selegiline in brain may be a far more potent MAO-A inhibitor, and this may confer greater efficacy. The

drug (in a patch) may earn FDA approval for acute and chronic major depression either with or without

atypical features. The transdermal formulation bypasses gut and liver and allows for higher plasma

levels with a low risk of foodstuff interactions. The drug is available in patches of 20, 30, and 40

mg/cm2 (6, 9, and 12 mg/24 hours, respectively) applied daily. In clinical trials, the starting daily dose

was typically 20 mg (6 mg/24 hours), and the daily dose was then increased by 10 mg (3 mg/24

hours) every 1–2 weeks to a maximum of 40 mg (12 mg/24 hours). The package insert indicates that

the 6- and 9-mg dose/24 hours may increase the risk for a tyramine interaction in some patients. This

observation is based on a study in healthy control subjects in which a high-tyramine diet was

associated with mild increases in blood pressure with the 9- and 12-mg patches. The risk of untoward

interactions is largely theoretical. We have done studies that used the 9- and 12-mg doses without a

restricted diet and have observed no increases in blood pressure.

Rash has been the primary side effect that was observed to be greater with transdermal selegiline than

with placebo. While most patients do not have substantial reactions to the patch, some skin reactions

can be quite intense. We have seen a few patients with erythema that extends far beyond the patch

Page 60 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chaptersite, and pruritis is not uncommon. Oral diphenhydramine seems to help with the itching. After site

reactions, insomnia is the next most common side effect and is consistent with the amphetamine-like

effects of the drug. Standard sleep medications such as zolpidem or temazepam appear to be helpful

and are well tolerated. While sleep does seem to normalize after the patient has taken the drug for a

few weeks, just taking the patch off at night also seems to help. Unfortunately, taking half the dose

might also decrease the efficacy of the transdermal selegiline. The patch, designed for 24-hour

delivery, needs to be changed daily. Some patients have taken to cutting the 6 mg/24 hour patch in

half if they cannot tolerate a full dose. Although cutting the patch should reduce the daily dose in

proportion to the amount cut (since surface area of the patch is directly related to total drug dose), the

manufacturer recommends against cutting the patch because compromising the integrity of the patch

could affect reliability of transdermal drug delivery. The risk of a serotonin syndrome when transdermal

selegiline is used in combination with a serotonergic drug appears reduced but not eliminated. Thus,

the drug should not be combined with SSRIs, SNRIs, or most TCAs. However, orthostasis, weight gain,

and sexual dysfunction appear to be much less of a problem with transdermal selegiline than with oral

MAOIs.

Given the ease of use and better tolerability of transdermal selegiline versus oral MAOIs, we are

typically using it before considering other MAOIs. The patient profile that may best fit with transdermal

selegiline includes patients who have experienced failed trials with one or more classes of

antidepressants, depressed patients with prominent fatigue or cognitive deficits, and patients with

atypical depression.

Moclobemide is the best-studied RIMA. Its actions on MAO are easily reversed (i.e., do not require

regeneration of the enzyme). Moclobemide has a half-life of only 1–3 hours. It is available in Europe,

Canada, and other parts of the world, but not in the United States. Several thousand depressed

patients have been enrolled in moclobemide studies over the past 10 years, and it has been found to

be effective in a wide spectrum of depressive illnesses, including melancholic, endogenous, atypical,

psychotic (in combination with a neuroleptic), and bipolar subtypes (Fitton et al. 1992).

Moclobemide appears to be effective in elderly as well as younger patients and may be effective in the

treatment of social phobia. In unpublished South American trials, moclobemide appeared to be as

effective as—if not more effective than—imipramine and superior to placebo. However, one meta

analysis in Europe (Lotufo-Neto et al. 1999) suggested that moclobemide was not a particularly

effective antidepressant in comparison with imipramine and placebo. In another South American study,

moclobemide was significantly more effective than placebo in the treatment of social phobia.

The primary advantages of moclobemide over standard MAOIs are its tolerability and its safety. Nausea

is the only side effect reported more commonly for moclobemide than for placebo. Significant

orthostasis and other cardiovascular side effects are usually not seen. Furthermore, moclobemide has

proved safe in overdoses to 20 g.

Because moclobemide does not increase tyramine sensitivity (Cusson et al. 1991), the risk of dietary

interactions appears low. In Europe, the only significant dietary restriction is avoiding large amounts of

aged cheeses after taking a dose of the drug. Moclobemide is usually given after meals or at bedtime

to minimize dietary interactions.

The risk of serious drug interactions also appears to be lower with moclobemide. However, serious

interactions have been reported with meperidine, clomipramine, and possibly the SSRIs. There is one

report that moclobemide has been administered safely with fluvoxamine and fluoxetine (Dingemanse

1993). It is unlikely that moclobemide will be introduced soon in the United States because of a

number of failed trials, but it is available through pharmacies in Europe and Canada. Development of

another RIMA, brofaromine, has also been canceled because of an apparent lack of efficacy.

MELATONIN AGONIST–5-HT

2C ANTAGONIST

Page 61 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterAgomelatine represents one of the more novel approaches to the pharmacotherapy of depression. The

drug’s 5-HT2C antagonist pharmacology provides both antidepressant and anxiolytic properties, while

the melatonin MT1 and MT2 agonist properties provide for sleep induction without much sedation. A

disturbance of circadian rhythms has long been recognized in mood disorders, most notably in sleep

and the diurnal variation common to melancholic depression. It remains to be seen whether a potent

melatonin agonist has other benefits in the treatment of depression.

Agomelatine has demonstrated anxiolytic and antidepressant properties in animal models (Papp et al.

2006). Preliminary clinical trials have demonstrated that dosages above 25 mg/day appear effective in

the treatment of depression (Loo et al. 2002a, 2002b). The first phase III trial to be completed was

very encouraging. Agomelatine 25–50 mg/day was superior to placebo in the treatment of depression

and was well tolerated (Kennedy and Emsley 2006). A analysis of more severely depressed patients

within the sample of 212 patients studied indicated that this subset also appeared to respond to

agomelatine. Thus, there is some hope that agomelatine may prove to be useful in severely depressed

and perhaps currently treatment-resistant patients.

Even if agomelatine proves no more efficacious than currently available treatments, its favorable side

effect profile may be a distinct advantage over that of many available antidepressants. Agomelatine’s

specific receptor effects are associated with fewer sexual side effects, less GI upset, and and less

daytime sedation than those of most serotonergic antidepressants (Dubocovich 2006). In addition,

there is no evidence of weight gain or of a discontinuation syndrome when the drug is stopped

abruptly.

It is anticipated that the target dosage of agomelatine will be 25 mg/day, with some patients

benefiting from a dosage of up to 50 mg/day. We can imagine the combination of agomelatine with

either SSRIs, bupropion, or SNRIs in the treatment of resistant depression, but no studies have yet

evaluated the augmenting benefit of agomelatine.

NOVEL ANTIDEPRESSANTS

Over the past several years, a variety of other novel approaches to the treatment of major depression

have been investigated. Whereas all marketed antidepressants appear to significantly impact

monoamines, these new agents appear to work by completely different mechanisms.

Among the more promising areas in antidepressant research is the use of agents that impact the

hypothalamic-adrenal axis in major depression. Since severe depression is often characterized by

hypercortisolemia, it has been speculated that some of the symptoms of a depressive episode might be

attributable to elevated cortisol levels. For example, there is some evidence that cognitive symptoms,

diurnal variation, and perhaps even psychotic symptoms in depression might be due, at least in part,

to elevated cortisol levels. Several types of anticortisol agents are under investigation. Corticotropin

releasing factor (CRF) antagonists have been synthesized by a number of pharmaceutical companies

and are being examined for anxiety disorders and depression (Mitchell 1998). One, R121919, has been

reported to produce significant antidepressant effects (Zobel et al. 2000), but its development was

canceled because of elevated liver enzymes. Likewise, glucocorticoid receptor antagonists that block

cortisol’s effects at the low-affinity receptor at the level of the cerebral cortex have shown promise as

antidepressants. Initial reports by our group suggested that mifepristone might have promise in the

treatment of psychotic depression (Belanoff et al. 2002). A biotechnology company that two of us

(A.F.S., C.D.) have an interest in has pursued more rigorous studies with mifepristone. Two double

blind trials of C-1073 600 mg/day for 7 days in the treatment of psychotic depression have yielded

surprising results. The first trial failed to show a benefit on its primary endpoint, a 30% reduction in

psychosis on the Brief Psychiatric Rating Scale (BPRS), but it did show differences when more rigorous

response, such as remission, was evaluated in post hoc analyses. The second trial demonstrated a

rapid and sustained effect on the psychosis in psychotic depression but insignificant separation from

placebo on measures of depression (DeBattista et al. 2006). We believe that the drug has more

Page 62 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterimportant effects on psychosis than on depression. At the time of this writing, two phase III trials have

had inconclusive results. The response rate of the comparison groups (antidepressant plus placebo)

was as high as 95%, and the addition of mifepristone could not improve this response rate. Other

groups have demonstrated cognitive and mood improvements associated with mifepristone in the

treatment of bipolar depression (Young et al. 2004).

Corticotropin-releasing factor antagonists may also be useful in the treatment of anxiety and

depression. The first, uncontrolled human study of a CRF antagonist in the treatment of MDD

demonstrated that the drug appeared to alleviate depressive symptoms in a small number of patients

(Zobel et al. 2000). However, that CRF antagonist was subsequently shown to be hepatotoxic, and

thus its development was suspended. Nonetheless, a variety of CRF antagonists are in development,

with none past early Phase II trials.

