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Arielle D. Stanford, Alexandra Sporn, Andrew D. Krystal, Richard D. Weiner, Sarah H. Lisanby: Chapter 27. Convulsive
and Other Somatic Therapies, in Gabbard’s Treatments of Psychiatric Disorders, 4th Edition. Edited by Glen O. Gabbard.
Copyright ©2009 American Psychiatric Publishing, Inc. DOI: 10.1176/appi.books.9781585622986.257453. Printed
5/10/2009 from www.psychiatryonline.com
Gabbard’s Treatments of Psychiatric Disorders > Part V. Mood Disorders >
Chapter 27. Convulsive and Other Somatic Therapies
INTRODUCTION
Nonpharmacological somatic therapies are among the oldest and the newest biological therapies in
psychiatry. Convulsive therapy dates back to the very beginnings of modern biological psychiatry.
Electroconvulsive therapy (ECT) now approaches its 70th anniversary, and older forms of
chemically induced convulsive therapy date back even further. Novel somatic therapies are being
developed to noninvasively stimulate the brain using electrical or magnetic fields applied through
the scalp (e.g., transcranial magnetic stimulation [TMS], magnetic seizure therapy [MST], and
transcranial direct current stimulation [tDCS]) via stimulation of the vagus nerve (i.e., vagus nerve
stimulation [VNS]), or via electrodes implanted directly into the brain (e.g., deep brain stimulation
[DBS]).
This chapter reviews the state of the art of convulsive and other somatic therapies for mood
disorders, of which only ECT and VNS are approved by the U.S. Food and Drug Administration (FDA)
for the treatment of mood disorders, although TMS is approved in other countries. Information on
evolving somatic therapies illustrates new horizons in potential therapies for mood disorders. These
approaches include TMS, MST, tDCS, and DBS for mood disorders, which are investigational and
off-label in the United States at the time of this writing (Table 27–1).
Table 27–1. Comparison of somatic therapies
Seizure
induction
Type of
stimulation
FDA approved for
depression
Unique aspects
ECT Yes Electrical Yes Unmatched efficacy
Significant side effects
Newer delivery methods resulting in
improve efficacy and tolerability
VNS No Electrical Yes (as adjunctive
treatment in adults)
Long-term treatment (not an acute
treatment)
rTMS No Magnetic Not at the time of this
writing
Noninvasive, focal treatment
Minimal side effects, no anesthesia
MST Yes Magnetic No Potential to retain therapeutic efficacy of
ECT
Focal stimulation
Fewer cognitive side effects than ECT
DBS No Electrical No Circuitry targeted precisely
Deeper brain structures reached than
with magnetic fields or focal ECT
tDCS No Electrical No Noninvasive, portable, and inexpensive
treatment
Few side effects
Note. FDA = U.S. Food and Drug Administration; ECT = electroconvulsive therapy; VNS = vagus nerve
stimulation; rTMS = repetitive transcranial magnetic stimulation; MST = magnetic seizure therapy; DBS =Print: Chapter 27. Convulsive and Other Somatic Therapies http://www.psychiatryonline.com/popup.aspx?aID=257457&print=yes…
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deep brain stimulation; tDCS = transcranial direct current stimulation (i.e., direct current polarization).
ELECTROCONVULSIVE THERAPY
ECT, the use of electrically induced seizures for therapeutic purposes, has remained the most
effective antidepressant treatment through its progressive evolution over the past 70 years. In
1938, chemical induction methods were superseded by the safer and more reliable electrical
induction, and the introduction of general anesthesia in the late 1950s reduced morbidity.
Additional technical innovations over the past 30 years have improved ECT administration in
regards to efficacy and side effects.
This section focuses on the use of ECT for mood disorders in contemporary practice. More detailed
information on ECT and on its use in other disorders is available (Abrams 1997; American
Psychiatric Association 2001; Beyer et al. 1998). The American Psychiatric Association (APA) work
provides comprehensive clinical recommendations covering all aspects of ECT, including training
and privileging.
Current Status of ECT
ECT has been shown to be a safe, effective, and at times even lifesaving treatment for severe
psychiatric disorders, including major depression with and without psychotic features, mania,
schizophrenia and schizoaffective disorder, catatonic states, and neuroleptic malignant syndrome
(American Psychiatric Association 2001; Daly et al. 2001; George 2002; George et al. 2002;
Ghaziuddin et al. 2002; Lisanby et al. 2000a, 2003b; Greenhalgh et al. 2005; Sackeim 1986;
Sackeim and Rush 1995). For many patients without adequate response or tolerance to currently
available pharmacotherapy, ECT has proven effective (UK ECT Review Group 2003). About 1–2
million individuals receive ECT each year worldwide, with utilization increasing.
ECT remains the only FDA-approved monotherapy for medication-resistant depression. The value of
ECT has been endorsed by numerous professional societies and other groups, including the APA
(American Psychiatric Association 2001), the National Institutes of Health and Mental Health
(Consensus Conference 1985), and the U.S. Surgeon General (U.S. Department of Health and
Human Services 1999). Over the last several decades, a series of scientific advances in ECT
methodology were made. These advances have made modern ECT a state-of-the-art medical
procedure in which both efficacy and safety can be optimized.
Indications
A referral for ECT can be made on a primary basis for any of the following reasons: 1) an urgent
need (either psychiatrically or medically) for a rapid response (see Case 1, later in chapter), 2)
treatment alternatives associated with a higher risk than ECT (see Case 2, later in chapter), 3) a
history of preferential response to ECT, or 4) patient preference for ECT (American Psychiatric
Association 2001). Most patients, however, are referred for ECT on a secondary basis as a result of
1) lack of adequate response or demonstrated intolerance to treatment alternatives or 2)
deterioration of the patient’s condition to the point at which criteria for primary use are met. The
determination of lack of adequate response (i.e., treatment resistance) is best made individually,
taking into account symptom severity, functional impairment, risks, and patient attitudes, in
addition to the number, duration, type, and dosage of prior medication trials (American Psychiatric
Association 2001).
ECT for Children and Adolescents
ECT is rarely used in children and uncommonly used in adolescents. In such patients, ECT is only
used when medication resistance has been clearly established (Kellner and Bourgon 1998;
Greenhalgh et al. 2005; Petrides et al. 1994; Rey and Walter 1997). Although ECT has been
successfully used in young people for treatment-resistant depression (Rey and Walter 1997; Walter
and Rey 2003; Walter et al. 1999a, 1999b), intractable mania (Carr et al. 1983; Russell et al. 2002),
catatonia (Cizadlo and Wheaton 1995; Ghaziuddin et al. 2002; Slooter et al. 2005), schizophrenia
(Bender 1947), and neuroleptic malignant syndrome (Chungh et al. 2005; Ghaziuddin et al. 2002), Print: Chapter 27. Convulsive and Other Somatic Therapies http://www.psychiatryonline.com/popup.aspx?aID=257457&print=yes…
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there is a marked paucity of published data on ECT in youth. Most reports are single cases, and
there are no controlled trials (Segal et al. 2004). However, the systematic review of several
randomized trials of ECT that included both children and adults found that ECT is no less effective in
children and adolescents than in other age groups (Morales et al. 2005).
