Chapter 20 Opioid Maintenance Treatment

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DOI: 10.1176/appi.books.9781585623440.351947

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Chapter 20. Opioid Maintenance Treatment

OPIOID MAINTENANCE TREATMENT: INTRODUCTION

Opioid dependence (i.e., dependence on opiate or opiate-like drugs) is a chronic and severe

psychiatric disorder associated with substantial risk of mortality, medical and other psychiatric

morbidity, and adverse social, vocational, familial, and legal consequences. As with other chronic

and severe medical or psychiatric disorders, the goals of treatment are to prevent or reduce the

adverse medical, psychiatric, and other consequences of the disorder and to improve the patient’s

functioning, quality of life, and overall well-being.

Since its development in the 1960s as a treatment for opioid dependence, opioid agonist

maintenance treatment, initially with methadone and more recently with L- -acetyl-methadone

(LAAM) or the partial agonist buprenorphine, has proven to be the most effective treatment for

opioid dependence. This treatment greatly reduces the risk of mortality, morbidity, and other

adverse consequences of the disorder. Methadone or other opioid agonist maintenance treatment

generally refers to a comprehensive treatment approach that includes the continuing

administration of opioid medications under medical supervision in combination with drug

counseling, behavioral monitoring and intervention, and provision of other psychiatric, medical, and

vocational services as clinically indicated. Medically supervised provision of methadone

maintenance alone, in the absence of counseling or other services (referred to as interim

methadone maintenance in the United States), however, may still lead to substantial benefits

compared with not providing methadone maintenance (Schwartz et al. 2007). Although other

treatments (e.g., medically supervised withdrawal followed by opioid antagonist maintenance

treatment or long-term residential therapeutic community treatment) are efficacious for some

patients, the widespread patient appeal of opioid agonist maintenance treatment, high treatment

retention, substantial reductions of illicit drug use and criminal activity, and improvement in

medical, social, family, and vocational functioning during opioid agonist maintenance treatment

combine to make it the most effective approach for individuals meeting eligibility requirements for

1.  

Nevertheless, the rationale for methadone or other opioid agonist maintenance treatment is often

misunderstood; social and political opposition to methadone maintenance treatment limits its use

in many regions of the world and within the United States; access to the treatment is often limited

by inadequate treatment resources (lack of programs or treatment “slots”) and reimbursement;

and methadone or other opioid agonist maintenance treatment is often suboptimal and provided

without adhering to research-based principles that are known to improve its efficacy.

In this chapter, I review the rationale for opioid agonist maintenance treatment and the clinical

pharmacology, medication interactions, and adverse effects of methadone; the research supporting

the efficacy and effectiveness of methadone maintenance treatment overall and the efficacy of

specific components of treatment (dose, counseling, duration of treatment); special treatment

issues (comorbid other substance use, psychiatric disorders, and medical disorders; pain

management; pregnancy); federal rules governing opioid agonist maintenance treatment; and

opioid agonist maintenance treatment in primary care clinics and physician offices.

The clinical pharmacology of buprenorphine, the third medication approved by the U.S. Food and

Drug Administration (FDA) for opioid agonist maintenance treatment, is reviewed in Chapter 21,

“Buprenorphine Maintenance,” in this volume.

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Recent studies point to an increase in illicit opioid use and dependence in the United States during

the past decade and indicate that approximately 2 million adults are dependent on heroin or

nonmedically prescribed prescription opioids (SAMHSA 2006). Initiation of illicit opioid use most

often begins in late adolescence and early adulthood and is generally preceded by use of cigarettes,

alcohol, and other drugs. The latency period for the transition from occasional use to dependence is

variable and may last only a few weeks to several years or more. The number of new users of

nonmedically prescribed opioids (by oral, intranasal, or injection routes) has increased in the

United States from an estimated 600,000 individuals in 1990 to 2.2 million individuals in 2006 and

has become the drug category with the largest number of new users each year (SAMHSA 2007).

The availability of high-purity heroin, which may be used by nasal insufflation or smoking, may also

have lowered the threshold for initial experimentation with heroin and attracted many new users

(Bach and Lantos 1999).

Heroin continues to be used primarily by injection in many regions in the United States, but in some

regions of the country most patients addicted to heroin entering treatment now report noninjection

routes of administration (National Institute on Drug Abuse 2005). Although these other routes of

administration reduce the risk of infectious diseases (e.g., HIV, hepatitis, endocarditis), the risk of

transition from nonmedically prescribed opioids to heroin and from noninjection to injection use is

high—one study estimated that 15% of intranasal heroin users convert to injection use each year

(Neaigus 1998)—and the incidence of infectious diseases increases dramatically following

transition to injection use. Drug overdose is also a significant risk with insufflation or smoking of

heroin or with oral, intranasal, or injection use of prescription opioids, although many users are not

aware of this risk.

The transition from heroin use to dependence carries a dire prognosis, with a risk of dying of

approximately 2% per year, and sustained remission is difficult to achieve. A little more than 30

years after admission to compulsory drug abuse treatment in California, nearly half of the 581

heroin-addicted men followed up on in one cohort study had died (Hser et al. 2001). At the time of

admission, most of these heroin-addicted men were in their 20s and 30s, and the results of this and

other studies indicate that, in comparison with peers matched for age, gender, and socioeconomic

status, the annual risk of dying for a heroin-addicted person is increased 6- to 20-fold. Most of the

excess mortality is due to drug overdose, suicide, violence, accidents, infection, or chronic liver

disease. Only 23% of the original cohort of addicted men in California were not currently using

illicit opiates 33 years after admission; the rest were currently using (9%), refused to provide a

urine specimen for toxicology testing (4%), were in prison (6%), were not interviewed (10%), or

were dead (49%). Notably, only about one out of six of those who were continuing to use 20 years

after admission and about the same proportion of those who had been abstinent for less than 5

years at that time point were abstinent 10 years later. One-quarter of those who had been

abstinent for more than 15 years at the 20-year follow-up also relapsed over the next 10 years.

These findings point to the persistence of the disorder and the high risk of relapse even after long

periods of remission. Less than 10% of the cohort participated in methadone maintenance

treatment in any given year, but heroin use was reduced in those who participated in this

treatment. As has been so vividly demonstrated in the results of this and other long-term follow-up

studies (Vaillant 1973), after its onset, the course of heroin or other opioid dependence is chronic

and persistent, marked by periods of abstinence that are often followed by relapse, and associated

with a severe risk of death or disability.

CLINICAL PHARMACOLOGY OF METHADONE AND LAAM

Methadone is a synthetic, long-acting, orally available opioid that acts primarily as a high-affinity

agonist at and opiate receptors; methadone also acts as an N-methyl-D-aspartate (NMDA)

antagonist (Gutstein and Akil 2001). After oral administration, methadone is rapidly and nearly

completely (85%–90%) absorbed in the intestine. Absorption can be delayed by reductions in

gastric emptying caused by food, by hypertonic sucrose solutions often used to dissolve methadone

(in order to deter its injection), or by methadone itself. Peak plasma levels of methadone occur 2–6

hours after oral administration. Methadone is highly lipophilic, has a large volume of distribution,Print: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

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and accumulates in high concentrations in solid organs (liver, kidney, lungs, and brain) (Wolff et al.

1997).

Generally administered as a racemic mixture, R-methadone has substantially higher affinity and

efficacy at and opioid receptors and lower protein binding in plasma compared with the

S-enantiomer. S-methadone is not inactive, however, and has comparable NMDA antagonist activity

to R-methadone and, compared with R-methadone, is associated with an opposite profile of effects

on mood (negative mood states) and withdrawal symptoms (increased rather than relieved),

especially at higher daily doses of the racemic mixture (Mitchell et al. 2004). Methadone undergoes

N-demethylation to a highly unstable compound, which undergoes rapid and spontaneous

cyclization and dehydration to the major inactive methadone metabolites. The major route of

methadone metabolism is through cytochrome P450 (CYP) enzymes, predominantly involving the

CYP3A4 pathway but also involving CYP2B6, CYP2C19, CYP2D6, CYP2C9, and possibly also CYP1A2

and CYP2C8 (Crettol et al. 2006); methadone also inhibits CYP2D6 (Eap et al. 2001). After oral

administration, methadone and its metabolites are excreted in approximately equal amounts in

urine, and urinary excretion accounts for about 50% of the dose.