Another line of antidepressant research has involved the use of peptide hormone antagonists, including

substance P antagonists, as antidepressants. In preliminary studies, two substance P antagonists

developed by Merck were found to be superior to placebo in the treatment of major depression

(Kramer et al. 1998, 2004). The drug also was well tolerated and had few side effects. However,

subsequent trials of MK-0869, unfortunately, failed in all five Phase III trials (Keller et al. 2006), and

the drug is no longer in development. Nonetheless, other pharmaceutical companies have developed

substance P antagonists that are currently being studied in major depression and social phobia. Our

hunch is that these drugs may prove to be more effective in treating anxiety disorders than treating

depression. Other peptide hormone neurotransmitters that are being investigated for developing

agents with antidepressant effects include somatostatin and cholecystokinin.

In addition to hormonal therapies, more conventional antidepressants are also under investigation. A

new type of 5-HT1A antagonist is under investigation. Buspirone-like compounds, such as gepirone and

ipsapirone, have proved disappointing as antidepressants. However, new compounds have shown early

evidence of being more potent in their monoamine effects than have their predecessors. Moreover,

gepirone has recently been resurrected and studied at higher doses in a long-acting formulation, with

mixed results. However, as noted previously, the drug did not receive approval, perhaps because of

limited efficacy data with the long-acting formulation.

Minaprine, which has been studied for many years, continues to be investigated. It is an atypical agent

with an affinity for serotonin, dopamine, and muscarinic receptors. Many double-blind studies have

attested to its efficacy and general tolerability. However, it is unclear whether it will ever be released

to the U.S. market.

In addition to reboxetine, other more selective NRIs, including lofepramine and viloxazine, also remain

in consideration. It remains to be seen what niche norepinephrine-specific agents will secure in the

armamentarium of antidepressants.

In the fourth edition of our manual, we wrote that “the next 10 years in antidepressant drug

development may be among the most promising since the development of the MAOIs and TCAs in the

1950s.” At this time, we are more skeptical as to whether the near future will yield any new

compounds with alternative mechanisms of action for the ambulatory depressed patient. What a

difference a few years make.

BIBLIOGRAPHY

Agosti V, Stewart JW, Quitkin FM: Life satisfaction and psychosocial functioning in chronic depression:

effect of acute treatment with antidepressants. J Affect Disord 23:35–41, 1991 [PubMed]

Aguglia E, Casacchia M, Cassano GB, et al: Double-blind study of the efficacy and safety of sertraline

versus fluoxetine in major depression. Int Clin Psychopharmacol 8:197–202, 1993 [PubMed]

Aizenberg D, Zemishlany Z, Weizman A: Cyproheptadine treatment of sexual dysfunction induced by

Page 63 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterserotonin reuptake inhibitors. Clin Neuropharmacol 18:320–324, 1995 [PubMed]

Altamura AC, Pioli R, Vitto M, et al: Venlafaxine in social phobia: a study in selective serotonin

reuptake inhibitor non-responders. Int Clin Psychopharmacol 14:239–245, 1999 [PubMed]

American Psychiatric Association: Diagnostic and Statistical Manual of Mental Disorders, 4th Edition.

Washington, DC, American Psychiatric Association, 1994

Amsterdam JD: A double-blind, placebo-controlled trial of the safety and efficacy of selegiline

transdermal system without dietary restrictions in patients with major depressive disorder. J Clin

Psychiatry 64:208–214, 2003 [PubMed]

Amsterdam JD, Berwish NJ: High dose tranylcypromine therapy for refractory depression.

Pharmacopsychiatry 22:21–25, 1989 [PubMed]

Amsterdam JD, Hornig-Rohan M, Maislin G: Efficacy of alprazolam in reducing fluoxetine-induced

jitteriness in patients with major depression. J Clin Psychiatry 55:394–400, 1994a

Amsterdam JD, Maislin G, Potter L: Fluoxetine efficacy in treatment resistant depression. Prog

Neuropsychopharmacol Biol Psychiatry 18:243–261, 1994b

Ansseau M, De Roeck J: Trazodone in benzodiazepine dependence. J Clin Psychiatry 54:189–191, 1993

[PubMed]

Ansseau M, Darimont P, Lecoq A, et al: Controlled comparison of nefazodone and amitriptyline in major

depressive inpatients. Psychopharmacology (Berl) 115: 254–260, 1994 [PubMed]

Anton RF, Sexauer JD: Efficacy of amoxapine in psychotic depression. Am J Psychiatry 140:1344–

1347, 1983 [PubMed]

Aranda-Michel J, Koehler A, Bejarano PA, et al: Nefazodone-induced liver failure: report of three cases.

Ann Intern Med 130 (4, part 1):285–288, 1999

Aranow RB, Hudson JL, Pope HG, et al: Elevated antidepressant plasma levels after addition of

fluoxetine. Am J Psychiatry 146:911–913, 1989 [PubMed]

Arminen SL, Ikonen U, Pulkkinen P, et al: A 12-week double-blind multi-centre study of paroxetine and

imipramine in hospitalized depressed patients. Acta Psychiatr Scand 89:382–389, 1994 [PubMed]

Armitage R, Rush AJ, Trivedi M, et al: The effects of nefazodone on sleep architecture in depression.

Neuropsychopharmacology 10:123–127, 1994 [PubMed]

Åsberg M, Cronholm B, Sjoqvist F, et al: Relationship between plasma level and therapeutic effect of

nortriptyline. Br Med J 3:331–334, 1971

Ashton AK, Bennett RG: Sildenafil treatment of serotonin reuptake inhibitor–induced sexual dysfunction

(letter). J Clinical Psychiatry 60:194–195, 1999 [PubMed]

Ashton AK, Rosen RC: Bupropion as an antidote for serotonin reuptake inhibitor–induced sexual

dysfunction. J Clin Psychiatry 59:112–115, 1998 [PubMed]

Balon R: Intermittent amantadine for fluoxetine-induced anorgasmia. J Sex Marital Ther 22:290–292,

1996 [PubMed]

Banasr M, Soumier A, Hery M, et al: Agomelatine, a new antidepressant, induces regional changes in

hippocampal neurogenesis. Biol Psychiatry 59(11):1087–1096, 2006 [PubMed]

Banham ND: Fatal venlafaxine overdose (letter; comment). Med J Aust 169: 445, 448, 1998

Barbey JT, Roose SP: SSRI safety in overdose. J Clin Psychiatry 59 (suppl 15):42–48, 1998

Beasley C Jr, Dornseif BE, Bosomworth JC, et al: Fluoxetine and suicide: a meta-analysis of controlled

Page 64 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chaptertrials of treatment for depression. BMJ 23:685–692, 1991 [also see comments] [erratum: BMJ 23:968,

1991]

Beasley C Jr, Potvin JH, Masica DN, et al: Fluoxetine: no association with suicidality in obsessive

compulsive disorder. J Affect Disord 24:1–10, 1992 [PubMed]

Belanoff J, Flores B, Kalezhan M, et al: Rapid reversal of psychotic major depression using

mifepristone. J Clin Psychopharmacol 21:516–521, 2001 [PubMed]

Belanoff JK, Rothschild AJ, Cassidy F, et al: An open label trial of C-1073 (mifepristone) for psychotic

major depression. Biol Psychiatry 52:386–392, 2002 [also see comment]

Bell IR, Cole JO: Fluoxetine induces elevation of desipramine levels and exacerbation of geriatric

nonpsychotic depression (letter). J Clin Psychopharmacol 8:447–448, 1988 [PubMed]

Benazzi FL: Nefazodone withdrawal symptoms. Can J Psychiatry 43:194–195, 1998 [also see

comment: Can J Psychiatry 44:286–287, 1999]

Bergeron R, Blier P: Cisapride for the treatment of nausea produced by selective serotonin reuptake

inhibitors (brief report). Am J Psychiatry 151:1084–1086, 1994 [PubMed]

Berk M, Ichim C, Brook S: Efficacy of mirtazapine add-on therapy to haloperidol in the treatment of

negative symptoms of schizophrenia: a double-blind, randomized, placebo-controlled study. Int Clin

Psychopharmacol 16:87–92, 2001 [PubMed]

Bertschy G, Vandel S, Vandel B, et al: Fluvoxamine-tricyclic antidepressant interaction: an accidental

finding. Eur J Clin Pharmacol 40:119–120, 1991 [PubMed]

Bhatara VS, Bandettini FC: Possible interaction between sertraline and tranylcypromine. Clin Pharm

12:222–225, 1993 [PubMed]

Bhattacharjee C, Smith M, Todd F, et al: Bupropion overdose: a potential problem with the new

“miracle” anti-smoking drug. Int J Clin Pract 55:221–222, 2001 [PubMed]

Black DW, Wesner R, Gabel J: The abrupt discontinuation of fluvoxamine in patients with panic

disorder. J Clin Psychiatry 54:146–149, 1993 [PubMed]

Bodkin JA, Amsterdam JD: Transdermal selegiline in major depression: a double-blind, placebo

controlled, parallel-group study in outpatients. Am J Psychiatry 159:1869–1875, 2002 [Full Text]

[PubMed]

Borys DJ, Setzer SC, Ling LJ, et al: Acute fluoxetine overdose: a report of 234 cases. Am J Emerg Med

10:115–120, 1992 [PubMed]

Boyd IW: Venlafaxine withdrawal reactions. Med J Aust 169:91–92, 1998 [PubMed]

Boyer WF, Feighner JP: An overview of paroxetine. J Clin Psychiatry 53 (2, suppl):3–6, 1992

Brown WA, Harrison W: Are patients who are intolerant to one SSRI intolerant to another? J Clin

Psychiatry 56:30–34, 1995 [PubMed]

Buckley NA, McManus PR: Fatal toxicity of serotoninergic and other antidepressant drugs: analysis of

United Kingdom mortality data. BMJ 325(7376):1332–1333, 2002 [also see comment]

Cantwell DP: ADHD through the life span: the role of bupropion in treatment. J Clin Psychiatry 59 (4,

suppl):92–94, 1998

Carpenter LL, Jocic Z, Hall JM, et al: Mirtazapine augmentation in the treatment of refractory

depression. J Clin Psychiatry 60:45–49, 1999a

Carpenter LL, Leon Z, Yasmin S, et al: Clinical experience with mirtazapine in the treatment of panic

Page 65 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterdisorder. Ann Clin Psychiatry 11:81–86, 1999b

Carpenter LL, Milosavljevic N, Schecter JM, et al: Augmentation with open-label atomoxetine for partial

or nonresponse to antidepressants. J Clin Psychiatry 66(10):1234–1238, 2005 [PubMed]

Chouinard G, Goodman W, Greist J, et al: Results of a double-blind placebo-controlled trial of a new

serotonin uptake inhibitor, sertraline, in the treatment of obsessive-compulsive disorder.