The infrequent use of ECT in youth may be due to several factors, including reluctance to use more
invasive treatments in youths, concern about potential for adverse cerebral effects while the brain
is still developing (although no clinical data support this contention), and, in some states,
regulations preventing use of ECT in patients below a certain age (e.g., age 16 years in Texas).
Fully informed consent may also be problematic. Practitioners should be aware of pertinent local
regulations governing the age of consent for medical procedures. The APA Committee on ECT
(American Psychiatric Association 2001) calls for a second opinion from a psychiatrist not
otherwise involved in the case, who is experienced in treating children or adolescents (one for
patients ages 13–17 years and two for patients age 12 years and under). Guidelines for the use of
ECT in adolescents have been proposed by the American Academy of Child and Adolescent
Psychiatry (Ghaziuddin et al. 2004a, 2004b).
ECT in Treatment of the Elderly
No one is “too old” for ECT. Risks associated with ECT increase with age, largely because of medical
comorbidity, but they also do so for all viable treatment alternatives, possibly at a higher rate
(Coffey and Kellner 2000; Sackeim 1998). ECT appears to be associated with a lower mortality rate
than otherwise treated elderly patients with severe depressive illness (Philibert et al. 1995). Given
the prevailing risk–benefit considerations and the substantial functional impairment due to
depression in late life, it is not surprising that elderly patients account for a greater fraction of
overall ECT use than they did in the past (34% in 1986 vs. 24% in 1980) (Thompson et al. 1994).
Advanced age does have certain implications regarding ECT technique, since the pharmacological
agents used with the procedure are subject to age-dependent changes in tolerance and metabolism,
and because seizure threshold rises with age.
Evidence for Acute-Phase Efficacy in Major Depression
ECT is the most rapid and effective treatment available for major depressive episodes. The evidence
includes a sizable number of well-controlled “sham-ECT” studies. A meta-analysis, for example
(Janicak et al. 1985), found that ECT was 20% more likely to induce a remission than were tricyclic
antidepressants (P < 0.001), a potent class of antidepressant medications. ECT has been associated
with a remission rate of 80%–90%, with maximum response typically attained after 2–4 weeks, but
the remission rate with ECT varies as a function of certain prognostic factors (see below).
Unfortunately, there have not yet been adequate comparisons between ECT and newer
antidepressant agents or, more importantly, combination treatments.
ECT is as effective in severe nonmelancholic episodes as it is in episodes characterized by
melancholic features (Sackeim and Rush 1995). Similarly, efficacy appears to be equivalent in
depressed patients with unipolar and bipolar mood disorders, though bipolar patients may show a
more rapid response (Daly et al. 2001). Psychotic depression, particularly with mood-congruent
delusions, is associated with an increased likelihood of success of ECT, compared with nonpsychotic
depression (Petrides et al. 1994; Sobin et al. 1996). Primary depressive episodes are more likely to
show full improvement with ECT than are those that are comorbid with dysthymia, anxiety
disorders, and borderline personality disorder (Prudic et al. 2004; Zorumski et al. 1986). In
addition, patients with medication-resistant depression have a lower remission rate with ECT
(Dombrovski et al. 2005; Prudic et al. 1996). Whether this effect is due to more
treatment-refractory cases or to longer depressive episodes in this patient group is unclear.
Unfortunately, such individuals are also less likely to respond to antidepressant interventions of
any type. For this reason, ECT may still be the most effective treatment in at least some such cases.
Evidence for Continuation/Maintenance–Phase Efficacy
For nearly all patients responding to ECT for depression, continuation/maintenance (C/M) therapyPrint: Chapter 27. Convulsive and Other Somatic Therapies http://www.psychiatryonline.com/popup.aspx?aID=257457&print=yes…
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is necessary. C/M therapy usually consists of antidepressant medications, typically continued for at
least 1 year. However, continuation pharmacotherapy may be less effective in patients whose ECT
indication was medication resistance (Sackeim 1994; Sackeim et al. 1990). For these patients,
pharmacotherapy may be combined with C/M ECT (American Psychiatric Association 2001; Petrides
et al. 1994; Rabheru and Persad 1997; Sackeim 1994). Most experts believe that existing data
support the use of C/M ECT when medication refractoriness or intolerance is present in C/M
antidepressant medication trials. However, C/M ECT may still be underutilized.
Specific indications for continuation ECT are 1) history of recurrent episodes responsive to ECT and
either 2) ineffectiveness of or intolerance to prophylactic pharmacotherapy or 3) patient preference
(American Psychiatric Association 2001). In some cases, patients will receive fewer total ECT
treatments had they not received continuation ECT (i.e., these patients thus have fewer relapses,
which often require an entire new course of ECT). Long-term use of C/M ECT is indicated either
when the patient’s history suggests a high risk of delayed relapse on medication alone or when
evidence of decompensation occurs during attempts to stretch out the interval between treatments
during the continuation phase. Average duration of continuation ECT has been reported at 10 weeks
(Petrides et al. 1994) to 6 months (Andrade and Kurinji 2002).
A recently completed randomized study contrasting the utility of continuation ECT alone (no
medications) versus a combination of nortriptyline and lithium failed to find a difference between
the groups (Kellner et al. 2006). However, it can be argued that the ECT arm was weakened by
giving only 10 treatments in 6 months and not allowing any medications. Routine clinical practice
would involve treatment with medications and continuation ECT in combination.
Contraindications and High-Risk Situations
There are no “absolute” contraindications for ECT. The decision to give any treatment is based on
an assessment of risks and benefits among the available treatment options. However, situations do
exist in which the risk of ECT is sufficiently high that its indications should be extremely strong
before considering ECT (American Psychiatric Association 2001).
The presence of a space-occupying intracerebral lesion has traditionally been considered to be just
such a situation, since ECT increases intracerebral pressure. However, recent reports have indicated
that slow-growing meningiomas without mass effect, as well as similar lesions of other types, do
not present a high risk for ECT (Krystal and Coffey 1997) or the risk can be diminished
pharmacologically (Patkar et al. 2000). Recent myocardial infarction may markedly raise risk levels,
due to the effects of ECT on the sympathetic and parasympathetic nervous system (see “Side
Effects,” below). However, the extent of the lesion, degree of healing, and current cardiovascular
status contribute to the specific level of risk that applies in any given case. Other examples of
high-risk conditions are unstable angina, poorly compensated congestive heart failure, severe
valvular cardiac disease, bleeding (or otherwise unstable) vascular aneurysm or malformation,
recent cerebral infarction, severe pulmonary dysfunction, or additional causes of high anesthetic
risk. In many such cases, however, risk levels can be substantially diminished by pharmacologically
altering the body’s physiological response to the induced seizure (American Psychiatric Association
2001; Weiner 2000). ECT has also been safely administered to patients with a history of brain
surgery, deep brain stimulators, cardiac pacemakers, automatic implanted defibrillators, and vagus
nerve stimulators. Appropriate subspecialty consultation is recommended in such situations.