The long plasma half-life of methadone (averaging 24 hours, with a range of 13–50 hours) after

repeated daily dosing results in part from accumulation of methadone in organ systems, and

achievement of steady-state plasma levels may take 5–10 days. Its long half-life permits

once-a-day methadone dosing during maintenance treatment. During maintenance treatment,

peak-to-trough plasma ratios generally range from 2:1 to 4:1 (Foster et al. 2001). Trough

concentrations exceeding 200 ng/mL are usually sufficient to prevent withdrawal, although some

studies suggest that an increased rate of decline, associated with more rapid metabolism of

methadone, even with adequate trough levels, also may be associated with withdrawal symptoms

(Dyer et al. 1999). There are considerable interindividual differences in methadone metabolism,

which may be mediated by genetic polymorphisms affecting the activity of CYP isoforms as well as

by medications that induce or inhibit these enzymes or by liver disease. Although clinically

significant diurnal alterations in mood state are not observed or reported during methadone

maintenance treatment for most patients, mood changes associated with changes in methadone

plasma concentration have been observed after administration of a sensitive assessment measure,

the Profile of Mood States. These changes are more pronounced before patients have developed full

tolerance to their daily dose and in patients who report experiencing withdrawal symptoms even

while taking a stable methadone dose compared with patients who do not report withdrawal (Dyer

et al. 2001). As a result, some patients with very rapid methadone metabolism may benefit from

methadone dosing two times a day (split dosing).

LAAM, a methadone derivative also approved by the FDA for opioid agonist maintenance treatment,

has a longer half-life than methadone (2 days) and is metabolized by CYP enzymes (primarily

CYP3A4) to two active metabolites with half-lives of 2 days (nor-LAAM) and 4 days (dinor-LAAM)

(Neff and Moody 2001). Like methadone, LAAM acts as a full agonist at opiate receptors and is

absorbed from the gastrointestinal tract after oral administration, with initial effects appearing

within 1 or 2 hours. Because LAAM is slowly metabolized to two active metabolites, which are

somewhat more potent than LAAM, steady-state levels of LAAM and its active metabolites and its

full effects are achieved after 1–3 weeks. Daily dosing can lead to excessive accumulation of active

medication and metabolites, and Monday-Wednesday-Friday dosing is recommended. The longer

period required to achieve a full maintenance dose is thought to be responsible for the greater

early attrition from treatment found during induction onto LAAM compared with methadone. The

abuse liability of LAAM is comparable with that of methadone, and consequently, use of LAAM is

restricted to approved narcotic treatment programs, which diminished its appeal to patients.

Reports of clinically significant prolongation of the QT interval and torsades de pointes associated

with LAAM led to its removal from the European Union and a black box warning in the United

States, and LAAM is no longer being marketed in the United States.

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Knowledge of possible interactions between opioid agonist medications used for maintenance

treatment and other prescribed or herbal medications or use of other substances is essential to

ensure the safety and efficacy of methadone dosing and dosing with other medications. Medication

interactions with methadone have been more thoroughly evaluated than with buprenorphine or

LAAM, and interaction effects with LAAM are complicated because its major metabolites are active.

Methadone metabolism may be increased substantially by concomitant administration of

medications that induce CYP hepatic enzymes (e.g., carbamazepine, phenytoin, rifampicin,

efavirenz, nevirapine, ritonavir, nelfinavir, phenobarbital, dexamethasone, spironolactone, and

possibly risperidone), and initiation of treatment with any of these medications may lead to

withdrawal symptoms in a methadone-maintained patient (Rainey 2002). Initiation of risperidone

treatment during methadone maintenance also has been associated with precipitation of opioid

withdrawal, possibly through induction of methadone metabolism, interference with methadone

absorption, or a direct effect of risperidone on opioid receptors (Wines and Weiss 1999).

Methadone also induces its own metabolism during the first 2–3 weeks of administration, and the

elimination half-life of methadone early in treatment is considerably longer (median 128 hours)

than after patients have been treated for more prolonged periods (median 48 hours) (Wolff et al.

2000). Initiation of St. John’s wort, which induces CYP3A4, was reported to reduce methadone

trough plasma concentrations substantially (19%–60%) in four patients and to lead to withdrawal

symptoms in two of the patients (Eich-Höchli et al. 2003).

Medications that inhibit CYP enzymes, including some macrolide antibiotics (e.g., erythromycin or

azithromycin), fluoroquinolones (e.g., ciprofloxacin), azole antifungals (e.g., ketoconazole or

voriconazole), and some selective serotonin reuptake inhibitors (e.g., sertraline, fluoxetine, or

fluvoxamine), may cause inhibition of methadone metabolism and symptoms associated with

increased methadone plasma levels, including sedation, confusion, or possibly respiratory

depression. The effects can be quite severe, as illustrated by a case report of a 42-year-old woman

treated with 140 mg/day of methadone for 6 years who experienced sedation, confusion, and

respiratory depression when treated for recurrent urinary tract infections with ciprofloxacin, a

potent inhibitor of CYP1A2 and CYP3A4 (Herrlin et al. 2000). Concurrent treatment with

venlafaxine (or on one occasion with fluoxetine), cigarette smoking, and acute infection may have

contributed to the severity of her symptoms. Fluoxetine and fluvoxamine, inhibitors of CYP2D6 and

CYP1A2, respectively, as well as paroxetine and fluconazole cause delayed metabolism and

increases in plasma methadone half-life (Begre et al. 2002). Grapefruit juice also inhibits CYP3A4

and may lead to modest increases in peak and 24-hour area-under-the-curve plasma methadone

concentrations. Increases in methadone plasma levels due to inhibition of methadone metabolism

are most likely to cause clinically significant symptoms at the onset of methadone treatment (when

patients have the lowest tolerance) and in patients with underlying liver disease. Methadone

treatment also affects the metabolism of other medications and causes increased plasma levels of

desipramine, amitriptyline, and zidovudine. Table 20–1 shows some of the reported and possible

medication interactions with methadone.

TABLE 20–1. Medication interactions with methadone

May reduce

plasma

methadone

May increase

plasma

methadone

Methadone may

increase plasma

levels of

Methadone may

decrease plasma

levels of

May increase risk of

arrhythmia if used

with methadone

Abacavir Amiodarone Amitriptyline Didanosine

Ca++ channel blockers

Amprenavir Cimetidine Desipramine Stavudine Class I, II

antiarrhythmics

Carbamazepine Ciprofloxacin Zidovudine Haloperidol, possibly

other neuroleptics

Efavirenz Erythromycin

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May reduce

plasma

methadone

May increase

plasma

methadone

Methadone may

increase plasma

levels of

Methadone may

decrease plasma

levels of

May increase risk of

arrhythmia if used

with methadone

Lopinavir +

ritonavir

Fluconazole

Possibly laxatives

Nelfinavir Fluoxetine

Possibly tricyclic

antidepressants

Nevirapine Fluvoxamine

Phenobarbital Saquinavir

Phenytoin Sertraline

Rifampin Voriconazole

Risperidone

Ritonavir

St. John’s wort

Note. The effects of medication interactions are further complicated by the need to take into consideration

the effects of medication discontinuation. For example, discontinuation of a medication that inhibits

methadone metabolism, such as fluoxetine, can lead to increased methadone metabolism and the occurrence

of withdrawal symptoms, craving, or relapse in a previously asymptomatic and stable patient receiving

methadone maintenance treatment.

Methadone interactions with antiretroviral medications and with medications used to treat hepatitis

C are of particular interest because of the high prevalence of HIV and hepatitis C infection among

injection drug users (Rainey 2002). Although protease inhibitors are potent inhibitors of CYP3A4,

nelfinavir causes substantial decreases (40%) in plasma methadone, which can be associated with

withdrawal symptoms, possibly as a result of also inducing CYP enzymes or increasing the free

(unbound) fraction of methadone in plasma. Methadone inhibition of the glucuronidation of

zidovudine increases the plasma concentrations of this medication and the potential for

dose-related toxicity. Methadone-induced decreased gastrointestinal motility, however, leads to

increased gastrointestinal degradation of stavudine and didanosine and significant decreases in

plasma concentrations of these medications. No significant interactions have been found between

methadone and either peg interferon or ribavirin, both of which are used to treat hepatitis C

(Sulkowski et al. 2005).