Psychopharmacol Bull 26: 279–284, 1990 [PubMed]

Claghorn J: A double-blind comparison of paroxetine and placebo in the treatment of depressed

outpatients. Int Clin Psychopharmacol 6 (suppl 4):25–30, 1992

Claghorn JL, Feighner JP: A double-blind comparison of paroxetine with imipramine in the long-term

treatment of depression. J Clin Psychopharmacol 13 (6, suppl 2): 23S–27S, 1993

Clayton AH, Warnock JK, Kornstein SG, et al: A placebo-controlled trial of bupropion SR as an antidote

for selective serotonin reuptake inhibitor–induced sexual dysfunction. J Clin Psychiatry 65:62–67, 2004

[PubMed]

Clerc GE, Ruimy P, Verdeau-Palles J: A double-blind comparison of venlafaxine and fluoxetine in

patients hospitalized for major depression and melancholia. The Venlafaxine French Inpatient Study

Group. Int Clin Psychopharmacol 9:139–143, 1994 [PubMed]

Cohn CK, Shrivastava R, Mendels J, et al: Double-blind, multicenter comparison of sertraline and

amitriptyline in elderly depressed patients. J Clin Psychiatry 51 (12, suppl):28–33, 1990

Cole JO, Bodkin JA: Antidepressant drug side effects. J Clin Psychiatry 51 (1, suppl): 21–26, 1990

Cole JO, Schatzberg AF: Antidepressant drug therapy, in Psychiatry Update: The American Psychiatric

Association Annual Review, Vol 2. Edited by Grinspoon L. Washington, DC, American Psychiatric Press,

1983, pp 472–491, 542–544

Connor KM, Davidson JR, Weisler RH, et al: A pilot study of mirtazapine in post-traumatic stress

disorder. Int Clin Psychopharmacol 14:29–31, 1999 [PubMed]

Cooper GL: The safety of fluoxetine—an update. Br J Psychiatry 153 (suppl 3):77–86, 1988

Cusson JR, Goldenberg E, Larochelle P: Effect of a novel monoamine-oxidase inhibitor, moclobemide,

on the sensitivity to intravenous tyramine and norepinephrine in humans. J Clin Pharmacol 31:462–

467, 1991 [PubMed]

Dalfen AK, Stewart DE: Who develops severe or fatal adverse drug reactions to selective serotonin

reuptake inhibitors? Can J Psychiatry 46:258–263, 2001 [PubMed]

Dallal A, Chouinard G: Withdrawal and rebound symptoms associated with abrupt discontinuation of

venlafaxine (letter). J Clin Psychopharmacol 18:343–344, 1998 [PubMed]

Daniels RJ: Serotonin syndrome due to venlafaxine overdose. J Accid Emerg Med 15:333–334, 1998

[PubMed]

Danish University Antidepressant Group: Paroxetine: a selective serotonin reuptake inhibitor showing

better tolerance but weaker antidepressant effect than clomipramine in a controlled multicenter study.

J Affect Disord 18:289–299, 1990

Davidson JR, DuPont RL, Hedges D, et al: Efficacy, safety, and tolerability of venlafaxine extended

release and buspirone in outpatients with generalized anxiety disorder. J Clin Psychiatry 60:528–535,

1999 [PubMed]

Davidson JR, Weisler RH, Butterfield MI, et al: Mirtazapine vs placebo in posttraumatic stress disorder:

a pilot trial. Biol Psychiatry 53(2):188–191, 2003 [PubMed]

Page 66 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterDavis JL, Smith RL: Painful peripheral diabetic neuropathy treated with venlafaxine HCl extended

release capsules (letter; see comments). Diabetes Care 22:1909–1910, 1999 [PubMed]

DeBattista C: A double-blind trial of bupropion in the treatment of SSRI-induced sexual dysfunction.

Paper presented at the 154th annual meeting of the American Psychiatric Association, New Orleans,

May 5–10, 2001

DeBattista C, Doghramji K, Menza MA, et al: Adjunct modafinil for the short-term treatment of fatigue

and sleepiness in patients with major depressive disorder: a preliminary double-blind, placebo

controlled study. J Clin Psychiatry 64:1057–1064, 2003 [PubMed]

DeBattista C, Lembke A, Solvason HB, et al: A prospective trial of modafinil as an adjunctive treatment

of major depression. J Clin Psychopharmacol 24:87–90, 2004 [PubMed]

DeBattista C, Solvason B, Poirier J, et al: A placebo-controlled, randomized, double-blind study of

adjunctive bupropion sustained release in the treatment of SSRI-induced sexual dysfunction. J Clin

Psychiatry 66(7):844–848, 2005 [PubMed]

DeBattista C, Belanoff J, Glass S, et al: Mifepristone versus placebo in the treatment of psychosis in

patients with psychotic major depression. Biol Psychiatry 60:1343–1349, 2006 [PubMed]

den Boer JA, Bosker FJ, Meesters Y: Clinical efficacy of agomelatine in depression: the evidence. Int

Clin Psychopharmacol 21 (suppl 1):S21–S24, 2006

Dessain EC, Schatzberg AF, Woods BT, et al: Maprotiline treatment in depression: a perspective on

seizures. Arch Gen Psychiatry 43:86–90, 1986 [PubMed]

Detke MJ, Lu Y, Goldstein DJ, et al: Duloxetine, 60 mg once daily, for major depressive disorder: a

randomized double-blind, placebo-controlled trial. J Clin Psychiatry 63:308–315, 2002 [PubMed]

Diaz-Martinez A, Benassinni O, Ontiveros A, et al: A randomized, open-label comparison of venlafaxine

and fluoxetine in depressed outpatients. Clin Ther 20:467–476, 1998 [PubMed]

Dingemanse J: An update of recent moclobemide interaction data. Int Clin Psychopharmacol 7:167–

180, 1993 [PubMed]

Doogan DP, Langdon CJ: A double-blind, placebo-controlled comparison of sertraline and dothiepin in

the treatment of major depression in general practice. Int Clin Psychopharmacol 9:95–100, 1994

[PubMed]

Dostert P, Benedetti MS, Poggesi I: Review of the pharmacokinetics and metabolism of reboxetine, a

selective noradrenaline reuptake inhibitor. Eur Neuropsychopharmacol 7 (suppl 1):S23–S35 [discussion

S71–S73], 1997

Dubocovich ML: Agomelatine targets a range of major depressive disorder symptoms. Curr Opin

Investig Drugs 7(7):670–80, 2006 [PubMed]

Dunner DL: An overview of paroxetine in the elderly. Gerontology 1:21–27, 1994

Dwight MM, Arnold LM, O’Brien H, et al: An open clinical trial of venlafaxine treatment of fibromyalgia.

Psychosomatics 39:14–17, 1998 [Full Text] [PubMed]

Einarson TR, Arikian SR, Casciano J, et al: Comparison of extended-release venlafaxine, selective

serotonin reuptake inhibitors, and tricyclic antidepressants in the treatment of depression: a meta

analysis of randomized controlled trials. Clin Ther 21:296–308, 1999 [PubMed]

Ellingrod VL, Perry PJ: Venlafaxine: a heterocyclic antidepressant. Am J Hosp Pharm 51:3033–3046,

1994 [PubMed]

Falkai P: Mirtazapine: other indications. J Clin Psychiatry 60 (suppl 17):36–40 [discussion 46–48],

Page 67 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapter1999

Farah A: Relief of SSRI-induced sexual dysfunction with mirtazapine treatment (letter). J Clin

Psychiatry 60:260–261, 1999 [PubMed]

Fava M, Rosenbaum JF, McGrath PJ, et al: Lithium and tricyclic augmentation of fluoxetine treatment

for resistant major depression: a double-blind, controlled study. Am J Psychiatry 151:1372–1374, 1994

[PubMed]

Fava M, Dunner DL, Greist JH, et al: Efficacy and safety of mirtazapine in major depressive disorder

patients after SSRI treatment failure: an open-label trial. J Clin Psychiatry 62:413–420, 2001 [PubMed]

Fava M, Nurnberg HG, Seidman SN, et al: Efficacy and safety of sildenafil in men with serotonergic

antidepressant-associated erectile dysfunction: results from a randomized, double-blind, placebo

controlled trial. J Clin Psychiatry 67(2):240–246, 2006a

Fava M, Rush AJ, Wisniewski SR, et al: A comparison of mirtazapine and nortriptyline following two

consecutive failed medication treatments for depressed outpatients: a STAR*D report. Am J Psychiatry

163(7):1161–1172, 2006b

Fawcett J, Barkin RL: Review of the results from clinical studies on the efficacy, safety and tolerability

of mirtazapine for the treatment of patients with major depression. J Affect Disord 51:267–285, 1998

[PubMed]

Feiger AD: A double-blind comparison of gepirone extended release, imipramine, and placebo in the

treatment of outpatient major depression. Psychopharmacol Bull 32:659–665, 1996 [PubMed]

Feiger A, Kiev A, Shrivastava RK, et al: Nefazodone versus sertraline in outpatients with major

depression: focus on efficacy, tolerability, and effects on sexual function and satisfaction. J Clin