Side Effects
Mortality
The risk of death with ECT is very low: approximately 1 per 10,000 patients (Abrams 2002;
American Psychiatric Association 2001), comparable to the rate expected from a series of brief
anesthetic procedures alone. Most deaths occur in the above-noted high-risk cases. The most
common cause of death with ECT is cardiovascular decompensation; other causes include prolonged
apnea, status epilepticus, and cerebral herniation (e.g., in unrecognized cases of brain tumor).Print: Chapter 27. Convulsive and Other Somatic Therapies http://www.psychiatryonline.com/popup.aspx?aID=257457&print=yes…
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Systemic Morbidity
The systemic morbidity associated with ECT is related to the physiological effects of induced
seizures in a setting of general anesthesia and muscular paralysis. Both sympathetic and
parasympathetic discharges typically produce transient benign disturbances in cardiac rate and
rhythm and in blood pressure. These changes can be associated with arrhythmias or cardiac
ischemia, although significant sequelae are rare (Weiner 2000). Such cardiovascular complications
are most likely in patients with severely compromised comorbid cardiac disease. Pharmacological
prophylaxis may be indicated (American Psychiatric Association 2001; Zielinski et al. 1993).
Although prolonged apnea and status epilepticus are rare events, resources to manage their
occurrence should be available. Bone fractures and other musculoskeletal injuries are prevented by
muscular paralysis, whereas injuries to teeth or soft tissues of the mouth are minimized by an oral
protective device (bite block). More common, usually mild systemic side effects include headache,
muscle pain, and nausea (American Psychiatric Association 2001).
Cognitive and Cerebral Morbidity
Cognitive dysfunction
Amnesia is the most commonly discussed side effect of ECT (American Psychiatric Association
2001; Sackeim 1992; Squire 1986). Memory difficulties increase over an index course of treatments
and diminish once ECT is stopped. Less often, memory function may actually improve following ECT,
especially when depression-related cognitive deficits or frank pseudodementia is present. Amnesic
effects with ECT are more prominent and last longer in patients with preexisting cerebral disease,
larger numbers of treatments in a course, or bilateral stimulus electrode placement, particularly
when treatment frequency is maintained at three times weekly.
Two types of memory deficits occur with ECT. More prominent is retrograde amnesia (i.e., difficulty
in remembering information learned before the ECT course). This deficit is greatest for more recent
memories, particularly those occurring within months before the ECT. Retrograde amnesia seems to
be more marked for information of an impersonal nature (Lisanby et al. 2000b). Objective testing
has revealed that these losses diminish over the weeks to months following ECT, except for some
recent memories—particularly those during the ECT treatment period and the preceding months
(American Psychiatric Association 2001; McElhiney et al. 1995). The proportion of patients with
persistent retrograde amnesia using objective testing following ECT is unknown; patient surveys
suggest that this may occur in a sizable minority (Sackeim 1992).
ECT can also induce anterograde amnesia (i.e., difficulty retaining newly learned information), most
severe during the ECT course and typically resolving in days to weeks following ECT
discontinuation.
The likelihood, severity, and persistence of ECT-induced amnesia are influenced by how ECT is
administered, particularly electrode placement and dosing (American Psychiatric Association 2001;
Sackeim et al. 1993, 2000; Sobin et al. 1995; Squire 1986). Severe amnesia during the ECT course
can be managed by increasing the interval between treatments (from three per week to two per
week or even one per week), changing ECT type (e.g., bilateral to unilateral electrode placement),
or, if necessary, ending the treatment course. Pharmacological attempts to ameliorate ECT-induced
amnesia (e.g., by using nootropics, hormones, stimulants, and peptides) have not been reliably
demonstrated (Krueger et al. 1992).
Complaints of more extensive or severe, long-lasting memory deficits have been reported by
patients (American Psychiatric Association 2001; Sackeim 1992). The incidence of these deficits,
while not precisely known, appears to be much lower than the more typical effects described above.
The etiology of these complaints is unclear. Many of these patients perform normally on objective
memory testing (although retrospectively testing for retrograde amnesia is difficult). These
complaints may involve nonphysiological characteristics (e.g., retrograde amnesia without a
temporal gradient) or other etiological factors (e.g., medication effects). Yet psychological factorsPrint: Chapter 27. Convulsive and Other Somatic Therapies http://www.psychiatryonline.com/popup.aspx?aID=257457&print=yes…
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may also play a role (e.g., an increased sensitivity to normal forgetting following a transient
organic amnesic effect, the development of conversion-type syndromes, or secondary gain).
Delirium
A period of postictal confusion, from 10 minutes to more than 1 hour after the seizure, is common.
The occurrence of interictal delirium, however, is far less common and seems most likely in patients
with preexisting cerebral impairment (e.g., Parkinson’s disease) (Krystal and Coffey 1997).
Structural brain changes
Metabolic, neurochemical, and neuropathological evidence indicates that structural brain changes
do not occur with electrically and chemically induced seizures (Coffey et al. 1991; Devanand et al.
1994). Prospective long-term follow-up studies with brain magnetic resonance imaging in humans
have confirmed these findings. Furthermore, there has been no evidence for neuropathological
damage following chronic treatment with bilateral ECT in monkeys (Dwork et al. 2004).
Electroconvulsive Therapy Technique
Informed Consent Process
Informed consent is provided by the patient or by an individual designated under state law (usually
a family member) for patients who are incapable of informed consent. All consent procedures
should follow applicable state regulations (which vary considerably). Consent is an ongoing
process, which can be revoked at any time. Although the consent form covers the entire series of
ECT treatments (except in certain states), it is recommended that reconsent be obtained if an index
series is unusually prolonged. Because C/M ECT differs in a number of ways from an index course of
treatments, it is useful to have a separate consent form for such purposes. Specific information that
should be provided in the consent is provided in the American Psychiatric Association Committee on
ECT 2000 report (American Psychiatric Association 2001).
Lay information on ECT, in both written materials and videotapes, can be obtained from the APA
(i.e., “Fact Sheet” on ECT) and from ECT device manufacturers. Several books oriented to the
general public are available (Endler 1990; Fink 1999). Any major discrepancies between local
regulations and publicly obtained information should be pointed out to the consentee.