RATIONALE FOR OPIOID AGONIST SUBSTITUTION TREATMENT WITH

METHADONE

The main, planned, and desired pharmacological effects of methadone, LAAM, or buprenorphine

when used for opioid agonist maintenance treatment are to prevent withdrawal and craving and to

block or attenuate the euphoric or other rewarding effects of heroin or other illicit opioid use. Oral

methadone dosages of 20–40 mg/day are generally sufficient to prevent or at least greatly

attenuate opiate withdrawal symptoms. Because craving for opiates is one of the earliest and most

powerful hallmarks of withdrawal, preventing withdrawal greatly reduces craving or the urge to

use illicit opioids. Preventing withdrawal also eliminates the repeated negative reinforcement that

occurs when heroin or other illicit opioids are self-administered to relieve withdrawal. Chronic

administration of higher doses of methadone, buprenorphine, or LAAM may directly reduce craving

(possibly by preventing more subtle manifestations of withdrawal) and also induce dose-dependent

tolerance to the effects of street doses of heroin and other illicit opioids, so that individuals

receiving sufficiently high doses experience little or no direct reinforcement from illicit opioid use

(Donny et al. 2002, 2005).

Additional advantages of the medications used for opioid agonist maintenance treatment are that

all of them have long-lasting effects on opiate receptors and substitute a less dangerous and lessPrint: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

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reinforcing method of administration (oral or sublingual) for more dangerous and reinforcing

routes (injection, smoking, nasal insufflation). Unlike the fluctuations in mood and consciousness

associated with repeated illicit administration of heroin and other short-acting opioids,

administration of long-acting maintenance medications during maintenance treatment normalizes

most neuroendocrine alterations found with use of short-acting opioids and does not substantially

alter mood or alertness throughout the day (Kreek and Koob 1998). Oral or sublingual routes of

administration lead to a relatively slow rate of increase in plasma (and brain) levels and are thus

less euphorigenic and inherently less reinforcing than routes associated with faster rates of

increase. During maintenance treatment, patients develop tolerance to the effects of their daily

methadone dose and generally experience no or only very limited and transient effects of their

daily dose. By preventing withdrawal, attenuating euphoric effects of illicit opioid use, reducing

illicit opioid use, and stabilizing mood, opioid agonist substitution treatment also provides a stable

medication platform facilitating provision of drug abuse counseling and other effective

rehabilitation services.

SAFETY AND TOXICITY

More than 40 years of clinical experience with methadone maintenance treatment, involving

hundreds of thousands of patients worldwide, has established the overall safety of methadone

when used for opioid agonist maintenance treatment. When used for maintenance treatment,

methadone has not been found to produce any long-term damage to heart, lung, kidney, liver,

brain, or other organ systems (Kreek 2000). Heroin and other opioid dependence is associated with

alterations of hypothalamic-pituitary-adrenal (HPA) axis and immune system functioning, whereas

methadone maintenance treatment generally leads to normalization of most measures of HPA axis

and immune system functioning and overall improvement in health status, although some

alterations of corticotropin releasing factor responsivity and other neuroendocrine measures may

persist (Schluger et al. 2003). The most commonly reported adverse effects of methadone when

used for maintenance treatment include constipation, which may be quite severe; sweating; and

urinary retention. Additionally, methadone maintenance treatment may be associated with

lymphocytosis and increased prolactin, albumin, and globulins. Adverse effects of methadone early

in treatment may also include nausea and vomiting, lightheadedness, hypotension, dizziness,

anorexia, and dry mouth. Methadone dose-related orgasm dysfunction (anorgasmia or delayed

orgasm) has recently been reported in men receiving methadone maintenance treatment, but other

measures of sexual dysfunction were not more prevalent in this population of men than in the

general population (Brown et al. 2005). Decreased respiratory sensitivity to carbon dioxide and

sleep apnea have also been reported for patients receiving methadone maintenance treatment, but

cigarette smoking may represent an important confound (Greenwald 2004). Similarly, low bone

density has also been reported among methadone-maintained patients, but a variety of (potentially

treatable) underlying medical conditions and dietary factors may account for this (Kim et al. 2006).

Although methadone is generally quite safe for maintenance treatment, methadone overdose can

cause severe sedation, respiratory depression, and death (Wolff 2002). Signs of methadone

overdose include drowsiness or coma, limpness, depressed respiratory rate and depth, loud

snoring, pin-point pupils, hypotension, and bradycardia. Methadone overdose may also lead to

pulmonary edema or aspiration. Overdose is particularly a problem with regard to accidental

ingestion by children, use by nondependent opioid users who experiment with methadone or

self-administer it, or at the initiation of methadone maintenance treatment if the initial doses are

too high or the methadone dose increased too rapidly. There are reports of apnea and coma in

children after ingestion of 5 mg of methadone and of death following ingestion of 10 mg of

methadone, although prompt treatment of overdose has led to complete recovery in children after

ingestion of much higher doses. Because of its long elimination half-life and the possibility of

delayed absorption, methadone overdose requires prolonged treatment.

Death has been reported to occur more than 24 hours after ingestion (and several hours after

discontinuation of naloxone treatment). Several studies report increased mortality rates during the

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methadone maintenance treatment, with much of the increased mortality attributed to overdose

deaths. Methadone dosages in excess of 40–50 mg/day at the onset of methadone maintenance

treatment, when methadone has not yet induced its own metabolism and its elimination half-life is

quite prolonged, may lead to methadone accumulation and overdose death even in individuals who

report large heroin habits but who are not fully tolerant to the full effects at both and receptors

of methadone. Fatalities may occur after several days of dosing if the methadone dose is started

too high or increased too rapidly (Buster et al. 2002). The risk of methadone overdose is increased

by concomitant use of medications interfering with methadone metabolism (e.g., medications that

inhibit CYP3A4) or use of alcohol or sedating drugs (e.g., benzodiazepines, chloral hydrate).

Individuals with reduced methadone metabolism due to genetic factors or liver disease and

individuals with underlying pulmonary, cardiac, liver, or renal disease may also be at increased risk

for overdose (Corkery et al. 2004). Recent guidelines for induction onto methadone maintenance

treatment recommend starting dosages of no more than 30–35 mg/day and gradual dosage

increases (5–10 mg no more frequently than every 2–3 days). Considerably lower starting dosages

may be advisable for patients at higher risk for overdose, including patients with underlying severe

respiratory or liver disease, patients treated with sedating medications or medications inhibiting

CYP3A4, or patients with lower baseline tolerance to opioids (Srivastava and Kahan 2006).

Recent reports indicate an association between methadone and cardiac conduction defects

(prolonged QTc interval) and torsades de pointes (Krantz et al. 2002), an association previously

noted for LAAM. A black box warning about these effects was added to the prescribing information

for methadone in December 2006. Methadone may also induce bradycardia through its effects on

calcium channels, as illustrated in a recent case report of bradycardia associated with methadone

administration to a patient dependent on both opioids and benzodiazepines (Ashwath et al. 2005).

Clinically significant prolongation of the QTc interval (>500 ms) during methadone treatment has

been reported in association with high methadone doses (mean ± SD 231 ± 201 mg in one review

of cases; Justo et al. 2006), but 29% of cases reported to the FDA were in patients treated at

dosages of 60–100 mg/day (Pearson and Woosley 2005). The incidence of clinically significant

prolongation of the QTc interval among methadone-maintained patients has not been sufficiently

studied; one small study found it in 2 of 83 methadone-maintained patients (Maremmani et al.

2005), whereas another study in a program using higher methadone dosages found it in 3 of 138

patients (Peles et al. 2006). Additional risk factors for prolongation of the QTc interval in

methadone-maintained patients include concomitant use of other medications causing QTc

prolongation or arrhythmias (e.g., haloperidol, class I or II antiarrhythmics, tricyclic

antidepressants, or calcium channel blockers), inhibiting methadone metabolism, or causing

electrolyte disturbances (e.g., diuretics); hypokalemia; liver dysfunction; heart disease; or cocaine

use. Methadone effects on the QTc interval may result from blockade of ionic current through

potassium channels composed of subunits expressed by the human ether-a-go-go–related gene.

These considerations suggest the need for caution and possibly repeat electrocardiogram testing

when prescribing higher dosages of methadone (e.g., greater than 120 mg/day) and when

prescribing methadone for patients with prolonged QTc intervals or with other risk factors for QTc

prolongation or cardiac arrhythmias, including, for example, cardiac hypertrophy (Deamer et al.