Psychiatry 57 (2, suppl):53–62, 1996

Feighner JP, Aden GC, Fabre LF, et al: Comparison of alprazolam, imipramine and placebo in the

treatment of depression. JAMA 249:3056–3064, 1983

Feighner JP, Herbstein J, Damlouji N: Combined MAOI, TCA, and direct stimulant therapy of treatment

resistant depression. J Clin Psychiatry 46:206–209, 1985 [PubMed]

Fisher S, Bryant SG, Kent TA: Postmarketing surveillance by patient self monitoring: trazodone vs

fluoxetine. J Clin Psychopharmacol 13:235–242, 1992

Fitton A, Faulds D, Goa KL: Moclobemide: a review of its pharmacology and therapeutic use in

depressive illness. Drugs 43:561–596, 1992 [PubMed]

Fluoxetine Bulimia Nervosa Collaborative Study Group: Fluoxetine in the treatment of bulimia nervosa:

a multicenter, placebo-controlled, double-blind trial. Arch Gen Psychiatry 49:139–147, 1992

Fontaine R, Ontiveros A, Elie R, et al: A double-blind comparison of nefazodone, imipramine, and

placebo in major depression. J Clin Psychiatry 55: 234–241, 1994 [PubMed]

Frank E, Kupfer DJ, Perl JM, et al: Three-year outcomes for maintenance therapy of recurrent

depression. Arch Gen Psychiatry 47:1093–1104, 1990 [PubMed]

Freeman EW, Rickels K, Sondheimer SJ, et al: Nefazodone in the treatment of premenstrual syndrome:

a preliminary study. J Clin Psychopharmacol 14:180–186, 1994 [PubMed]

Friel PN, Logan BK, Fligner CL: Three fatal drug overdoses involving bupropion. J Anal Toxicol 17

(7):436–438, 1993 [PubMed]

Gadde KM, Yonish GM, Wagner HR 2nd, et al: Atomoxetine for weight reduction in obese women: a

preliminary randomised controlled trial. Int J Obes (Lond) 30(7):1138–1142, 2006 [PubMed]

Page 68 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterGambi F, De Berardis D, Campanella D, et al: Mirtazapine treatment of generalized anxiety disorder: a

fixed-dose, open-label study. J Psychopharmacol 19(5):483–487, 2005 [PubMed]

Gelenberg AJ, Lydiard RB, Rudolph RL, et al: Efficacy of venlafaxine extended-release capsules in

nondepressed outpatients with generalized anxiety disorder: a 6-month randomized controlled trial.

JAMA 283: 3082–3088, 2000 [PubMed]

Geretsegger C, Bohmer F, Ludwig M: Paroxetine in the elderly depressed patient: randomized

comparison with fluoxetine of efficacy, cognitive and behavioural effects. Int Clin Psychopharmacol

9:25–29, 1994 [PubMed]

Gittelman DK, Kirby MG: A seizure following bupropion overdose (letter). J Clin Psychiatry 54:162,

1993 [PubMed]

Glassman A, Perel J, Shostak M, et al: Clinical implication of imipramine plasma levels for depressive

illness. Arch Gen Psychiatry 34:197–204, 1977 [PubMed]

Golden RN, Rudorfer MV, Sherer M, et al: Bupropion in depression I: biochemical effects and clinical

response. Arch Gen Psychiatry 45:139–143, 1988 [PubMed]

Goldstein D, Bitter I, Lu Y, et al: Duloxetine in the treatment of depression: a double-blind, placebo

controlled comparison with paroxetine. Eur Psychiatry 17 (suppl 1): 98, 2002

Goldstein MG: Bupropion sustained release and smoking cessation. J Clin Psychiatry 59 (4, suppl):66–

72, 1998

Goodnick PJ: Pharmacokinetics of second generation antidepressants: bupropion. Psychopharmacol

Bull 27:513–519, 1991 [PubMed]

Goodnick PJ, Puig A, DeVane CL, et al: Mirtazapine in major depression with comorbid generalized

anxiety disorder. J Clin Psychiatry 60:446–448, 1999 [PubMed]

Graber MA, Hoehns TB, Perry PJ: Sertraline-phenelzine drug interaction: a serotonin syndrome

reaction. Ann Pharmacother 28:732–735, 1994 [PubMed]

Grimsley SR, Jann MW: Paroxetine, sertraline, and fluvoxamine: new selective serotonin reuptake

inhibitors. Clin Pharm 11:930–957, 1992 [PubMed]

Gupta S, Ghaly N, Dewan M: Augmenting fluoxetine with dextroamphetamine to treat refractory

depression. Hosp Community Psychiatry 43:281–283, 1992 [PubMed]

Gupta S, Droney T, Masand P, et al: SSRI-induced sexual dysfunction treated with sildenafil. Depress

Anxiety 9:180–182, 1999 [PubMed]

Hamilton MS, Opler LA: Akathisia, suicidality, and fluoxetine. J Clin Psychiatry 53: 401–406, 1992 [also

see comments]

Hammad TA, Laughren T, Racoosin J: Suicidality in pediatric patients treated with antidepressant

drugs. Arch Gen Psychiatry 63(3):332–339, 2006a

Hammad TA, Laughren TP, Racoosin JA: Suicide rates in short-term randomized controlled trials of

newer antidepressants. J Clin Psychopharmacol 26(2):203–207, 2006b

Hamner MB, Frueh BC: Response to venlafaxine in a previously antidepressant treatment-resistant

combat veteran with post-traumatic stress disorder. Int Clin Psychopharmacol 13:233–234, 1998

[PubMed]

Haria M, Fitton A, McTavish D: Trazodone: a review of its pharmacology, therapeutic use in depression

and therapeutic potential in other disorders. Drugs Aging 4:331–355, 1994 [PubMed]

Harkin A, Kelly JP, McNamara M, et al: Activity and onset of action of reboxetine and effect of

Page 69 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chaptercombination with sertraline in an animal model of depression. Eur J Pharmacol 364:123–132, 1999

[PubMed]

Harris MG, Benfield P: Fluoxetine: a review of its pharmacodynamic and pharmacokinetic properties,

and therapeutic use in older patients with depressive illness. Drugs Aging 6:64–84, 1995 [PubMed]

Henry JA: Overdose and safety with fluvoxamine. Int Clin Psychopharmacol 6 (suppl 3): 41–45

[discussion 45–47], 1991

Hidalgo R, Hertzberg MA, Mellman T, et al: Nefazodone in post-traumatic stress disorder: results from

six open-label trials. Int Clin Psychopharmacol 14(2):61–68, 1999 [PubMed]

Hirschfeld RM: Efficacy of SSRIs and newer antidepressants in severe depression: comparison with

TCAs. J Clin Psychiatry 60:326–335, 1999 [PubMed]

Hoehn-Saric R, McLeod DR, Hipsley PA: Effect of fluvoxamine on panic disorder. J Clin

Psychopharmacol 13:321–326, 1993 [PubMed]

Holliday SM, Benfield P: Venlafaxine: a review of its pharmacology and therapeutic potential in

depression. Drugs 49:280–294, 1995 [PubMed]

Holliday SM, Plosker GL: Paroxetine: a review of its pharmacology, therapeutic use in depression and

therapeutic potential in diabetic neuropathy. Drugs Aging 3: 278–299, 1993 [PubMed]

Horgan D: Combined fluoxetine and desipramine in resistant depression (letter). Aust N Z J Psychiatry

27:166, 168, 1993 [also see comments]

Howland RH: Pharmacotherapy of dysthymia: a review. J Clin Psychopharmacol 11: 83–92, 1991

[PubMed]

Jacobsen FM: Fluoxetine-induced sexual dysfunction and an open trial of yohimbine. J Clin Psychiatry

53:119–122, 1992 [also see comments]

Jaffe PD, Batziris HP, van der Hoeven P, et al: A study involving venlafaxine overdoses: comparison of

fatal and therapeutic concentrations in postmortem specimens. J Forensic Sci 44:193–196, 1999

[PubMed]

Jenner PN: Paroxetine: an overview of dosage, tolerability, and safety. Int Clin Psychopharmacol 6

(suppl 4):69–80, 1992

Jermain DM, Preece CK, Sykes RL, et al: Luteal phase sertraline treatment for premenstrual dysphoric

disorder: results of a double-blind, placebo-controlled, crossover study. Arch Fam Med 8:328–332,

1999 [PubMed]

Johnson H, Bouman WP, Lawton J: Withdrawal reaction associated with venlafaxine. BMJ 317

(7161):787, 1998 [PubMed]

Judd FK, Moore K, Norman TR, et al: A multicentre double blind trial of fluoxetine versus amitriptyline

in the treatment of depressive illness. Aust N Z J Psychiatry 27:49–55, 1993 [PubMed]

Kaizar EE, Greenhouse JB, Seltman H, et al: Do antidepressants cause suicidality in children? A

Bayesian meta-analysis. Clin Trials 3(2):73–90 [discussion 91–98], 2006

Kasper S, Wolf R: Successful treatment of reboxetine-induced urinary hesitancy with tamsulosin. Eur

Neuropsychopharmacol 12:119–122, 2002 [PubMed]

Katona CL, Abou-Saleh MT, Harrison DA, et al: Placebo-controlled trial of lithium augmentation of

fluoxetine and lofepramine. Br J Psychiatry 166:80–86, 1995 [PubMed]

Kavoussi RJ, Liu J, Coccaro EF: An open trial of sertraline in personality disordered patients with

impulsive aggression. J Clin Psychiatry 55:137-141, 1994

Page 70 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterKaye WH, Weltzin TE, Hsu LK, et al: An open trial of fluoxetine in patients with anorexia nervosa. J Clin

Psychiatry 52:464–471, 1991 [PubMed]

Kazal L Jr, Hall DL, Miller LG, et al: Fluoxetine-induced SIADH: a geriatric occurrence? J Fam Pract

36:341–343, 1993 [PubMed]

Keller M, Montgomery S, Ball W, et al: Lack of efficacy of the substance P (neurokinin 1) receptor

antagonist aprepitant in the treatment of major depressive disorder. Biol Psychiatry 59:216–223, 2006