Pre-ECT Psychiatric and Medical Workup
Individuals privileged to administer ECT at the facility should evaluate patients before initiating
treatment (American Psychiatric Association 2001). The history and examination should 1)
delineate the indication for ECT; 2) address the nature and effects of prior treatments, including
ECT; 3) assess risk factors based on a medical, anesthetic, and dental history and address how
applicable risks might be reduced; and 4) make recommendations for any further pre-ECT
consultations or laboratory studies (many practitioners routinely screen patients with a complete
blood count, serum potassium and sodium levels, an electrocardiogram, and a pregnancy test for
women of child-bearing potential) or any changes in the patient’s management that are indicated
before or during ECT, including alterations in type and dosage of both psychotropic and medical
pharmacological agents. Furthermore, a preoperative anesthetic assessment by an anesthesia
provider to further clarify risk and to determine whether and how such risks could be minimized,
particularly in terms of modifications of the anesthetic procedure, should be conducted.
Management of Medications Before and During ECT Course
A plan to manage patients’ medication regimens (both psychotropics and other agents) is called for,
including which medications to discontinue and which to be taken before or held until after
treatment on ECT days. Medications that are medically essential or have a protective effect in
regard to ECT (e.g., most cardiac agents and antireflux preparations) should be administered before
ECT on treatment days, keeping fluid intake to a minimum. In general, agents that have a
potentially deleterious effect—either diminishing efficacy of ECT or increasing risk—should bePrint: Chapter 27. Convulsive and Other Somatic Therapies http://www.psychiatryonline.com/popup.aspx?aID=257457&print=yes…
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discontinued or substituted by another agent whenever possible; at the least, dosages should be
decreased to the minimum necessary. Examples of medications that may interfere with the efficacy
and safety of ECT include theophylline, lithium, benzodiazepines, and anticonvulsants (American
Psychiatric Association 2001). Whether ECT increases the risk of cerebral toxicity from lithium is
debated (American Psychiatric Association 2001; Mukherjee 1993; Small and Milstein 1990).
Holding the lithium dose for 24 hours before each ECT treatment may decrease the risk and is
standard practice at some centers. When benzodiazepines cannot be withdrawn, held, or reduced,
the antagonist flumazenil can be used to reverse their anticonvulsant effect during ECT (Krystal et
- 1998). In such cases, a parenteral benzodiazepine (e.g., intravenous midazolam) should be
administered immediately after the seizure to avoid withdrawal symptoms. Antipsychotic
medication should be continued during ECT in patients with psychosis, particularly those with
schizophrenia or schizoaffective disorder, as the two treatment types may have synergistic action.
Currently, the augmentation of ECT with antidepressant medications is widespread, but only
preliminary data directly address this practice (American Psychiatric Association 2001; Lauritzen et
- 1996).
ECT in Patients With General Medical Illness
Patients receiving ECT often have concomitant general medical conditions, many of which raise
specific concerns when ECT is used (American Psychiatric Association 2001; Weiner 2000). Patients
with hypertension should have blood pressure stabilized before ECT and receive their routine
antihypertensive medication(s) before each treatment. Patients with coronary artery disease
should also receive their antianginal agents before ECT, and consideration should be given to the
use of acute sympatholytics when ECT is delivered to avoid peri-ECT angina. Cardiac pacemakers
reduce the cardiac risk of pathological arrhythmias with ECT, as do implanted cardiac defibrillators.
However, cardiologist consultation before ECT is still recommended for these individuals. Similarly,
patients who have diabetes mellitus or asthma and those who are pregnant require special
management (Miller 1994; Wisner 1988).
Staffing and Location of ECT Treatments
The provision of ECT requires highly trained and experienced staff. The anesthesia provider also
maintains the patient’s airway and handles medical emergencies (American Psychiatric Association
2001). Separate treatment and recovery areas should be provided whenever possible. Constraints
on clinical practice have increased the pressure to provide ECT on an outpatient basis, but this
should only be done in cases where the patient does not require hospitalization and can comply
with the treatment regimen (American Psychiatric Association 2001; Fink et al. 1996). Such
patients should be briefly evaluated before each treatment and not discharged until he or she is
capable of leaving with the assistance of a significant other.
Number and Frequency of Treatments
The number of ECT treatments administered in an index course is based on clinical progress (see
“Continuation/Maintenance Therapy” section for treatment number and frequency with that
modality). Typically, patients require 6–12 treatments in an index course, although as few as 3 or
greater than 20 may be required. As noted, reconsent should be considered when an unusually long
course is required (American Psychiatric Association 2001). There does not appear to be any
benefit in continuing ECT once a therapeutic plateau (i.e., no further improvement) is reached. In
cases of partial improvement, consideration should be given to optimize technique (see
“Management of Missed, Inadequate, or Prolonged Seizures,” later in chapter). There is no “lifetime
maximum” number of treatments.
In the United States, ECT is usually administered three times a week (American Psychiatric
Association 2001). Some recent studies indicate that administration of twice-weekly bilateral ECT
treatments (as performed elsewhere) results in a therapeutic response similar to that with
thrice-weekly treatments but with fewer short-term cognitive side effects, although response rate
is slower (Shapira et al. 1998). Patients with an urgent need for rapid response may be treatedPrint: Chapter 27. Convulsive and Other Somatic Therapies http://www.psychiatryonline.com/popup.aspx?aID=257457&print=yes…
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daily for the first few treatments, whereas patients who develop delirium or severe cognitive
deficits may require a reduction in treatment frequency. Multiple monitored ECT (induction of
multiple seizures in a single treatment session [Maletzky 1981]) increases risks of cognitive
deficits, prolonged seizures, and exaggerated cardiovascular response (Abrams 1997). It is no
longer within the standard of practice, with the exception of double-seizure induction for dosage
titration (see “Stimulus Dosing,” later in chapter) at the initial ECT treatment.
Anesthetic Issues
Anticholinergic Agents
Anticholinergic agents are used to minimize oropharyngeal secretions and the risk of posttreatment
asystole or bradycardia. Glycopyrrolate is the agent preferred by many practitioners because it is
less likely to cross the blood-brain barrier and thus potentially exacerbate cognitive side effects.
Anticholinergic premedication is most important for cardiac patients and with use of subconvulsive
stimulations (American Psychiatric Association 2001).
Sympatholytic Agents
The transient surge in systolic pressure and heart rate following seizure onset is of concern in
patients at risk for cardiac ischemia. The effect can be attenuated, but hypotension should be
avoided. Careful agent selection includes consideration of duration of action and anticonvulsant
effects.
Ventilation
The airway should be ensured and oxygen ventilation begun before infusion of muscle relaxant and
anesthetic, and ventilation should be continued until the patient resumes spontaneous breathing
(except during electrical stimulus delivery) (American Psychiatric Association 2001). A flexible
mouth guard protects the patient from the involuntary muscle contractions that accompany the
electrical stimulus.
Anesthesia
A light level of anesthesia is used to provide amnesia for the effects of the muscular paralysis and
the electrical stimulation with minimal interference with seizure induction. The primary agent used
in the U.S. is methohexital, a rapidly acting barbiturate with a short half-life (American Psychiatric
Association 2001; Swartz 1993). Propofol has been avoided because of its even greater
anticonvulsant properties (Swartz 1992), although this effect has not been associated with
diminished efficacy (Martensson et al. 1994). Ketamine, which does not raise seizure threshold, is
an alternative agent for patients with very high seizure thresholds (Rasmussen et al. 1996), as is
etomidate, which can lengthen seizures (Avramov et al. 1995; Gazdag et al. 2004).