2001).

Although methadone causes sedation in individuals who have not developed tolerance, methadone

maintenance treatment is generally not associated with significant sedative effects once patients

have developed tolerance to their daily methadone dose, nor is it associated with alterations of

neuropsychological functioning. With regard to driving, an evidence-based review of methadone

maintenance effects on driving performance concluded that there is relatively strong and consistent

evidence that the driving ability of patients stabilized on long-term opioid treatment is not impaired

by their regular doses of opioid medication (Fishbain et al. 2003). Patients should be advised not to

drive if they feel sedated, not to drive after using alcohol (or illicit drugs), and to be particularly

cautious if they are using medications that may increase sedation (e.g., antihistamines,

benzodiazepines) or after a dose increase. A range of neuropsychological impairments has been

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executive functioning (impulse control, planning, and decision making), verbal and visual memory,

attention, processing speed, and response inhibition. These deficits may persist after prolonged

periods of abstinence from illicit opioid use and may reflect preexisting deficits or result from

alcohol or drug abuse. Notably, however, stabilized patients receiving methadone maintenance

treatment with no evidence of illicit drug use for the preceding 18 months do not differ in measures

of neuropsychological functioning from former heroin users abstinent from illicit drug use for the

past 18 months (Prosser et al. 2006). During methadone induction or before patients have

developed tolerance to their methadone dose, methadone dose administration may be associated

with some effects on mood and cognition, including some impairment of delayed verbal recall

(Curran et al. 2001). One recent study documented significant improvement from pretreatment

baseline after 2 months of methadone maintenance treatment on measures of learning, memory,

and psychomotor performance (Gruber et al. 2006). The underlying cognitive impairments of

opioid-dependent patients (including memory and attention deficits) suggest the importance of

carefully tailoring drug counseling to the cognitive abilities of the patient, especially at the

beginning of methadone maintenance treatment, when these deficits may be most pronounced.

EFFECTIVENESS OF OPIOID AGONIST MAINTENANCE TREATMENT

The effectiveness of methadone and other opioid agonist maintenance treatments for reducing

illicit drug use, reducing mortality and morbidity, and improving social, vocational, and legal

functioning has been established in randomized, controlled clinical trials and quasi-experimental

and observational studies and has been validated in several recent meta-analyses (Institute of

Medicine Committee on the Prevention of HIV Infection Among Injecting Drug Users in High Risk

Countries 2006). Mortality rates are reduced substantially during methadone maintenance

treatment, although they remain somewhat higher than for the general population because of the

impaired health of many patients at treatment entry (e.g., HIV infection, hepatitis C). The risk of

new infection with HIV is substantially reduced in patients receiving methadone maintenance

treatment compared with untreated heroin-addicted patients in the same geographic setting, and

the risk decreases in association with the length of time continuously treated with methadone

maintenance (Metzger et al. 1993). Criminal activity decreases during treatment and has been

found to increase substantially among individuals discharged from treatment because of the closing

of public methadone programs after financial cutbacks (Anglin et al. 1989). Follow-up data from

the National Treatment Outcome Study confirm the findings of previous national studies of drug

abuse treatment regarding the effectiveness of methadone maintenance treatment for reducing

illicit drug use and criminal activity (Hubbard et al. 1997).

Most studies of the long-term effects of treatment are based on methadone maintenance, but

shorter-term studies (generally lasting up to 6 months) suggest that the effectiveness of

maintenance treatment with LAAM or buprenorphine is comparable with that with methadone. Early

attrition from LAAM compared with methadone has been a problem in some studies (Clark et al.

2002), but results for methadone, buprenorphine, and LAAM, when provided at sufficient doses,

were comparable (and significantly better than the results for a group treated with low-dose

methadone) in a large, double-blind clinical trial (Johnson et al. 2000). Recent meta-analyses

suggest that methadone may be associated with somewhat better overall reductions in illicit opiate

use compared with buprenorphine maintenance, although sufficient doses of both methadone and

buprenorphine are more efficacious than low maintenance doses of either medication (Mattick et

1. 2004). Advantages of buprenorphine compared with methadone, including a decreased risk of

respiratory depression, led to buprenorphine being classified as a Schedule III narcotic and thus

permitted to be prescribed by specially certified physicians in office-based practices, whereas

methadone is a Schedule II narcotic and may only be dispensed for methadone maintenance

treatment in specialized narcotic treatment programs.

Despite the overwhelming scientific evidence establishing the efficacy and effectiveness of opioid

agonist maintenance treatment, misunderstanding of, prejudice toward, and political opposition to

methadone treatment persist and continue to interfere with efforts to increase access to and

availability of this treatment modality in the United States and elsewhere in the world. At present,Print: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

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only about 240,000 of the estimated 2 million individuals dependent on heroin or other opioids in

the United States are enrolled in opioid agonist maintenance treatment. When methadone

maintenance treatment has been made widely available, free or at low cost, and publicized, 90% or

more of the heroin-addicted population have been attracted into treatment (Hartgers et al. 1992).

Economic factors, including medical insurance coverage (or the lack of coverage) for methadone

maintenance treatment, affect both entry and retention in methadone maintenance treatment. In

Oregon, 1-year retention in methadone maintenance increased from 28% to 51% when managed

care picked up the costs, whereas exclusion of methadone coverage from Medicaid led to decreased

entry into methadone maintenance treatment (Deck and Carlson 2005; Deck et al. 2006). These

findings indicate that the low market penetration of methadone maintenance treatment results

primarily from the lack of its availability in many geographic areas and the long waiting lists and

costs of treatment even in areas where programs are available, rather than from a lack of potential

need, interest, or demand for treatment.

Considerable program-to-program variability in how treatment is provided and in the effectiveness

of agonist maintenance treatment (as measured by the prevalence of continued illicit drug use

during treatment and other outcome measures) has drawn attention to identifying the key

components of methadone maintenance treatment (e.g., dose, duration of treatment, counseling,

program structure) and improving the quality of treatment programs (Ball and Ross 1991). The

most recent national survey of methadone treatment practices found that substantial progress had

been made in improving treatment practices compared with earlier surveys but still pointed to

continuing problems with inadequate methadone doses in many programs (D’Aunno and Pollack

2002).

METHADONE DOSE AND TREATMENT DURATION

The efficacy and effectiveness of maintenance treatment with methadone, as with LAAM and

buprenorphine, are dose dependent, and effective dosages generally fall within a targeted range of

60–120 mg/day or higher for methadone, 8–16 mg/day or higher for buprenorphine, and 80–140

mg three times per week for LAAM. The optimal dosage for a given patient, however, should be

based on the patient’s response to treatment.

Early observational studies pointed to the dose-dependent efficacy of methadone for maintenance

treatment, and more recent randomized, double-blind clinical trials and experimental studies

confirmed the earlier observations with regard to methadone and established the dose-dependent

efficacy of buprenorphine and LAAM. Although methadone dosages of 20–30 mg/day lead to

greater retention in treatment compared with placebo doses, illicit opioid use is dose-dependently

reduced at moderate (60–75 mg) daily doses and reduced even more at higher (100 mg) daily

doses (Strain et al. 1993, 1999). In experimental studies, dosages of 30 mg/day and 60 mg/day

are sufficient to suppress most withdrawal symptoms for more than 48 hours, but full attenuation

of the subjective and reinforcing effects of heroin (up to 20 mg/70 kg) occurs only with a higher

methadone dosage (100–150 mg/day) (Donny et al. 2002, 2005). Increased craving for opiates has

been observed 24 hours after a 25% reduction in the daily methadone dose, consistent with clinical

observations and patient reports of withdrawal-related discomfort and increased risk for

resumption of illicit opioid use following a missed daily methadone dose (Greenwald 2002).

Clinically, patients who continue illicit opioid use at a given daily methadone dose often reduce or

eliminate illicit opioid use when the daily methadone dose is increased gradually over several

weeks to a sufficiently high dose. Several studies suggest that some poor responders to methadone

dosages of 80–100 mg/day have increased metabolism of methadone and suboptimal trough

plasma methadone levels or increased rates of clearance; increasing the methadone dose to

achieve trough levels greater than 200 ng/mL, or providing methadone in split doses to prevent

trough levels from declining too rapidly or below this target, can help to reduce or eliminate

continued illicit opiate use (Dyer et al. 2001).