[PubMed]

Keller Ashton A, Hamer R, Rosen RC: Serotonin reuptake inhibitor–induced sexual dysfunction and its

treatment: a large-scale retrospective study of 596 psychiatric outpatients. J Sex Marital Ther 23:165–

175, 1997

Kennedy SH, Emsley R: Placebo-controlled trial of agomelatine in the treatment of major depressive

disorder. Eur Neuropsychopharmacol 16(2):93–100, 2006 [PubMed]

Keppel Hesselink JM, de Jongh PM: Sertraline in the prevention of depression (comment). Br J

Psychiatry 161:270–271, 1992

Kiayias JA, Vlachou ED, Lakka-Papadodima E: Venlafaxine HCl in the treatment of painful peripheral

diabetic neuropathy (letter; see comment). Diabetes Care 23: 699, 2000 [PubMed]

Killen JD, Robinson TN, Ammerman S, et al: Randomized clinical trial of the efficacy of bupropion

combined with nicotine patch in the treatment of adolescent smokers. J Consult Clin Psychol 72:729–

735, 2004 [PubMed]

Kincaid RL, McMullin MM, Crookham SB, et al: Report of a fluoxetine fatality. J Anal Toxicol 14:327–

329, 1990 [PubMed]

Klieser E, Lehmann E, Heinrich K: Fluoxetine in patients with major depressive disorder—a responder

analysis. Pharmacopsychiatry 28:14–19, 1995 [PubMed]

Kline NS: Clinical experience with iproniazid (Marsilid). J Clin Exp Psychopathol 19 (2, suppl 1): 72–78

[discussion 78–79], 1958

Kotlyar M, Golding M, Brewer ER, et al: Possible nefazodone withdrawal syndrome (letter). Am J

Psychiatry 156:1117, 1999 [Full Text] [PubMed]

Koutouvidis N, Pratikakis M, Fotiadou A: The use of mirtazapine in a group of 11 patients following

poor compliance to selective serotonin reuptake inhibitor treatment due to sexual dysfunction. Int Clin

Psychopharmacol 14:253–255, 1999 [PubMed]

Kramer MS, Cutler N, Feighner J, et al: Distinct mechanism for antidepressant activity by blockade of

central substance P receptors. Science 281:1640–1645, 1998 [also see comments]

Kramer MS, Winokur A, Kelsey J, et al: Demonstration of the efficacy and safety of a novel substance P

(NK1) receptor antagonist in major depression. Neuropsychopharmacology 29:385–392, 2004

[PubMed]

Kuhn R: Uber die behandlung depressiver zustande mit einem iminodibenzylderivat (G22355). Schweiz

Med Wochenschr 87:1135–1140, 1957 [PubMed]

Kuhn R: The treatment of depressive states with G22 355 (imipramine hydrochloride). Am J Psychiatry

115:459–464, 1958 [PubMed]

Kupfer DJ, Frank E, Perel JM, et al: Five-year outcome for maintenance therapies in recurrent

depression. Arch Gen Psychiatry 49:769–773, 1992 [PubMed]

Labbate LA, Pollack MH: Treatment of fluoxetine-induced sexual dysfunction with bupropion: a case

Page 71 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterreport. Ann Clin Psychiatry 6:13–15, 1994 [PubMed]

Landen M, Eriksson E, Agren H, et al: Effect of buspirone on sexual dysfunction in depressed patients

treated with selective serotonin reuptake inhibitors. J Clin Psychopharmacol 19:268–271, 1999

[PubMed]

Lang E, Hord AH, Denson D: Venlafaxine hydrochloride (Effexor) relieves thermal hyperalgesia in rats

with an experimental mononeuropathy. Pain 68:151–155, 1996 [PubMed]

Lauber C: Nefazodone withdrawal syndrome (letter). Can J Psychiatry 44:285–286, 1999 [PubMed]

Leaf EV: Comment: venlafaxine overdose and seizure. Ann Pharmacother 32: 135–136, 1998

[PubMed]

Leiononen E, Skarstein J, Behnke K, et al: Efficacy and tolerability of mirtazapine versus citalopram: a

double-blind, randomized study in patients with major depressive disorder. Int Clin Psychopharmacol

14:329–337, 1999

Lenderking WR, Tennen H, Nackley JF, et al: The effects of venlafaxine on social activity level in

depressed outpatients. J Clin Psychiatry 60:157–163, 1999 [PubMed]

Liappas J, Paparrigopoulos T, Tzavellas E, et al: Mirtazapine and venlafaxine in the management of

collateral psychopathology during alcohol detoxification. Prog Neuropsychopharmacol Biol Psychiatry 29

(1):55–60, 2005 [PubMed]

Liebowitz M, Karoun F, Quitkin F: Biochemical effects of L-deprenyl in atypical depressives. Biol

Psychiatry 20:558–565, 1985 [PubMed]

Liebowitz MR, Quitkin FM, Stewart JW: Antidepressant specificity in atypical depression. Arch Gen

Psychiatry 45:129–137, 1988 [PubMed]

Lonnqvist J, Sihvo S, Syvalahti E, et al: Moclobemide and fluoxetine in atypical depression: a double

blind trial. J Affect Disord 32:169–177, 1994 [PubMed]

Loo H, Dalery J, Macher JP, et al: Pilot study comparing in blind the therapeutic effect of two doses of

agomelatine, melatoninergic agonist and selective 5HT2C receptors antagonist, in the treatment of

major depressive disorders [in French]. Encephale 28(4):356–362, 2002a

Loo H, Hale A, D’haenen H: Determination of the dose of agomelatine, a melatoninergic agonist and

selective 5-HT(2C) antagonist, in the treatment of major depressive disorder: a placebo-controlled

dose range study. Int Clin Psychopharmacol 17(5):239–247, 2002b

Lotufo-Neto F, Trivedi M, Thase ME: Meta-analysis of the reversible inhibitors of monoamine oxidase

type A moclobemide and brofaromine for the treatment of depression. Neuropsychopharmacology

20:226–247, 1999 [PubMed]

Louie AK, Lewis TB, Lannon RA: Use of low-dose fluoxetine in major depression and panic disorder. J

Clin Psychiatry 54:435–438, 1993 [PubMed]

Lucca A, Serretti A, Smeraldi E: Effect of reboxetine augmentation in SSRI resistant patients. Hum

Psychopharmacol 15(2):143–145, 2000 [PubMed]

Luckhaus C, Jacob C: Venlafaxine withdrawal syndrome not prevented by maprotiline, but resolved by

sertraline (letter). Int J Neuropsychopharmacol 4(1):43–44, 2001 [PubMed]

Macbeth R, Rajagopalan M: Venlafaxine withdrawal syndrome (letter). Aust N Z J Med 28:218, 1998

[PubMed]

Mainie I, McGurk C, McClintock G, et al: Seizures after bupropion overdose (letter). Lancet 357

(9268):1624, 2001 [PubMed]

Page 72 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterMann JJ, Aarons SF, Wilner PJ, et al: A controlled study of the antidepressant efficacy and side effects

of (–)-deprenyl: a selective monoamine oxidase inhibitor. Arch Gen Psychiatry 46:45–50, 1989

[PubMed]

Massana J: Reboxetine versus fluoxetine: an overview of efficacy and tolerability. J Clin Psychiatry 59

(suppl 14):8–10, 1998

Massana J, Moller HJ, Burrows GD, et al: Reboxetine: a double-blind comparison with fluoxetine in

major depressive disorder. Int Clin Psychopharmacol 14:73–80, 1999 [PubMed]

McCabe BT, Tsuang MT: Dietary consideration in MAO inhibitor regimens. J Clin Psychiatry 43:178–

181, 1982 [PubMed]

McGrath PJ, Quitkin FM, Harrison W, et al: Treatment of melancholia with tranylcypromine. Am J

Psychiatry 141:288–289, 1984 [PubMed]

McGrath PJ, Stewart JW, Quitkin FM, et al: Gepirone treatment of atypical depression: preliminary

evidence of serotonergic involvement. J Clin Psychopharmacol 14: 347–352, 1994 [PubMed]

McGrath PJ, Stewart JW, Fava M, et al: Tranylcypromine versus venlafaxine plus mirtazapine following

three failed antidepressant medication trials for depression: a STAR*D report. Am J Psychiatry 163

(9):1531–1541, 2006 [Full Text] [PubMed]

Mendlewicz J: Efficacy of fluvoxamine in severe depression. Drugs 2:32–37 [discussion 37–39], 1992

Michelson D, Bancroft J, Targum S, et al: Female sexual dysfunction associated with antidepressant

administration: a randomized, placebo-controlled study of pharmacologic intervention. Am J Psychiatry

157:239–243, 2000 [Full Text] [PubMed]

Michelson D, Kociban K, Tamura R, et al: Mirtazapine, yohimbine or olanzapine augmentation therapy

for serotonin reuptake–associated female sexual dysfunction: a randomized, placebo-controlled trial. J

Psychiatr Res 36:147–152, 2002 [PubMed]

Michelson D, Adler LA, Amsterdam JD, et al: Addition of atomoxetine for depression incompletely

responsive to sertraline: a randomized, double-blind, placebo-controlled study, in 2006 Syllabus and

Proceedings Summary, American Psychiatric Association 159th Annual Meeting, New York, May 20–25,

2006. Arlington, VA, American Psychiatric Association, 2006, p 74

Mirin SM, Schatzberg AF, Creasey DE: Hypomania and mania after tricyclic withdrawal. Am J Psychiatry

138:87–89, 1981 [PubMed]

Mitchell AJ: The role of corticotropin releasing factor in depressive illness: a critical review. Neurosci

Biobehav Rev 22:635–651, 1998 [PubMed]

Modell JG, Rosenthal NE, Harriett AE, et al: Seasonal affective disorder and its prevention by

anticipatory treatment with bupropion XL. Biol Psychiatry 58(8):658–667, 2005 [PubMed]