Muscular Relaxation and Physiological Monitoring
Because of its rapid action and extremely short half-life, succinylcholine is the muscle relaxant of
choice for ECT. Alternative agents include the muscarinic antagonists, which are associated with a
longer period of apnea. Current monitoring includes respiration, carbon dioxide, blood oxygen
saturation, blood pressure, and heart rate from before anesthesia induction until the time the
patient leaves the treatment room.
Stimulus Electrode Placement
For many years, ECT stimulus electrodes were applied bitemporally—so-called bilateral (BL) ECT.
Nondominant (and hence generally right) unilateral (RUL) ECT places both electrodes over the
nondominant cerebral hemisphere, thereby relatively sparing verbal memory function (Lancaster et
- 1958).
Dozens of additional investigations comparing the efficacy and safety of various forms of RUL
versus more traditional BL ECT (reviewed in Abrams 2002) have demonstrated 1) less frequent,Print: Chapter 27. Convulsive and Other Somatic Therapies http://www.psychiatryonline.com/popup.aspx?aID=257457&print=yes…
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severe, and persistent memory impairment, particularly in regard to left-hemisphere function, with
RUL ECT; and 2) a more rapid or pronounced antidepressant effect with BL ECT. RUL ECT
administered using a frontotemporal to high-centroparietal configuration (d’Elia 1970) in
combination with a significantly suprathreshold stimulus intensity (see “Stimulus Dosing,” below)
improves efficacy, although it is not necessarily equivalent to BL ECT (McCall et al. 2000; Sackeim
et al. 1993, 2000). The increases in RUL ECT stimulus intensity are associated with increased
amnesia, although less than is seen with BL ECT. Bifrontal electrode placement has also shown
evidence of improved cognitive outcome relative to BL. However, more evidence is needed
comparing bifrontal ECT with suprathreshold RUL ECT (Bailine et al. 2000; Ranjkesh et al. 2005).
Thus, electrode placement and stimulus intensity are made on a case-by-case analysis of
anticipated benefits versus likely risks (American Psychiatric Association 2001).
Electrical Stimulus
Electrical Principles Pertinent to ECT
The electrical stimulus is applied once maximal muscular paralysis has been attained and good
electrical continuity (i.e., low interelectrode impedance) is established. Contemporary ECT devices
made in the U.S. allow monitoring of this electrical continuity.
At present, ECT devices are produced by two companies in the U.S.: MECTA, Inc. (Lake Oswego,
OR), and Somatics, Inc. (Lake Bluff, IL). In both cases, the signal used for the ECT stimulus is the
bidirectional brief pulse. Sine wave stimuli delivered by older devices are no longer recommended.
Brief pulse ECT is characterized by pulse width (e.g., 0.25–2.0 msec), pulse frequency (e.g., 40–90
Hz, or pulse pairs per second), duration of the entire train of pulses (e.g., 0.5–8.0 seconds), and the
peak current of each pulse (e.g., 0.5–1.0 amp). The use of very narrow pulses (e.g., 0.25–0.5 msec)
is termed ultra-brief pulse ECT and may offer a further potential for stimulus optimization. A single
composite stimulus intensity parameter is the charge (in millicoulombs).
Stimulus Dosing
The seizure threshold is the minimum stimulus intensity required to induce a generalized seizure. It
varies as much as 50-fold across patients. Seizure threshold is higher in men and in older persons,
and it increases with more ECT treatments. Seizure threshold is lower with RUL d’Elia placement
(American Psychiatric Association 2001; Sackeim et al. 1991). Also for RUL ECT, efficacy increases
as a function of how much the stimulus intensity exceeds the seizure threshold. RUL ECT at 500%
above threshold approaches the efficacy of BL ECT (Sackeim et al. 1993, 2000).
Based on these relationships, the most precise method for stimulus dosing is to determine the
seizure threshold with a titration procedure at the first treatment and to then administer a stimulus
at a chosen degree above threshold subsequently. Various dosing schedules have been suggested
to individualize ECT delivery (Coffey et al. 1995). Fixed formula dosing techniques are available, but
less accurate (American Psychiatric Association 2001).
Seizure Monitoring
Monitoring of Motor Response
Visual seizure monitoring of the motor convulsive response (Weiner et al. 1991) has been used to
detect the presence and duration of the motor convulsive response. A blood pressure cuff inflated
to above the systolic pressure and placed on the hand or foot before infusion of the paralytic agent
is used. When RUL ECT is given, cuffing the right ankle is recommended to help ensure that the
seizure is bilateral.
Monitoring of Electroencephalographic Response
ECT-induced seizures involve the intense and highly synchronous discharge of neurons throughout
the cerebral hemispheres, which are best monitored by scalp-recorded electroencephalography
(EEG) (American Psychiatric Association 2001; Weiner et al. 1991). The EEG seizure typically lastsPrint: Chapter 27. Convulsive and Other Somatic Therapies http://www.psychiatryonline.com/popup.aspx?aID=257457&print=yes…
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10–15 seconds longer than the ictal motor response. In some individuals, prolonged EEG seizures
occur that are not detected by motor response monitoring. Therefore, single- or double-channel EEG
monitoring is recommended. Double-channel monitoring (available on most U.S. ECT devices) is
recommended to observe seizure symmetry and to provide backup when substantial EEG artifacts
occur. The EEG seizure typically begins by the end of the stimulus. The tonic portion of the ictal
motor response is usually characterized by a polyspike format, whereas the clonic portion shows a
polyspike–slow-wave pattern. The end of the seizure may be abrupt or gradual, and the immediate
postictal EEG is suppressed and may appear “flat” (Krystal et al. 1993; Nobler et al. 1993).
Determination of Seizure Adequacy
Historically, seizure duration was assumed to be the primary measure of seizure adequacy, with a
typical clinical cutoff criterion of 25 seconds (Weiner et al. 1991). However, work by Sackeim et al.
1993) showed that for RUL ECT, seizure duration did not ensure the therapeutic efficacy of ECT as
well as increase in stimulus intensity. Alternative EEG-based measures sensitive to the extent to
which the stimulus is suprathreshold would better guide the determination of the lowest effective
stimulus intensity to maximize efficacy while keeping side effects to a minimum (Krystal et al.
1998). Some studies suggest that amplitude and regularity of ictal EEG slow waves and the degree
of postictal EEG suppression have promise in this regard (Krystal et al. 1998). However, no
EEG-based models have yet been validated for use in clinical dosing.