Duration of treatment is also a critical factor, and premature discontinuation of methadone

treatment leads to relapse. In one randomized clinical trial, tapering of methadone dose to zeroPrint: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

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over 60 days (methadone detoxification) after 4 months of methadone maintenance treatment led

to accelerated attrition from treatment and significant increases in illicit opioid use in the test

group compared with a group assigned to continued methadone maintenance treatment (Sees et al.

2000). Substantial and sustained changes in vocational or social functioning and lifestyle may take

years to achieve for many patients (Gunne et al. 2002). Even then, the risk of relapse after

discontinuation of methadone maintenance remains high even for patients who have been receiving

methadone maintenance treatment for prolonged periods and have made substantial changes in

lifestyle and achieved stable recovery while receiving treatment. Because of the difficulties

experienced by many patients who attempt tapering and detoxification (Calsyn et al. 2006), the

high risk of relapse after discontinuing methadone maintenance treatment, and the very high risk

of severe adverse consequences associated with relapse, many patients may benefit optimally from

lifetime maintenance. Decisions about whether or when to discontinue methadone treatment for

patients who are benefiting from it should always be made collaboratively and with the patient’s

fully informed and voluntary consent.

Taken together, the results of observational studies, experimental human laboratory studies, and

randomized clinical trials are compelling: methadone maintenance dose-dependently decreases

illicit opioid use; its beneficial effects on health and social and vocational functioning may occur

gradually over prolonged periods; and the effectiveness of methadone maintenance treatment

diminishes substantially when methadone doses are lowered or discontinued, even when patients

can continue to receive enhanced psychosocial services.

DRUG COUNSELING AND BEHAVIORAL COMPONENTS OF AGONIST

MAINTENANCE TREATMENT

As with many other medical or psychiatric disorders, the effectiveness of medication treatment can

be greatly enhanced by combining medication administration with counseling aimed at promoting

treatment adherence and lifestyle change. The seminal study establishing the treatment effects of

counseling evaluated treatment outcomes for 92 patients randomly assigned to one of three levels

of services (minimal counseling, standard drug counseling, or standard drug counseling plus

enhanced vocational, legal, and medical services) (McLellan et al. 1993). All patients received

identical standard daily methadone doses. The prevalence of continued illicit opioid use and of

cocaine use was substantially higher among patients in the minimal counseling group, who

received only brief contact with a counselor once per month, compared with patients in the

standard counseling group, who received weekly or more frequent counseling until achieving

sustained abstinence, or the enhanced services group. By the end of 12 weeks, 69% of the patients

in the minimal counseling group had triggered the criteria for protective transfer (unremitting drug

use, as evidenced by 8 consecutive weeks of illicit opiate or cocaine use or three emergency

situations requiring immediate health care interventions), whereas 41% of those receiving

standard counseling and 19% of those receiving enhanced services met the criteria. Although

enhanced services led to the best outcomes overall, standard drug counseling was found to be the

most cost-effective approach.

Subsequent studies have found no overall advantage for requiring an intensive day treatment

program at program entry compared with weekly drug counseling, and some patients (e.g., those

with social anxiety) may benefit more from weekly individual drug counseling than from day

treatment (Avants et al. 1998, 1999). A variety of different types of counseling approaches,

including cognitive and behavioral treatment, the community reinforcement approach, 12-step

facilitation counseling, and counseling combining the different approaches, can be effective as long

as they are performed consistently and with a high degree of competence. In addition to the

specific counseling provided, behavioral monitoring (e.g., urine toxicology testing) during

treatment and consistent behavioral responses to patient’s behavior (e.g., providing take-home

methadone to patients who become abstinent or increasing the frequency and intensity of required

counseling for patients with continued illicit drug use) contributes greatly to improved treatment

outcomes (Brooner et al. 2007).

Although effective counseling improves outcomes for many patients, it is unclear whether allPrint: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

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patients require counseling to benefit from treatment, and the optimal frequency, intensity, and

duration of counseling have not been well established. Recent randomized clinical trials have

shown substantial benefits of providing methadone maintenance in the absence of any counseling

services, compared with waiting list control groups, with regard to reductions in illicit drug use and

subsequent enrollment in a full-service methadone maintenance treatment program (Schwartz et

1. 2006, 2007; Yancovitz et al. 1991). Interim methadone maintenance is permitted for up to 120

days under federal regulations in the United States that were designed to improve access to

methadone maintenance treatment in areas that have long waiting lists for entering full-service

narcotic treatment programs.

CO-OCCURRING PSYCHIATRIC DISORDERS

The prevalence of co-occurring substance use and other psychiatric disorders among

opiate-dependent individuals entering methadone maintenance treatment greatly exceeds the

prevalence found in the general population, even controlling for age, gender, socioeconomic status,

and other factors, as has consistently been shown in studies conducted over the past 25 years in

several different geographic areas (Brooner et al. 1997; Rounsaville et al. 1982). Left untreated,

many of these disorders are associated with an adverse prognosis and an overall poorer response

to methadone maintenance treatment. Thus, careful psychiatric assessment of patients entering

methadone or other agonist maintenance treatment and early institution of treatment interventions

for co-occurring disorders are essential.

A high prevalence of co-occurring alcohol abuse or dependence was noted in early studies of

patients receiving methadone maintenance treatment, and several studies suggested that

treatment with disulfiram administration (after detoxification, if necessary) supervised at the time

of methadone ingestion, led to improvement of alcohol dependence, illicit drug use, and social

functioning. Marijuana use is also very common among patients receiving opioid agonist

maintenance treatment, but the clinical significance of marijuana use in this population is a matter

of some controversy. Some studies suggest that marijuana use is not associated with other illicit

drug use during opioid agonist maintenance treatment, but marijuana use still may interfere with

full participation in treatment and rehabilitation (Nirenberg et al. 1996; Saxon et al. 1993).

Beginning in the early 1980s, cocaine abuse and dependence became epidemic among

opioid-dependent individuals. Although the prevalence of cocaine abuse and dependence has

declined substantially in the general population since then, these problems have remained endemic

among opioid-dependent individuals. The reported prevalence of cocaine abuse or dependence

among new admissions to methadone treatment ranges from 15% to 40% or more in the United

States. Although the prevalence of frequent cocaine use decreases substantially during opioid

agonist maintenance treatment (from 36% at treatment entry to 22% after 1 year in the Treatment

Outcome Prospective Study; Fairbank et al. 1993), continued cocaine abuse is associated with

continued illicit opiate use, injection drug use, increased risk of HIV and other infectious diseases,

increased risk of cardiac toxicity, and criminal activity.

Promising treatment interventions for cocaine abuse during opioid agonist maintenance treatment

include behavioral treatments such as contingency management, in which vouchers with a

monetary value are used to reward cocaine-free urine tests (Schottenfeld et al. 2005). Notably, in

this study, patients randomly assigned to methadone (60–90 mg/day) reduced illicit opiate and

cocaine use significantly more than patients assigned to buprenorphine (12–16 mg/day). Several

studies suggest that supervised administration of disulfiram also reduces cocaine use during

methadone or buprenorphine maintenance treatment (George et al. 2000; Petrakis et al. 2000),

independent of its effects on reducing alcohol use, but this is not an FDA-approved indication for

disulfiram. The potential severity of disulfiram-alcohol-cocaine interactions in patients who use

both cocaine and alcohol while taking disulfiram, as well as the potential risks of

disulfiram-induced hepatotoxicity or neuropathy, raise safety concerns about its use for this

indication. Recent preclinical and clinical studies suggest that increasing the methadone dose may

decrease cocaine as well as illicit opioid use. High-dose methadone is reported to block conditionedPrint: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

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place preference to cocaine and both spontaneous and cocaine-precipitated cocaine seeking in rats

(Leri et al. 2006), and some earlier clinical studies reported greater reductions in cocaine use with

higher compared with lower methadone doses (Stine and Kosten 1992).

Benzodiazepine abuse and dependence are also a problem for a high proportion (generally

comparable with the prevalence of cocaine abuse) of individuals receiving opioid agonist

maintenance treatment. As with concurrent cocaine abuse and dependence, benzodiazepine abuse

and dependence are associated with continued heroin or other illicit drug use, injection drug use,

increased risk of infection, and continued involvement in drug subcultures (Darke et al. 1993).