Monoamine oxidase inhibitors and anesthesia: update. Int Drug Ther Newsl 24:13–14, 1989

Monteleone P, Gnocchi G: Evidence for a linear relationship between plasma trazodone levels and

clinical response in depression in the elderly. Clin Neuropharmacol 13 (suppl 1):84–89, 1990

Montgomery SA: Chairman’s overview: the place of reboxetine in antidepressant therapy. J Clin

Psychiatry 59 (suppl 14):26–29, 1998

Mooney JJ, Schatzberg AF, Cole JO, et al: Enhanced signal transduction by adenylate cyclase in platelet

membranes of patients showing antidepressant responses to alprazolam: preliminary data. J Psychiatr

Res 19:65–75, 1985 [PubMed]

Mucci M: Reboxetine: a review of antidepressant tolerability. J Psychopharmacol 11 (suppl 4):S33–

Page 73 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterS37, 1997

Muehlbacher M, Nickel MK, Nickel C, et al: Mirtazapine treatment of social phobia in women: a

randomized, double-blind, placebo-controlled study. J Clin Psychopharmacol 25(6):580–583, 2005

[PubMed]

Murdoch D, McTavish D: Sertraline: a review of its pharmacodynamic and pharmacokinetic properties,

and therapeutic potential in depression and obsessive-compulsive disorder. Drugs 44:604–624, 1992

[PubMed]

Murphy GM Jr, Kremer C, Rodrigues HE, et al: Pharmacogenetics of antidepressant medication

intolerance. Am J Psychiatry 160:1830–1835, 2003 [also see comment]

Nefazodone for depression. Med Lett Drugs Ther 37:33–35, 1995

Nelson JC, Shottenfeld RS, Conrad CD: Hypomania after desipramine withdrawal. Am J Psychiatry

140:624–625, 1983 [PubMed]

Nemeroff CB: Paroxetine: an overview of the efficacy and safety of a new selective serotonin reuptake

inhibitor in the treatment of depression. J Clin Psychopharmacol 13 (6, suppl 2):10S–17S, 1993

Nemeroff CB: The clinical pharmacology and use of paroxetine, a new selective serotonin reuptake

inhibitor. Pharmacotherapy 14:127–138, 1994 [PubMed]

Nemeroff CB, Entsuah RA, Willard B, et al: Venlafaxine and SSRIs pooled remission analysis (NR263),

in 2003 New Research Program and Abstracts, American Psychiatric Association 156th Annual Meeting,

San Francisco, CA, May 17–22, 2003. Washington, DC, American Psychiatric Association, 2003

Niederhofer H: Atomoxetine also effective in patients suffering from narcolepsy? Sleep 28(9):1189,

2005 [PubMed]

Niederhofer H: Is atomoxetine also effective in patients suffering from Tourette syndrome? J Child

Neurol 21(9):823, 2006 [PubMed]

Nierenberg AA: The treatment of severe depression: is there an efficacy gap between the SSRIs and

TCA antidepressant generations? J Clin Psychiatry 55 (9, suppl): 55–61 [discussion 60–61, 98–100],

1994

Nierenberg AA, Keck PE: Management of monoamine oxidase inhibition–associated insomnia with

trazodone. J Clin Psychopharmacol 9:42–45, 1989 [PubMed]

Nierenberg AA, Cole JO, Glass L: Possible trazodone potentiation of fluoxetine: a case series. J Clin

Psychiatry 53:83–85, 1992 [PubMed]

Nierenberg AA, Feighner JP, Rudolph R, et al: Venlafaxine for treatment-resistant unipolar depression.

J Clin Psychopharmacol 14:419–423, 1994 [PubMed]

Nierenberg AA, McLean NE, Alpert JE, et al: Early nonresponse to fluoxetine as a predictor of poor 8-

week outcome. Am J Psychiatry 152:1500–1503, 1995 [PubMed]

Nierenberg AA, Farabaugh AH, Alpert JE, et al: Timing of onset of antidepressant response with

fluoxetine treatment. Am J Psychiatry 157:1423–1428, 2000 [Full Text] [PubMed]

Norden MJ: Fluoxetine in borderline personality disorder. Prog Neuropsychopharmacol Biol Psychiatry

13:885–893, 1989 [PubMed]

Norden MJ: Buspirone treatment of sexual dysfunction associated with selective serotonin reuptake

inhibitors. Depression 2:109–112, 1994

Norton PA, Zinner NR, Yalcin I, et al: Duloxetine versus placebo in the treatment of stress urinary

incontinence. Am J Obstet Gynecol 187:40–48, 2002 [PubMed]

Page 74 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterNurnberg HG, Hensley PL, Lauriello J, et al: Sildenafil for women patients with antidepressant-induced

sexual dysfunction. Psychiatr Serv 50:1076–1078, 1999a

Nurnberg HG, Lauriello J, Hensley PL, et al: Sildenafil for iatrogenic serotonergic antidepressant

medication–induced sexual dysfunction in 4 patients. J Clin Psychiatry 60:33–35, 1999b

Nurnberg HG, Thompson PM, Hensley PL: Antidepressant medication change in a clinical treatment

setting: a comparison of the effectiveness of selective serotonin reuptake inhibitors. J Clin Psychiatry

60:574–579, 1999c

Nurnberg HG, Gelenberg A, Hargreave TB, et al: Efficacy of sildenafil citrate for the treatment of

erectile dysfunction in men taking serotonin reuptake inhibitors. Am J Psychiatry 158:1926–1928,

2001 [Full Text] [PubMed]

Olfson M, Marcus SC, Shaffer D: Antidepressant drug therapy and suicide in severely depressed

children and adults: a case-control study. Arch Gen Psychiatry 63:865–872, 2006 [PubMed]

Oslin DW, Ten Have TR, Streim JE, et al: Probing the safety of medications in the frail elderly: evidence

from a randomized clinical trial of sertraline and venlafaxine in depressed nursing home residents. J

Clin Psychiatry 64:875–882, 2003 [PubMed]

Otani K, Tanaka O, Kaneko S, et al: Mechanisms of the development of trazodone withdrawal

symptoms. Int Clin Psychopharmacol 9:131–133, 1994 [PubMed]

Ottevanger EA: The efficacy of fluvoxamine in patients with severe depression. Prog

Neuropsychopharmacol Biol Psychiatry 18:731–740, 1994 [PubMed]

Pande AC, Sayler ME: Severity of depression and response to fluoxetine. Int Clin Psychopharmacol

8:243–245, 1993 [PubMed]

Papakostas GI, Petersen TJ, Burns AM, et al: Adjunctive atomoxetine for residual fatigue in major

depressive disorder. J Psychiatr Res 40(4):370–373, 2006 [PubMed]

Papp M, Litwa E, Gruca P, Mocaer E: Anxiolytic-like activity of agomelatine and melatonin in three

animal models of anxiety. Behav Pharmacol 17(1):9–18, 2006 [PubMed]

Paris PA, Saucier JR: ECG conduction delays associated with massive bupropion overdose. J Toxicol

Clin Toxicol 36(6):595–598, 1998 [PubMed]

Patten SB: The comparative efficacy of trazodone and imipramine in the treatment of depression. Can

Med Assoc J 146:1177–1182, 1992 [PubMed]

Pearlstein TB, Stone AB: Long-term fluoxetine treatment of late luteal phase dysphoric disorder. J Clin

Psychiatry 55:332–335, 1994 [PubMed]

Pernia A, Mico JA, Calderon E, et al: Venlafaxine for the treatment of neuropathic pain. J Pain Symptom

Manage 19:408–410, 2000 [PubMed]

Pescatori ES, Engelman JC, Davis G, et al: Priapism of the clitoris: a case report following trazodone

use. J Urol 149:1557–1559, 1993 [PubMed]

Phanjoo A: The elderly depressed and treatment with fluvoxamine. Int Clin Psychopharmacol 6 (suppl

3):33–37 [discussion 37–39], 1991

Phanjoo AL, Wonnacott S, Hodgson A: Double-blind comparative multicentre study of fluvoxamine and

mianserin in the treatment of major depressive episode in elderly people. Acta Psychiatr Scand

83:476–479, 1991 [PubMed]

Pinzani V, Ginies E, Robert L, et al: Venlafaxine withdrawal syndrome: report of six cases and review of

the literature [in French]. Rev Medecine Interne 21(3):282–284, 2000 [PubMed]

Page 75 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterPope HG, Hudson JI, Jonas JM, et al: Bulimia treated with imipramine: a placebo-controlled, double

blind study. Am J Psychiatry 140:554–558, 1983 [PubMed]

Preskorn SH: Should bupropion dosage be adjusted based upon therapeutic drug monitoring?