Management of Missed, Inadequate, or Prolonged Seizures
Missed seizures lack therapeutic effects. They should be followed by increasing the stimulus
intensity (e.g., 50%) after an interval of approximately 20 seconds (to rule out delayed ictal
response). Brief (abortive) or otherwise inadequate seizures should be followed by restimulation at
a higher stimulus intensity after 45 seconds to allow the relative refractory period to pass. If the
patient’s seizure threshold exceeds the capability of the ECT device, the threshold can be decreased
by lowering the dose of anesthetic agent (if possible), by switching to etomidate or ketamine
for anesthesia, or by stopping/decreasing concurrent medications with anticonvulsant properties
(American Psychiatric Association 2001). Prolonged seizures (i.e., lasting longer than 3 minutes)
should be terminated pharmacologically (American Psychiatric Association 2001). Poorly
suppressed postictal EEG or inappropriately high EEG amplification can be misinterpreted as a
prolonged seizure.
Continuation/Maintenance Therapy
Maintenance Pharmacotherapy
Most individuals who receive ECT have a chronic or recurrent prior course of illness that puts them
at risk for recurrence—particularly during the first 6 months after remission (American Psychiatric
Association 2001). The 1-year recurrence rate following ECT is 50% despite medications (Sackeim
1994; Sackeim et al. 1990). Thus, continuation therapy is essential (American Psychiatric
Association 2001). For most cases, psychotropic medications are used. However, patients with a
history of medication resistance during the index episode are less likely to maintain remission on
continuation pharmacotherapy than nonresistant patients (Sackeim et al. 1990). For
medication-resistant patients who respond to ECT, consider giving the patient either a class of
medication not previously used or continuation ECT (American Psychiatric Association 2001;
Sackeim 1994).
Continuation ECT
When continuation-phase medications do not maintain remission, C/M ECT should be considered.
Continuation ECT following successful ECT typically involves gradually shifting from frequent (e.g.,
weekly) to monthly treatments over 1–3 months and then maintaining the monthly administration
schedule for at least 6 months after remission (or longer if indicated) (American Psychiatric
Association 2001; Fink et al. 1996). Decisions regarding scheduling should be made on an ongoing
basis, based on the patient’s history and present response. Concomitant psychotropic agents mayPrint: Chapter 27. Convulsive and Other Somatic Therapies http://www.psychiatryonline.com/popup.aspx?aID=257457&print=yes…
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be useful for patients who are unable to benefit fully with continuation C/M ECT alone. Although
C/M ECT may slow the resolution of the index ECT course–associated memory disturbance, the
development or worsening of memory impairment is thought to be unlikely unless there is
prolonged use of short-interval C/M ECT (weekly or bimonthly), though some patients tolerate it
well. The need for C/M ECT should be reviewed by the practitioner and patient at least twice a year;
consent should be reobtained at least every 6 months, as should anesthetic/medical and cognitive
reevaluations. The presence of persistent memory deficits should be weighed against the
anticipated benefits of continuing ECT.
Case Examples
Case 1
Mr. B, a 72-year-old right-handed man, was being treated for a major depressive episode. He was
transferred from the inpatient service of a freestanding psychiatric hospital because of serious medical
comorbidity (severe coronary artery disease) and deterioration in his overall condition. Mr. B had been
well until 3 months before admission. At the time of his transfer, his psychiatric presentation was
characterized by intense dysphoria, inability or unwillingness to answer questions, severe motor
retardation, a belief that he had committed terrible deeds and should be punished, and refusal to eat.
Although he had been hospitalized in the initial facility for a week, antidepressant medications had not
been initiated because of the staff’s concern about his medical condition. Medically, Mr. B’s coronary
artery disease was characterized by angina on exertion, requiring daily antianginal medication, and a
cardiac ejection fraction of 30% (indicating a severe level of dysfunction). The preliminary diagnosis was
major depression with psychotic features.
Because of the gravity of Mr. B’s presentation, a referral for ECT on a primary basis was indicated.
Although a cardiology consultation corroborated the level of cardiac dysfunction, the consultant also
agreed that Mr. B’s mental condition represented an even greater risk than proceeding with ECT. Mr. B
was not able to follow a discussion on ECT by the attending psychiatrist and indicated that he did not
want treatment or food because he deserved to die. Because he did not have the capacity for providing
informed consent, a guardianship procedure was begun and his son was adjudicated the appointed
guardian and provided surrogate consent.
Mr. B received his routine oral antianginal agent 2 hours before ECT and was further premedicated with
intravenous labetalol 5 mg, given 2 minutes before anesthesia induction. Because of the urgent need for
a rapid response, he was administered BL ECT at a rate of three treatments per week. Mr. B tolerated the
procedure well, except for some transient premature ventricular contractions lasting 2 minutes
postictally. These contractions were prevented in successive treatments by an increase in the labetalol
dose. After three treatments, a clear improvement in his symptoms was noted, along with some
confusion occurring between treatments. Decreasing the rate of treatments to two per week allowed
continued improvement with only mild levels of confusion and amnesia. After six treatments Mr. B was
back to his premorbid state. His son described the patient’s response as “being brought back from the
dead.” Mr. B was given nortriptyline on discharge from the hospital. He remained well at 1-year
follow-up.
Case 2
Ms. C was a 58-year-old right-handed woman with a long history of recurrent major depression. After
numerous unsuccessful trials of various antidepressant medications, both alone and in combination, her
prior 3 episodes had led to referrals for BL ECT. These courses of treatment were associated with a
marked improvement and were well tolerated except that she experienced moderate transient memory
impairment. After each course of ECT, the last of which ended 5 months previously, she was given
continuation pharmacotherapy, with only transient benefit. No medical risks were present on pre-ECT
evaluation during the last 3 episodes.
Because of her recent history of good response, except for memory disturbance with prior ECT, Ms. C was
referred for a course of RUL ECT treatments to reduce the risk of cumulative cognitive morbidity.Print: Chapter 27. Convulsive and Other Somatic Therapies http://www.psychiatryonline.com/popup.aspx?aID=257457&print=yes…
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However, little therapeutic response was evident after the sixth treatment, in contrast to what had been
observed during her previous BL ECT courses. Following discussion with Ms. C and her husband, she was
switched to BL ECT and began to show improvement after two further treatments. During the tenth
treatment it was noted that Ms. C’s EEG seizure duration had fallen to 22 seconds, despite the use of
maximum electrical stimulation. Beginning at the eleventh treatment, her anesthetic agent was switched
from methohexital to ketamine, leading to a 100% increase in seizure duration. Ms. C continued to
improve and reached a therapeutic plateau after 13 treatments.
Because of her history of rapid relapse, Ms. C was referred for C/M ECT, for which she provided informed
consent. Treatments were begun at the rate of one per week for 4 weeks, followed by one every 2 weeks
for an additional 4 weeks, one per 3 weeks for the next 6 weeks, and then monthly. Throughout this
period, Ms. C remained in clinical remission without adverse effects. After 12 months on C/M ECT, the
treatments were stopped, with close follow-up maintained. At her most recent visit, 18 months following
the most recent index course, Ms. C was still taking no psychotropic medications, and she continued to
be euthymic.