Benzodiazepine abuse also increases the risk of oversedation and respiratory depression in patients

receiving methadone maintenance treatment. Benzodiazepine use during agonist maintenance

treatment poses a difficult challenge for psychiatrists and treatment programs because many

patients experience anxiety disorders that could be treated with benzodiazepines, but

benzodiazepines are frequently misused by patients receiving opioid agonist maintenance

treatment (Spiga et al. 2001). Approximately one-third of the benzodiazepine-using patients in one

study reported taking higher benzodiazepine doses than prescribed, and many took very high doses

around the time of ingesting their daily methadone to boost the methadone effects (Stitzer et al.

1981). Gradual tapering and then discontinuation of benzodiazepines may be possible on an

ambulatory basis, but many patients require inpatient treatment to complete detoxification

successfully. Substitution with a longer-acting benzodiazepine, such as clonazepam, followed by

gradual tapering and discontinuation may offer some advantages. In one study comparing

clonazepam tapering and discontinuation with clonazepam maintenance, clonazepam maintenance

was associated with better retention and decreased benzodiazepine abuse (assessed by self-report

only) (Weizman et al. 2003). Clonazepam may also be administered under direct observation at the

time of methadone dispensing to reduce its potential for abuse or diversion.

Mood disorders, anxiety disorders, and personality disorders, which are also considerably more

prevalent among opioid agonist–maintained patients than in the general population, also may

adversely affect response to agonist maintenance treatment. Treatment of current depression,

found in approximately 15%–25% of those entering treatment, may lead to improvements in mood

and other depression outcome measures and also to reductions in illicit drug use (Nunes et al.

1998, 2004). Treatment of anxiety disorders in agonist-maintained patients is complicated by the

high abuse liability of benzodiazepines in this population. Cognitive and behavioral treatments for

anxiety disorders either alone or, when indicated, in combination with medications with little or no

abuse liability (e.g., buspirone, citalopram) can be beneficial for patients. A recent clinical trial

found no beneficial effect of buspirone for reducing anxiety symptoms in patients receiving

methadone maintenance treatment, however, although depressive symptoms were reduced in

these patients (McRae et al. 2004). Antisocial personality disorder, found in approximately 25% of

patients, has in some but not all studies been associated with a relatively less optimal response to

methadone maintenance treatment (Alterman et al. 1996).

CO-OCCURRING MEDICAL DISORDERS AND PROVISION OF MEDICAL CARE

Patients receiving opioid agonist maintenance treatment may experience health problems

associated with opioid dependence (e.g., AIDS, hepatitis B or C, tuberculosis) or common in the

general population (e.g., hypertension, diabetes, heart and lung disease), and the stabilizing

effects of maintenance treatment on patients’ overall functioning facilitate implementation of

effective medical treatment for these health problems and preventive health services. A study

conducted by the Centers for Disease Control and Prevention among 1,717 injection drug users

entering treatment in six cities in the United States found that 50%–81% had evidence of hepatitis

B, 66%–93% had hepatitis C, and infection with HIV ranged from 3%–5% in cities in the Midwest

and West to 28%–29% in the Northeast (Murrill et al. 2002). The prevalence of infection with

hepatitis B, hepatitis C, or HIV was significantly higher for older injection drug users than for

younger users. With the advent of effective treatments for HIV and hepatitis C, it is essential to

screen patients for these conditions at admission and at regular intervals during opioid agonistPrint: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

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maintenance treatment and to refer patients with these disorders for treatment. Several recent

studies have shown the safety and efficacy of peg interferon and ribavirin treatment for patients

with hepatitis C receiving methadone maintenance treatment. Peg interferon does not alter

methadone metabolism or pharmacokinetics, and patients receiving methadone maintenance

treatment show good virologic response to treatment (Mauss et al. 2004; Sulkowski et al. 2005).

Coordination of addiction treatment and medical treatments can improve medication adherence,

adherence to medical treatment recommendations, and response to medical treatment. Several

studies suggest that provision of onsite primary care medical services improves primary care

attendance and initial retention in methadone maintenance treatment (Saxon et al. 2006).

Treatment for hepatitis C can be integrated into methadone maintenance programs (Litwin et al.

2005) and is cost-effective (Sheerin et al. 2004). Interactions between opioid agonist maintenance

medications and some medications to treat medical conditions may necessitate dose adjustments

or consideration of alternative medication treatments, as noted earlier in this chapter in the section

“Medication Interactions.” Other preventive health services that benefit patients include

immunizations (e.g., for hepatitis B, for antibody- and antigen-negative patients who are at risk for

infection; for tetanus; and for pneumococcal pneumonia) as well as testing for tuberculosis and

syphilis and treatment for those with evidence of infection. Adherence to medical treatment, such

as prophylactic isoniazid treatment, can also be improved through directly observed treatment at

the time of methadone dispensing.

Because of the extremely high prevalence of cigarette smoking among opioid-dependent

individuals, health problems associated with cigarette smoking (e.g., emphysema, cancer,

cardiovascular disease) are common among patients receiving opioid agonist maintenance

treatment. Smoking cessation interventions may lead to considerable health benefits for patients

receiving methadone maintenance treatment, and many such patients are interested in stopping

smoking. Some studies suggest that smoking cessation is difficult to achieve or sustain for many of

these patients, and at present few methadone treatment programs offer smoking cessation

treatment (Nahvi et al. 2006; Richter et al. 2004).

PAIN MANAGEMENT DURING OPIOID AGONIST MAINTENANCE

TREATMENT

Pain is an important clinical problem among patients receiving methadone maintenance treatment,

and appropriate management and treatment of pain is essential for optimal care. A recent survey of

patients receiving methadone maintenance treatment in two methadone programs found that 37%

of patients experienced chronic pain (i.e., lasting 6 months or longer) of moderate or greater

severity, most often involving the musculoskeletal system (back or leg pain) or headache.

Two-thirds of these patients reported that pain interfered substantially with their functioning, and

many reported using illicit drugs to treat pain during the preceding 3 months (Rosenblum et al.

2003). In one study, opioid-dependent patients with chronic pain at entry into methadone

maintenance treatment had comparable retention and drug use outcomes as patients without

chronic pain, but they continued to have problems with pain and worse psychological functioning,

compared with patients without chronic pain, even after 1 year of methadone maintenance

treatment (Ilgen et al. 2006).

Treatment of acute or chronic pain among patients receiving methadone maintenance treatment is

complicated by the difficulties, common to both opioid-dependent patients and patients without any

history of drug abuse, of assessing pain severity objectively, diagnosing underlying etiologies of

painful conditions, and prescribing optimal treatment regimens that reduce pain and improve

patient functioning and well-being with the fewest adverse effects. These difficulties are further

complicated in patients receiving methadone maintenance treatment by the effects of methadone

maintenance on pain sensitivity and tolerance to opioid analgesia as well as by concerns about the

potential abuse liability of opioids prescribed for analgesia to patients with a history of drug abuse.

Because methadone is used for the treatment of chronic pain, some physicians mistakenly assume

that patients receiving methadone maintenance treatment do not require opioid analgesicPrint: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

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medications in addition to their daily methadone dose to treat either acute or chronic painful

conditions. To the contrary, such patients develop tolerance to the analgesic effects of their daily

dose and may also become cross-tolerant to the analgesic effects of morphine or other opioids

administered for pain relief (Athanasos et al. 2006). Additionally, acute or chronic opioid

administration may lead to increased sensitivity to pain. Increased pain sensitivity has been found

in association with administration of heroin, morphine, methadone, and other opioids, possibly

through up-regulation of spinal dynorphin (Gardell et al. 2002), and has also been reported in

patients receiving methadone maintenance treatment (Compton et al. 2001).

Some physicians may be reluctant to prescribe opioid analgesics to patients receiving methadone

maintenance treatment because of concerns about precipitating relapse to illicit drug use.