Psychopharmacol Bull 27:637–643, 1991 [PubMed]

Price J, Grunhaus LJ: Treatment of clomipramine-induced anorgasmia with yohimbine: a case report. J

Clin Psychiatry 51:32–33, 1990 [PubMed]

Prien RF, Kupfer DJ, Mansky PA, et al: Drug therapy in the prevention of recurrences in unipolar and

bipolar affective disorders. Arch Gen Psychiatry 41:1096–1104, 1984 [PubMed]

Quitkin F, Gibertine M: Patients with probable atypical depression are responsive to the 5-HT1a partial

agonist, gepirone-ER. Presentation at the annual meeting of the American College of

Neuropsychopharmacology, San Juan, Puerto Rico, 2001

Quitkin F, Rabkin A, Klein DF: Monoamine oxidase inhibitors. Arch Gen Psychiatry 36:749–760, 1979

[PubMed]

Quitkin FM, Rabkin JG, Ross D, et al: Duration of antidepressant drug treatment: what is an adequate

trial? Arch Gen Psychiatry 41:238–245, 1984 [PubMed]

Quitkin FM, McGrath PJ, Stewart JW, et al: Chronological milestones to guide drug change: when

should clinicians switch antidepressants? Arch Gen Psychiatry 53: 785–792, 1996 [PubMed]

Quitkin FM, Taylor BP, Kremer C: Does mirtazapine have a more rapid onset than SSRIs? J Clin

Psychiatry 62:358–361, 2001 [PubMed]

Raby WN: Treatment of venlafaxine discontinuation symptoms with ondansetron (letter). J Clin

Psychiatry 59:621–622, 1998 [PubMed]

Reimherr FW, Wood DR, Byerley B, et al: Characteristics of responders to fluoxetine. Psychopharmacol

Bull 20:70–72, 1984 [PubMed]

Reimherr FW, Chouinard G, Cohn CK, et al: Antidepressant efficacy of sertraline: a double-blind,

placebo- and amitriptyline-controlled, multicenter comparison study in outpatients with major

depression. J Clin Psychiatry 51 (12, suppl):18–27, 1990 [also see comments]

Richelson E: Synaptic pharmacology of antidepressants: an update. McLean Hospital Journal 13:67–88,

1988

Richelson E, Nelson A: Antagonism by antidepressants of neurotransmitter receptors of normal human

brain in vitro. J Pharmacol Exp Ther 230:94–102, 1984 [PubMed]

Rickels K, Schweizer E: Clinical overview of the selective serotonin reuptake inhibitors. J Clin Psychiatry

51 (12, suppl):9–12, 1990

Rickels K, Chung HR, Csanolsi IB, et al: Alprazolam, diazepam, imipramine, and placebo in outpatients

with major depression. Arch Gen Psychiatry 44: 862–866, 1987 [PubMed]

Rickels K, Downing R, Schweizer E, et al: Antidepressants for the treatment of generalized anxiety

disorder: a placebo-controlled comparison of imipramine, trazodone, and diazepam. Arch Gen

Psychiatry 50:884–895, 1993 [PubMed]

Rickels K, Schweizer E, Clary C, et al: Nefazodone and imipramine in major depression: a placebo

controlled trial. Br J Psychiatry 164:802–805, 1994 [PubMed]

Riggs PD, Leon SL, Mikulich SK, et al: An open trial of bupropion for ADHD in adolescents with

substance use disorders and conduct disorder. J Am Acad Child Adolesc Psychiatry 37:1271–1278,

1998 [PubMed]

Page 76 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterRohrig TP, Ray NG: Tissue distribution of bupropion in a fatal overdose. J Anal Toxicol 16:343–345,

1992 [PubMed]

Roose SP, Glassman AH: Cardiovascular effects of tricyclic antidepressants in depressed patients with

and without heart disease. J Clin Psychiatry 50 (July suppl):1–18, 1989

Roose SP, Glassman AH, Attia E, et al: Selective serotonin reuptake inhibitor efficacy in melancholia

and atypical depression. Paper presented at the 147th annual meeting of the American Psychiatric

Association, Philadelphia, PA, May 21–26, 1994

Rosen R, Shabsigh R, Berber M, et al: Vardenafil Study Site Investigators: Efficacy and tolerability of

vardenafil in men with mild depression and erectile dysfunction: the Depression-Related Improvement

With Vardenafil for Erectile Response Study. Am J Psychiatry 163(1):79–87, 2006 [Full Text] [PubMed]

Rothschild AJ: Fluoxetine-nortriptyline therapy of treatment-resistant major depression in a geriatric

patient. J Geriatr Psychiatry Neurol 7:137–138, 1994 [PubMed]

Rothschild AJ, Locke CA: Reexposure to fluoxetine after serious suicide attempts in three patients. J

Clin Psychiatry 52:491–493, 1991 [PubMed]

Rothschild AJ, Samson JA, Bessette MP, et al: Efficacy of the combination of fluoxetine and

perphenazine in the treatment of psychotic depression. J Clin Psychiatry 54: 338–342, 1993 [PubMed]

Rudorfer MV, Manji HK, Potter WZ: Comparative tolerability profiles of the newer versus older

antidepressants. Drug Saf 10:18–46, 1994 [PubMed]

Ruoff GE: Depression in the patient with chronic pain. J Fam Pract 43 (6, suppl):S25–S33 [discussion

S34], 1996

Rush AJ, Trivedi MH, Wisniewski SR, et al., STAR*D Study Team: Bupropion-SR, sertraline, or

venlafaxine-XR after failure of SSRIs for depression. N Engl J Med 354(12):1231–1242, 2006 [PubMed]

Sacchetti E, Conte G, Guarneri L: Are SSRI antidepressants a clinically homogeneous class of

compounds? Lancet 344:126–127, 1994 [PubMed]

Salzman C, Wolfson AN, Schatzberg AF, et al: Effect of fluoxetine on anger in symptomatic volunteers

with borderline personality disorder. J Clin Psychopharmacol 15:23–29, 1995 [PubMed]

Sarchiapone M, Amore M, De Risio S, et al: Mirtazapine in the treatment of panic disorder: an open

label trial. Int Clin Psychopharmacol 18(1):35–38, 2003 [PubMed]

Sargant W: The treatment of anxiety states and atypical depressions by the monoamine oxidase

inhibitor drugs. J Neuropsychiatry 3 (suppl 1):96–103, 1962

Schatzberg AF: Trazodone: a 5-year review of antidepressant efficacy. Psychopathology 20 (suppl

1):48–56, 1987

Schatzberg AF: Triazolobenzodiazepines in the treatment of depressive disorders, in Proceedings of the

British Association for Psychopharmacology—Thirty Years On. Edited by Leonard B. London, CNS

Publishers, 1990

Schatzberg AF, Cole JO: Benzodiazepines in depressive disorders. Arch Gen Psychiatry 35:1359–1365,

1978 [PubMed]

Schatzberg AF, Cole JO, Blumer DP: Speech blockage: a tricyclic side effect. Am J Psychiatry 135:600–

601, 1978 [PubMed]

Schatzberg AF, Rosenbaum AH, Orsulak PJ, et al: Toward a biochemical classification of depressive

disorders, III: pretreatment urinary MHPG levels as predictors of response to maprotiline.

Psychopharmacology (Berl) 75:34–38, 1981 [PubMed]

Page 77 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterSchatzberg AF, Cole JO, Cohen BM, et al: Survey of depressed patients who have failed to respond to

treatment, in Affective Disorders. Edited by Davis JM, Maas J. Washington, DC, American Psychiatric

Press, 1983, pp 73–85

Schatzberg AF, Kremer C, Rodrigues HE, et al: Double-blind, randomized comparison of mirtazapine

and paroxetine in elderly depressed patients. Am J Geriatr Psychiatry 10:541–550, 2002 [PubMed]

Schneier FR, Liebowitz MR, Davies SO, et al: Fluoxetine in panic disorder. J Clin Psychopharmacol

10:119–121, 1990 [PubMed]

Schwartz D, Blendl M: Sedation and anxiety reducing properties of trazodone, in Trazodone: Modern

Problems in Pharmacopsychiatry, Vol 9. Edited by Ban TA, Silvestrini B. Basel, Switzerland, S Karger,

1974, pp 29–46

Shatkin JP: Atomoxetine for the treatment of pediatric nocturnal enuresis. J Child Adolesc

Psychopharmacol 14(3):443–447, 2004 [PubMed]

Sheehan DV, Davidson J, Manshreck TC, et al: Lack of efficacy of a new antidepressant (bupropion) in

the treatment of panic disorder with phobias. J Clin Psychopharmacol 3:28–31, 1983 [PubMed]

Shopsin B: Bupropion’s prophylactic efficacy in bipolar affective illness. J Clin Psychiatry 44:163–169,

1983 [PubMed]

Shrivastava RK, Cohn C, Crowder J, et al: Long-term safety and clinical acceptability of venlafaxine and

imipramine in outpatients with major depression. J Clin Psychopharmacol 14:322–329, 1994 [PubMed]

Shrivastava RK, Shrivastava S, Overweg N, et al: Amantadine in the treatment of sexual dysfunction

associated with selective serotonin reuptake inhibitors (letter). J Clin Psychopharmacol 15:83–84, 1995

[PubMed]

Simon GE, VonKorff M, Heiligenstein JH, et al: Initial antidepressant choice in primary care:

effectiveness and cost of fluoxetine vs. tricyclic antidepressants. JAMA 275:1897–1902, 1996 [PubMed]

Simon GE, Savarino J, Operskalski B, et al: Suicide risk during antidepressant treatment. Am J

Psychiatry 163(1):41–47, 2006 [Full Text] [PubMed]

Solyom L, Solyom C, Ledwidge B: Fluoxetine treatment of obsessive-compulsive disorder. Can J

Psychiatry 36:723–727, 1991 [PubMed]

Sondergard L, Kvist K, Andersen PK, et al: Do antidepressants precipitate youth suicide? A nationwide

pharmacoepidemiological study. Eur Child Adolesc Psychiatry 15(4):232–240, 2006a

Sondergard L, Kvist K, Andersen PK, et al: Do antidepressants prevent suicide? Int Clin

Psychopharmacol 21(4):211–218, 2006b

Songer DA, Schulte H: Venlafaxine for the treatment of chronic pain. Am J Psychiatry 153:737, 1996

[PubMed]

Spar E: Plasma trazodone concentrations in elderly depressed inpatients: cardiac and short-term

efficacy. J Clin Psychopharmacol 7:406–409, 1987 [PubMed]

Spiegel K, Kalb R, Pasternak GW: Analgesic activity of tricyclic antidepressants. Ann Neurol 13:462–

465, 1983 [PubMed]

Spiller HA, Ramoska EA, Krenzelok EP, et al: Bupropion overdose: a 3-year multi-center retrospective

analysis. Am J Emerg Med 12:43–45, 1994 [PubMed]

Stamenkovic M, Pezawas L, de Zwaan M, et al: Mirtazapine in recurrent brief depression. Int Clin

Psychopharmacol 13:39–40, 1998 [PubMed]

Stark P, Fuller RW, Wong DT: The pharmacologic profile of fluoxetine. J Clin Psychiatry 46:7–13, 1985

Page 78 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapter[PubMed]

Stein MB, Liebowitz MR, Lydiard R, et al: Paroxetine treatment of generalized social phobia (social

anxiety disorder): a randomized controlled trial. JAMA 280:708–713, 1998 [PubMed]

Steiner M, Steinberg S, Stewart D, et al: Fluoxetine in the treatment of premenstrual dysphoria.