VAGUS NERVE STIMULATION
Vagus nerve stimulation (VNS) is FDA approved for adjunctive treatment of chronic or recurrent
medication-resistant depressive episodes in adults, and it is also approved for treatment-refractory
partial-onset seizures. VNS entails the direct, intermittent electrical stimulation of the left cervical
vagus nerve via a pulse generator implanted in the left chest wall. The electrode is wrapped around
the left vagus nerve in the neck and is connected to the generator subcutaneously. Intermittent left
VNS sends afferent signals to the nucleus tractus solitarius and connected limbic and cortical areas
(George et al. 2000). Implantation surgery involves two incisions: one in the chest for the
generator, and another in the neck for the electrode. Surgery is usually performed under brief
general anesthesia, as day surgery or with an overnight stay. Stimulation parameters are adjusted
with a programming wand that communicates with the generator. Patients may turn off the
stimulation when needed by holding a magnet over the generator.
In the first study of 30 treatment-resistant depressed patients (Rush et al. 2000), response rates
were 40% after 10 weeks of open-label, adjunctive VNS treatment. The response rate was
sustained (46%), and the remission rate significantly increased (from 17% to 29%) after an
additional 9 months of VNS treatment (Rush et al. 2005b); in addition, substantial improvements in
function were reported with long-term VNS therapy.
In a subsequent report of an extended sample (n = 59) (Sackeim et al. 2001b), the short-term (3
months) and longer-term (24 months) effects of adjunctive VNS treatment (Nahas et al. 2005)
revealed 10-week response rates of 31% (after 3 months), 44% (after 1 year), and 42% (after 2
years). Remission rates were 15%, 27%, and 22% respectively, demonstrating continuous and
stable improvement. By 2 years, 81% were still receiving VNS.
However, a 10-week randomized, controlled, masked multicenter trial comparing adjunctive VNS
with sham treatment in 235 outpatients with treatment-resistant unipolar or bipolar depression
failed to show a significant difference on the primary outcomes between active and sham treatment
(Rush et al. 2005a). However, a naturalistic follow-up study of long-term (1-year) VNS treatment of
the same cohort (n = 202) revealed progressively increasing improvement, with a 12-month
response rate of 27.2% and a remission rate of 15.8%. These results, compared with those seen in
a comparably matched but nonrandomized control group that received treatment as usual,
indicated that VNS was associated with greater improvement than pharmacological treatment alone
(27% vs. 13%) (George et al. 2005). The finding of significant longer-term benefit of adjunctive
VNS relative to active treatment excluding VNS was from an open-label study in which treatment
was not controlled. On the other hand, the improvement in VNS patients was not attributable to
medication changes, nor was a delayed placebo effect likely in such chronically ill
treatment-resistant patients.
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VNS is generally well tolerated. Voice alteration, dyspnea, and neck pain are the most frequently
reported adverse events (George et al. 2005). The surgical implantation does carry the risks of
infection, vocal cord paralysis, and bradycardia or asystole (single occurrences for all, except no
vocal cord paralysis in the randomized controlled trial [Rush et al. 2005a]). In the long-term
naturalistic study of VNS for major depression, only 3 out of 235 patients (1%) terminated VNS
because of adverse events (George et al. 2005). VNS does not cause cognitive side effects (Sackeim
et al. 2001a). In fact, neurocognitive performance was significantly improved with VNS—apparently
due to the improvement in depression (Sackeim et al. 2001a).
Indications and Contraindications for VNS
VNS is approved as an adjunctive long-term treatment for chronic or recurrent depressive episodes
in adults with a major depressive episode who have not had an adequate response to four or more
adequate antidepressant trials. Determination of what constitutes an adequate trial requires careful
assessment of whether adequate dosages were prescribed (and taken) for an adequate period of
time. Optimally, this should be substantiated by careful review of treatment records, pharmacy
reports, and blood levels where appropriate. Trials should have included different medication
classes (i.e., not just selective serotonin reuptake inhibitors or serotonin-norepinephrine reuptake
inhibitors but also tricyclic antidepressants and monoamine oxidase inhibitors) or various
augmentation strategies with or without ECT. A second opinion from a clinician specializing in
treatment-resistant depression and knowledgeable regarding VNS is advisable.
VNS is contraindicated in patients with bilateral or left cervical vagotomy, and patients with a VNS
implant should not receive short-wave diathermy, microwave diathermy, or therapeutic ultrasound
diathermy. The efficacy of VNS in other disorders is unknown.
VNS does not exert rapid antidepressant action. Acutely suicidal patients and others in need of
rapid response would be more appropriately treated with other strategies. VNS is indicated as a
long-term treatment option only for those with a chronic or recurrent course of illness.
ECT can be safely used in patients with an implant if the VNS generator is turned off during delivery
of ECT to avoid anticonvulsant effects of VNS. Whether VNS would be useful in relapse prevention
post-ECT deserves study.
VNS Dosing
The optimal dose of VNS is unknown. The published studies were not designed to identify optimal
dosing parameters (time on, time off, frequency, current, pulse width). The epilepsy literature
suggests that there is a threshold current for efficacy. However, because that threshold is unknown
for VNS, current is typically increased up to >1 milliamperes (mA) and clinical benefit assessed
over several months. The side effects of VNS are known to be dose dependent (e.g., lowering pulse
width reduces neck pain, allowing patients to tolerate higher currents).
TRANSCRANIAL MAGNETIC STIMULATION
Transcranial magnetic stimulation (TMS) provides noninvasive brain stimulation with time-varying
magnetic fields to induce electrical current and neuronal depolarization in targeted cortical regions
(Barker et al. 1985). Repetitive TMS (rTMS) pulses are delivered at 1–20 Hz. Low-frequency ( 1 Hz)
rTMS reportedly decreases neuronal excitability, while high-frequency (10–20 Hz) rTMS increases it
(Speer et al. 2000). Unlike ECT, rTMS requires neither anesthesia nor seizure induction. rTMS does
not produce disorientation or clinically apparent cognitive side effects. rTMS sessions typically last
30 minutes and are repeated daily, 5 days per week, with the length of treatment ranging from 2 to
4 weeks. The few studies of longer acute treatment for depression revealed continued improvement
over the third and fourth weeks (Rumi et al. 2005). Although optimal dosing has not been fully
examined, studies generally suggest that higher intensities, more pulses per session, and more
pulses per course are associated with superior outcome (Gershon et al. 2003).