Administration of opioid analgesics to these patients for the treatment of acute pain has not been

found to lead to relapse or even to the need for higher methadone doses after the painful condition

has resolved (Kantor et al. 1980). Recommendations for managing acute pain in a patient receiving

methadone maintenance treatment include continued provision of the patient’s regular daily

methadone dose and administration of additional analgesic medications, including non-opioid

analgesics or short-acting opioids, as clinically indicated (Alford et al. 2006; Mehta and Langford

2006). During methadone maintenance treatment, results of positron emission tomography studies

suggest that methadone occupies 19%–32% of the opioid receptor, leaving a substantial

proportion of unoccupied receptors available for analgesic response to opioid medications (Kling et

1. 2000). When opioid analgesics are required, patients receiving methadone maintenance

treatment may require even higher doses or more frequent administration of opioid analgesic

medications to ameliorate pain than do patients who are not opioid dependent or receiving

methadone maintenance treatment. In a recent study, patients receiving methadone maintenance

treatment undergoing liver transplantation needed higher doses of intraoperative and

postoperative opioid analgesia than did other liver transplant recipients (Weinrieb et al. 2004).

When opioid analgesics are required for such individuals, it is important to use only medications

that act as full (rather than partial) agonists at opioid receptors; administration of a partial agonist

(e.g., pentazocine or buprenorphine) may precipitate withdrawal.

PREGNANCY AND OPIOID DEPENDENCE

Opioid dependence during pregnancy has adverse health effects on the pregnant woman, fetus, and

neonate, resulting from a combination of direct drug effects, withdrawal, infections associated with

injection drug use and addiction, the detrimental effect of addiction on nutrition, and the possible

exposure to violence. Opiate withdrawal during pregnancy, especially when it occurs without

medical treatment or supervision, causes significant fetal stress and is associated with spontaneous

abortion and fetal demise (Archie 1998). Early studies found that methadone maintenance

treatment led to substantial reductions in opiate use and improvements in nutrition, health status,

and participation in prenatal care for heroin-dependent pregnant women and also to improved fetal

growth and perinatal outcomes in their offspring. These findings led to the recommendation to

provide comprehensive methadone treatment to heroin-dependent pregnant women, with services

including prenatal and obstetrical treatment, nutritional supplementation, and counseling in

addition to methadone maintenance medications (Kaltenbach et al. 1998).

Determination of the optimal methadone dose during pregnancy requires recognition of the effects

of pregnancy on methadone metabolism and disposition and careful balancing between the risks of

continued illicit opiate use, if the methadone dose is too low, and the risks of the neonatal

abstinence syndrome (NAS), which may be associated with higher methadone doses. Methadone

plasma elimination rate is increased and its plasma half-life is decreased substantially during

pregnancy, most likely as a result of increased volume of distribution and increased liver

metabolism and placental and fetal metabolism. Consequently, methadone doses may need to be

increased and administered more frequently (two or three times per day) during pregnancy in

order to prevent withdrawal and craving and to obtain optimal reductions of illicit opioid use. In

one study, mean methadone trough plasma levels were approximately 0.3 mg/L in pregnant

women who did not experience withdrawal symptoms and significantly lower (0.175 mg/L) inPrint: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

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pregnant women who did experience withdrawal symptoms, despite somewhat higher daily

methadone doses administered to women who experienced withdrawal (Drozdick et al. 2002).

Methadone doses of 50–150 mg, or occasionally even higher, and split dosing may be needed in

pregnant women who experience withdrawal symptoms, in order to achieve methadone trough

levels of 0.2–0.4 mg/L, which are likely to suppress withdrawal and reduce illicit opioid use.

Opiate dependence and opioid agonist maintenance treatment during pregnancy are both

associated with NAS. NAS is characterized by central nervous system irritability and disturbances of

gastrointestinal, respiratory, and autonomic nervous system function. Features of NAS may include

high-pitched crying, yawning, sneezing, tremors, increased muscle tone, feeding difficulties,

diarrhea, rapid respiratory rate or periods of apnea, and seizure (Kaltenbach et al. 1998). Findings

regarding the relationship between maternal methadone dose and the incidence of NAS have been

inconsistent, and continued heroin or other illicit opioid use among patients treated with lower

methadone doses may complicate analysis of the relationship. In one study, methadone dose and

heroin use during the pregnancy were both significantly correlated with NAS. Continuing heroin use

during pregnancy was found in 31% of the women; 68% of the neonates of women who continued

to use heroin during pregnancy required treatment for withdrawal, whereas 35% of the neonates

of women with no evidence of illicit opioid use required treatment. The correlation between

methadone dose and NAS remained significant, however, even when controlling for heroin use

(Dashe et al. 2002). In that study, approximately 12% of the neonates born to mothers who were

treated with less than 20 mg/day of methadone required treatment for withdrawal, whereas 90%

of those born to mothers receiving 40 mg/day or more of methadone required treatment. A more

recent study found that approximately half of the neonates born to mothers treated with

methadone doses greater than 100 mg/day, and a comparable proportion of those born to mothers

treated with less than this daily dose, required treatment for NAS (McCarthy et al. 2005). In this

study, pregnant women were maintained at a full range of dosages (14–190 mg/day), titrated to

prevent craving and withdrawal. Illicit opioid or other drug use was relatively low during

treatment; 18% of the newborns tested positive for illicit drugs at delivery. Higher maternal

methadone doses, although not associated with NAS, were associated with less illicit drug use.

Differences among studies in the symptom thresholds for initiating treatment and differences in the

rates of continuing illicit opioid use may account for differences in the rates of neonates needing

treatment for withdrawal.

Methadone is secreted into breast milk, and it is estimated that breastfed infants may absorb

approximately 2%–3% of the maternal methadone dose (Begg et al. 2001). There is some

controversy regarding the risks and benefits of women breastfeeding during methadone treatment.

The “Patient Information” section on methadone published by the U.S. Food and Drug

Administration states that methadone “passes through your breast milk and may harm your baby”

(U. S. Food and Drug Administration 2007). The advisory sheet regarding maintenance treatment

for pregnant women published by the Substance Abuse and Mental Health Service Administration,

however, reaffirms earlier guidelines (Center for Substance Abuse Treatment 2005) that in most

situations the benefits of breastfeeding outweigh the potential risks of the small amounts of

methadone contained in breast milk (SAMHSA 2007). The risks to the baby are likely to be greatest

if very high dosages of methadone are prescribed for pain management or the baby was not

exposed to methadone in utero and has not developed tolerance to it. Despite the overall favorable

safety and efficacy profile of methadone maintenance during pregnancy and after childbirth, illicit

or harmful substance use (including abuse of opioids, cocaine, benzodiazepines, marijuana,

cigarettes, and alcohol) during methadone maintenance treatment may reduce some of the

beneficial effects of methadone maintenance treatment during pregnancy or after childbirth on

maternal health and well-being as well as on fetal growth, perinatal outcome, and child

development. These considerations have led to some calls for a reappraisal of the role of

methadone maintenance treatment during pregnancy (Brown et al. 1998), but high rates of

continued illicit opioid use in some studies may reflect less than optimal methadone dosing.

Carefully supervised medical withdrawal of an opioid-dependent pregnant woman may be

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opioids without maintenance treatment (e.g., women treated in residential programs) or when

opioid agonist maintenance treatment is not available. Some studies suggest that opiate

detoxification can be performed safely during pregnancy under careful medical supervision (Dashe

et al. 1998, 2002). Of course, withdrawal during pregnancy reduces the likelihood of neonatal

abstinence and other perinatal complications only if the pregnant woman remains abstinent

following completion of withdrawal and adheres to other medical and nutritional recommendations.