Canadian Fluoxetine/Premenstrual Dysphoria Collaborative Study Group. N Engl J Med 332:1529–1534,

1995 [also see comments]

Stewart JW, Harrison W, Quitkin FM, et al: Phenelzine-induced pyridoxine deficiency. J Clin

Psychopharmacol 4:225–226, 1984 [PubMed]

Stokes PE: Fluoxetine: a five-year review. Clin Ther 15:216–243 [discussion 215], 1993

Storrow A: Bupropion overdose and seizure. Am J Emerg Med 12:183–184, 1994 [PubMed]

Stuppaeck CH, Geretsegger C, Whitworth AB, et al: A multicenter double-blind trial of paroxetine

versus amitriptyline in depressed inpatients. J Clin Psychopharmacol 14:241–246, 1994 [PubMed]

Sunderland T, Cohen RM, Thompson KE, et al: L-Deprenyl treatment of older depressives (NR159), in

1989 New Research Program and Abstracts, American Psychiatric Association 142nd Annual Meeting,

San Francisco, May 6–11, 1989. Washington, DC, American Psychiatric Association, 1989, p 101

Sunderland T, Cohen RM, Molchan S, et al: High-dose selegiline in treatment-resistant older depressive

patients. Arch Gen Psychiatry 51:607–615, 1994 [PubMed]

Taylor K, Rowbotham MC: Venlafaxine hydrochloride and chronic pain. West J Med 165:147–148, 1996

[PubMed]

Taylor MJ, Rudkin L, Hawton K: Strategies for managing antidepressant-induced sexual dysfunction:

systematic review of randomised controlled trials. J Affect Disord 88(3):241–254, 2005 [PubMed]

Teicher MH, Cohen BM, Baldessarini RJ, et al: Severe daytime somnolence in patients treated with an

MAOI. Am J Psychiatry 145:1552–1556, 1988 [PubMed]

Teicher MH, Glod C, Cole JO: Emergence of intense suicidal preoccupation during fluoxetine treatment.

Am J Psychiatry 147:207–210, 1990 [PubMed]

Teicher MH, Glod CA, Cole JO: Antidepressant drugs and the emergence of suicidal tendencies. Drug

Saf 8:186–212, 1993 [PubMed]

Thase ME: Effects of venlafaxine on blood pressure: a meta-analysis of original data from 3744

depressed patients. J Clin Psychiatry 59:502–508, 1998 [PubMed]

Thase ME: Effectiveness of antidepressants: comparative remission rates. J Clin Psychiatry 64 (suppl

2):3–7, 2003

Thase ME, Blomgren SL, Birkett MA, et al: Fluoxetine treatment of patients with major depressive

disorder who failed initial treatment with sertraline. J Clin Psychiatry 58:16–21, 1997 [PubMed]

Thase ME, Entsuah AR, Rudolph RL: Remission rates during treatment with venlafaxine or selective

serotonin reuptake inhibitors. Br J Psychiatry 178: 234–241, 2001 [PubMed]

Thompson C: Mirtazapine versus selective serotonin reuptake inhibitors. J Clin Psychiatry 60 (suppl

17):18–22 [discussion 46–48], 1999

Tignol J, Stoker MJ, Dunbar GC: Paroxetine in the treatment of melancholia and severe depression. Int

Clin Psychopharmacol 7:91–94, 1992 [PubMed]

Tollefson GD, Rampey A Jr, Potvin JH, et al: A multicenter investigation of fixed-dose fluoxetine in the

treatment of obsessive-compulsive disorder. Arch Gen Psychiatry 51:559–567, 1994 [PubMed]

Page 79 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapterTrivedi MH, Fava M, Wisniewski SR, et al: STAR*D Study Team: Medication augmentation after the

failure of SSRIs for depression. N Engl J Med 354(12):1243–1252, 2006 [PubMed]

Turner R: Quality of life: experience with sertraline. Int Clin Psychopharmacol 9 (suppl 3): 27–31,

1994

van Bemmel AL, Havermans RG, van Diest R: Effects of trazodone on EEG sleep and clinical state in

major depression. Psychopharmacology (Berl) 107:569–574, 1992

van Laar MW, van Willigenburg AP, Volkerts ER: Acute and subchronic effects of nefazodone and

imipramine on highway driving, cognitive functions, and daytime sleepiness in healthy adult and

elderly subjects. J Clin Psychopharmacol 15:30–40, 1995

van Moffaert M, de Wilde J, Vereecken A, et al: Mirtazapine is more effective than trazodone: a double

blind controlled study in hospitalized patients with major depression. Int Clin Psychopharmacol 10:3–9,

1995

Vartiainen H, Leinonen E: Double-blind study of mirtazapine and placebo in hospitalized patients with

major depression. Eur Neuropsychopharmacol 4:145–150, 1994 [PubMed]

Volicer L, Rheaume Y, Cyr D: Treatment of depression in advanced Alzheimer’s disease using

sertraline. J Geriatr Psychiatry Neurol 7:227–229, 1994 [PubMed]

Wagner W, Plekkenpol B, Gray TE, et al: Review of fluvoxamine safety database. Drugs 2:48–53

[discussion 53–54], 1992

Walker PW, Cole JO, Gardner EA, et al: Improvement in fluoxetine-associated sexual dysfunction in

patients switched to bupropion. J Clin Psychiatry 54:459–465, 1993 [PubMed]

Walsh BT, Stewart JW, Wright L, et al: Treatment of bulimia with monoamine oxidase inhibitors. Am J

Psychiatry 139:1629–1630, 1982 [PubMed]

Walsh BT, Kaplan AS, Attia E, et al: Fluoxetine after weight restoration in anorexia nervosa: a

randomized controlled trial. JAMA 295(22):2605–2612, 2006 [erratum: JAMA 296(8):934, 2006]

Warrington SJ, Padgham C, Lader M: The Cardiovascular Effects of Antidepressants (Psychological

Medicine Monogr Suppl 16). Cambridge, UK, Cambridge University Press, 1989

Weilburg JB, Rosenbaum JF, Biederman J, et al: Fluoxetine added to non-MAOI antidepressants

converts nonresponders to responders: a preliminary report. J Clin Psychiatry 50:447–449, 1989

[PubMed]

Weisler RH, Johnston JA, Lineberry CG, et al: Comparison of bupropion and trazodone for the

treatment of major depression. J Clin Psychopharmacol 14:170–179, 1994 [PubMed]

Wheadon DE, Rampey A Jr, Thompson VL, et al: Lack of association between fluoxetine and suicidality

in bulimia nervosa. J Clin Psychiatry 53:235–241, 1992 [PubMed]

Wheatley D: Triple-blind, placebo-controlled trial of Ginkgo biloba in sexual dysfunction due to

antidepressant drugs. Hum Psychopharmacol 19(8):545–548, 2004 [PubMed]

Wheatley DP, van Moffaert M, Timmerman L, et al: Mirtazapine: efficacy and tolerability in comparison

with fluoxetine in patients with moderate to severe major depressive disorder. J Clin Psychiatry

59:306–312, 1998 [PubMed]

Wilcox CS, Ferguson JM, Dale JL, et al: A double-blind trial of low- and high-dose ranges of gepirone

ER compared with placebo in the treatment of depressed outpatients. Psychopharmacol Bull 32:335–

342, 1996 [PubMed]

Wilde MI, Plosker GL, Benfield P: Fluvoxamine. An updated review of its pharmacology and therapeutic

Page 80 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapteruse in depressive illness. Drugs 46:895–924, 1993 [PubMed]

Wolfe F, Cathey MA, Hawley DJ: A double-blind placebo-controlled trial of fluoxetine in fibromyalgia.

Scand J Rheumatol 23:255–259, 1994 [PubMed]

Wolfersdorf M, Barg T, Konig F, et al: Paroxetine in the treatment of inpatients with non-delusional

endogenous or neurotic depression. Schweiz Arch Neurol Psychiatr 145:15–18, 1994 [PubMed]

Yoon SJ, Pae CU, Kim DJ, et al: Mirtazapine for patients with alcohol dependence and comorbid

depressive disorders: a multicentre, open label study. Prog Neuropsychopharmacol Biol Psychiatry 30

(7):1196–1201, 2006 [PubMed]

Young AH, Gallagher P, Watson S, et al: Improvements in neurocognitive function and mood following

adjunctive treatment with mifepristone (RU-486) in bipolar disorder. Neuropsychopharmacology

29:1538–1545, 2004 [PubMed]

Zisook S, Rush AJ, Haight BR, et al: Use of bupropion in combination with serotonin reuptake

inhibitors. Biol Psychiatry 59(3):203–210, 2006 [PubMed]

Zobel AW, Nickel T, Kunzel HE, et al: Effects of the high-affinity corticotropin-releasing hormone

receptor 1 antagonist R121919 in major depression: the first 20 patients. J Psychiatr Res 34:171–181,

2000 [PubMed]

Zornberg GL, Pope H Jr: Treatment of depression in bipolar disorder: new directions for research. J Clin

Psychopharmacol 13:397–408, 1993 [PubMed]

Copyright © 2008 American Psychiatric Publishing, Inc. All Rights Reserved.

Page 81 of 81

Print: Chapter 3. Antidepressants

22/09/2008

http://www.psychiatryonline.com/popup.aspx?aID=231806&print=yes_chapter