During rTMS, patients are awake and require no anesthesia. Other than headache and scalp pain,
there are no significant common side effects; thus, outpatients return to work or otherPrint: Chapter 27. Convulsive and Other Somatic Therapies http://www.psychiatryonline.com/popup.aspx?aID=257457&print=yes…
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responsibilities immediately following each treatment session. rTMS carries a risk of seizure when
excessively high levels of stimulation are used. The intensity of the magnetic stimulus is measured
as a percentage of the motor threshold, the minimum intensity required to elicit a twitch in a target
hand muscle in 5 of 10 trials. Most treatment trials have used intensities between 80% and 120%
of the motor threshold. Careful attention to published safety guidelines regarding dosage selection
and medical monitoring is important to ensure safety (Belmaker et al. 2003; Wassermann 1998).
The FDA has labeled TMS devices “to be used by prescription only,” which means under the
direction of a physician. TMS must be given by clinically trained personnel supervised by a
physician.
The potential research and clinical use of TMS have been reviewed elsewhere (George et al. 1999;
Lisanby et al. 2002; Wassermann and Lisanby 2001). TMS is not currently FDA approved for any
clinical condition, although it is approved as a treatment for depression in Canada. Most of the
clinical work with TMS has focused on its potential therapeutic value in the treatment of
depression, but promising work is emerging in schizophrenia and anxiety disorders.
A growing number of studies suggest that rTMS may be useful in the treatment of major depressive
episodes (Aarre et al. 2003; Burt et al. 2002; Holtzheimer et al. 2001; Kozel and George 2002; Loo
and Mitchell 2005). The antidepressant efficacy of rTMS appears comparable to that of ECT in
nonpsychotic patients (Schreiber et al. 2002), but true double-blinding of such comparisons
remains evasive. Most rTMS studies have enrolled patients who are resistant to one or more classes
of antidepressants but not necessarily resistant to ECT. Despite many placebo-controlled trials
revealing a statistically significant difference between rTMS and sham treatment, only a few studies
have reported substantial rates of response or remission. Meta-analyses have reported relatively
low response rates for rTMS (>50% reduction in depressive symptoms; e.g., 13.7% with rTMS vs.
7.9% with sham stimulation [Holtzheimer et al. 2001]) (see also Burt et al. 2002; Kozel and George
2002). Findings from more recent studies using longer durations of treatment and sequential
bilateral stimulation are more encouraging (Fitzgerald et al. 2006; Gershon et al. 2003; Holtzheimer
et al. 2001). Recently released results of a major pivotal trial demonstrated a significant
improvement in the active rTMS group over sham treatment (Aaronson et al., in press).
MAGNETIC SEIZURE THERAPY
Magnetic seizure therapy (MST), a novel investigational treatment, uses high-dose rTMS to induce
seizures for therapeutic purposes (Kosel et al. 2003; Lisanby et al. 2001, 2003a). MST requires
anesthesia but offers better control over the site of stimulation and intracerebral current density
than does ECT. MST allows the targeting of specific brain regions implicated in depression while
reducing the spread to other brain areas. By limiting the spread of activation to limbic regions, MST
may reduce the cognitive side effects associated with ECT. In humans (Kosel et al. 2003; Lisanby et
- 2003a) and other primates (Moscrip et al. 2005), MST has fewer cognitive side effects than does
ECT.
Since the first use of MST in a patient with treatment-resistant major depression (Lisanby et al.
2001), several trials of MST have been conducted, including a randomized, within-subject,
double-masked trial comparing ECT and MST in 10 patients with treatment-refractory major
depression (Lisanby et al. 2003a). MST seizures had shorter duration, lower ictal EEG amplitude,
less postictal suppression, and faster orientation recovery. Measures of attention, retrograde
amnesia, and category fluency were superior in MST, and fewer subjective side effects were
reported in MST recipients. Because MST has the potential of retaining the efficacy of ECT but with
fewer cognitive side effects, it may be of use for patients who are unresponsive to antidepressant
medications but cannot tolerate ECT.
DEEP BRAIN STIMULATION
With deep brain stimulation (DBS), intracranial electrodes are implanted and chronically stimulate
targeted brain areas. Unlike lesioning procedures, DBS is believed to be fully reversible, and the
intensity of stimulation can be adjusted according to the acute effect on symptoms. DBS has been
successfully used in treatment-refractory patients with Parkinson’s disease, essential tremor,Print: Chapter 27. Convulsive and Other Somatic Therapies http://www.psychiatryonline.com/popup.aspx?aID=257457&print=yes…
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dystonia, and other movement disorders. DBS is being studied for treatment of psychiatric
conditions, such as obsessive-compulsive disorder and depression (Kopell et al. 2004). At this time,
about 20 patients worldwide have received DBS for depressive disorders, with varying stimulation
sites: the white matter underlying cingulate area 25 (Mayberg et al. 2005), the internal
capsule/nucleus accumbens (T. Schlaepfer, personal communication, May 2006), and the inferior
thalamic peduncle (Jimenez et al. 2005).
An open-label series of six patients with treatment-refractory depression were treated with DBS
and demonstrated very encouraging results (Mayberg et al. 2005). Upon activation of DBS, all six
patients spontaneously reported immediate improvement in mood, a feeling of calm, and increased
interests. In four of six patients, antidepressant response was maintained at 6 months, and three of
these four subjects achieved full remission. Subsequent controlled studies are needed to establish
the safety and efficacy of this most focal, although most invasive, treatment for refractory
depression.
TRANSCRANIAL DIRECT CURRENT STIMULATION
Transcranial direct current stimulation (tDCS), or direct current polarization, is a noninvasive
means of electrically polarizing neurons in the human cerebral cortex. tDCS entails the delivery of
1–3 mA of direct current through scalp electrodes, exerting a polarity-dependent effect on cortical
neurons at the stimulation site locally and downstream. Anodal stimulation facilitates cortical
function, while cathodal stimulation inhibits it. tDCS may enhance verbal fluency, improve word
recall, and facilitate recovery from hand paresis in stroke patients (Hummel et al. 2005). A recent
double-blind, randomized, sham-controlled trial of tDCS in depression found significant
antidepressant effect after anodal stimulation over the dorsolateral prefrontal cortex given for
20 minutes per day over 5 alternate days (Fregni et al. 2005). The low cost and good safety profile
of tDCS make it an attractive modality relative to other more invasive and costly procedures
(Nitsche 2002). Further clinical trials of longer duration are indicated.
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MST, VNS and DBS. Zhonghua Yi Xue Za Zhi (Taipei) 65:349–360, 2002 [PubMed]Print: Chapter 27. Convulsive and Other Somatic Therapies http://www.psychiatryonline.com/popup.aspx?aID=257457&print=yes…
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Copyright © 2009 American Psychiatric Publishing, Inc. All Rights Reserved.
Course Content
Introduction to Convulsive and Somatic Therapies
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History and Evolution of Convulsive Therapies
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Principles of Somatic Therapies
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Introduction to Convulsive and Somatic Therapies Quiz
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Ethical Considerations in Convulsive and Somatic Therapies
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Current Trends and Future Directions
Understanding the Mechanisms of Action
Advanced Techniques in Convulsive Therapy
Innovative Approaches in Somatic Therapies
Integrating Therapies: Case Studies and Applications
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