FEDERAL RULES GOVERNING OPIOID AGONIST MAINTENANCE

TREATMENT

Many aspects of opioid agonist maintenance treatment, including patient eligibility criteria,

medications that can be used for opioid agonist maintenance treatment, medication dispensing, and

program guidelines, are tightly regulated by federal and state rules and guidelines. Although

physicians may prescribe opioids for analgesia according to the usual guidelines for prescribing

controlled substances, methadone may only be dispensed for opioid detoxification or maintenance

treatment in accordance with federal and state regulations. With the exception of patients

hospitalized for conditions other than opioid dependence or during emergency periods of up to 3

days pending admission for more definitive treatment of addiction, methadone may only be

dispensed for opioid detoxification or maintenance treatment by opioid treatment programs that

have been certified by the Substance Abuse and Mental Health Services Administration and

approved by the appropriate state agency. The regulations are designed to ensure appropriate use

of this treatment modality, maintain effectiveness by encouraging optimal treatment and program

structure, and limit diversion of prescribed medications to illicit use. Recent revisions in federal

regulations regarding maintenance treatment with methadone have introduced quality assurance

monitoring and program certification requirements and also have made changes in the provisions

for take-home medications (U.S. Department of Health and Human Services 2001). The current

regulations define the required administrative and organizational structure of the program,

including the need for a medical director, and require the availability of counseling and medical

services and referral for other service needs. Eligibility for maintenance treatment with methadone

generally remains restricted to individuals ages 18 years or older who have been dependent on

opioids for a minimum of 1 year before admission. The 1-year history of dependence may be waived

for pregnant or previously treated patients or following prison release. Individuals younger than

age 18 years may be admitted if they have a history of repeated treatment failure (two or more

documented attempts at short-term detoxification or drug-free treatment within past 12 months);

parent or guardian consent is required for individuals younger than age 18 years. Depending on

their response to treatment, patients may receive up to a 6-day supply of take-home medications

by the end of the first year in treatment, up to a 2-week supply after 1 year in treatment, and a

maximum of a 1-month supply after 2 years in treatment.

An amendment to the Controlled Substances Act (Drug Addiction Treatment Act of 2000) enables

qualified physicians meeting defined training and certification criteria to prescribe office-based

opioid agonist detoxification or maintenance treatment using Schedule III, IV, or V medications

that have been approved for these indications by the FDA. In October 2002, buprenorphine became

the first Schedule III narcotic to be approved for these indications (Drug Enforcement

Administration 2002) and is now available through office-based prescription by physicians. The

current regulations governing narcotic treatment programs also permit office-based physicians to

become part of the medical staff of a narcotic treatment program or to obtain a license as a

satellite medication dispensing unit and thereby provide a form of office-based prescription of

methadone maintenance treatment. Individual physicians also may obtain a special narcotic

treatment program license, but the requirements for obtaining the license and operating as a

narcotic treatment program are considered too cumbersome by many physicians to make use of

this mechanism.

OFFICE-BASED OPIOID AGONIST MAINTENANCE TREATMENT

Historically, opioid agonist maintenance treatment in the United States was provided almost

entirely to patients enrolled in licensed narcotic treatment programs, whereas physicianPrint: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

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office-based treatment is widely available in Canada, England, France, and other countries. Despite

the laudable goals of restricting opioid agonist maintenance treatment to specially licensed narcotic

treatment programs (e.g., facilitating quality improvement goals and adherence to patient

eligibility criteria and decreasing the likelihood of diversion of prescribed opioid agonist

medications to illicit use), the restriction contributes to the lack of availability and difficulties in

gaining access to this treatment. Recent studies suggest that some opioid-dependent individuals

refrain from enrolling in narcotic treatment programs because of concerns about being recognized

by others in the program and identified as an addicted person and the possibility that this might

jeopardize his or her employment, family, or social situation. Additionally, some patients who have

achieved sustained recovery from illicit drug use during opioid agonist maintenance treatment

indicate a strong preference for “medical maintenance” by an office-based physician in order to

move away from continuing contact in clinics with many active drug users, to reduce the perceived

stigma of continuing attendance in a narcotic treatment program, and to gain greater flexibility in

prescribing and dispensing procedures (Fiellin et al. 2001).

The effectiveness of medical maintenance for stable patients receiving methadone maintenance

treatment has been evaluated in several studies, and many patients who have been abstinent from

illicit drugs for prolonged periods are able to make the transition to medical maintenance

successfully (Fiellin et al. 2001; King et al. 2002) and remain stable in medical maintenance for

prolonged periods (Harris et al. 2006; King et al. 2006; Merrill et al. 2005). One of the main

limitations noted in most of the studies is that only a small proportion of patients in methadone

maintenance treatment programs meet the stability criteria for medical maintenance, suggesting

that this approach will lead to only a modest increase in treatment capacity by freeing up treatment

slots in narcotic treatment programs (Fiellin et al. 2001; Rich et al. 2005). In one study that used

hair toxicology testing, a surprisingly high prevalence of previously undetected, recent illicit drug

use was found among patients meeting clinical criteria for medical maintenance (Fiellin et al.

2001). Patients with recent illicit drug use were substantially more likely than documented

abstinent patients to use illicit drugs in the next 6 months, but the likelihood of illicit drug use did

not differ between patients randomly assigned to medical maintenance in a physician’s office and

patients receiving continued treatment in the narcotic treatment program.

Qualified physicians who obtain special Drug Enforcement Administration registrations can now

provide office-based buprenorphine maintenance treatment for new admissions to maintenance

treatment, but relatively few studies have evaluated this setting and approach in the United States.

The initial studies of buprenorphine maintenance in a primary care clinic support the feasibility and

potential efficacy of this approach and suggest that many patients may benefit from

physician-prescribed buprenorphine maintenance and relatively brief weekly nurse-administered

counseling (Fiellin et al. 2006). Adherence to buprenorphine was quite variable, however, and

better adherence was associated with greater reductions in illicit drug use and retention in

treatment. The success of this approach for office-based opioid agonist maintenance treatment

raises important questions about the feasibility and potential efficacy of providing methadone

maintenance in these settings, although the potential abuse and diversion liability of methadone

limits dispensing options. As we enter an era of expanded access to opioid agonist maintenance

treatment and approval of new medications, settings, and dispensing options for this treatment, it

will be essential to evaluate the counseling requirements and the treatment protocols and

treatment algorithms that lead to optimal outcomes for patients (Kakko et al. 2007).

METHADONE MAINTENANCE TREATMENT IN PRISONS AND JAILS

The prevalence of opioid dependence and other substance use disorders among individuals

incarcerated in prisons or jails is substantially higher than in the general population in the United

States and throughout the world (Fazel et al. 2006). Additionally, although methadone

maintenance treatment reduces criminal activity, patients receiving methadone maintenance

treatment who become incarcerated experience significant difficulties. Surveys of jails indicate that

only about 1 in 4 contact the methadone program to verify the patient’s dose; very few continue

methadone maintenance while the patient is in jail; and many do not provide any efficaciousPrint: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

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medical treatment to manage withdrawal (Fiscella et al. 2004a, 2004b). Despite the high risk of

relapse to heroin after incarceration, the surveys also suggest that few prisons or jails refer

inmates at the time of release for drug abuse treatment. Methadone maintenance treatment during

incarceration may improve postrelease entry and retention in community-based methadone

treatment programs and possibly lower reincarceration rates (Magura et al. 1993). Additionally,

despite efforts to prevent drug use during incarceration, drug use and injection drug use may

occur. The potential for HIV or hepatitis C or B transmission associated with injection drug use in

prisons or jails is particularly high, because inmates may share needles and injection equipment in

an attempt to minimize the risk of being detected for possessing injection equipment (Calzavara et

1. 2003; Macalino et al. 2004; Zamani et al. 2006). The potential benefits of methadone

maintenance treatment during incarceration for reducing the risks both during periods of

incarceration and after release have led to the development of methadone treatment programs in

prisons in a number of countries. In one randomized clinical trial of methadone maintenance in

prison, heroin use and HIV and hepatitis C risk behaviors were significantly reduced in prison

inmates assigned to methadone maintenance treatment in prison compared with a waiting list

control (Dolan et al. 2003). The costs of providing methadone maintenance in prison and its

cost-effectiveness were comparable with the costs and cost-effectiveness of methadone

maintenance in community programs (Warren et al. 2006).

KEY POINTS

More than 40 years of clinical research and clinical experience with methadone maintenance treatment have

established the efficacy and effectiveness of this treatment for reducing illicit opioid use and for reducing the

mortality and morbidity associated with opioid dependence. Based on a thorough and critical review of the

literature, a recent Institute of Medicine committee concluded that the scientific evidence supports the

effectiveness of methadone maintenance treatment for reducing heroin and other illicit opioid use, retaining

patients in treatment, and reducing criminal activity, mortality, drug-related HIV risk behaviors, and the risk

of HIV transmission associated with heroin dependence (Institute of Medicine Committee on the Prevention of

HIV Infection among Injecting Drug Users in High Risk Countries 2006).

Critical factors determining the effectiveness of methadone maintenance treatment include treatment

duration, methadone dose, and provision of counseling and other services. The Institute of Medicine

committee also concluded that longer-term maintenance treatment is more effective than shorter-term

treatment and that the effectiveness of methadone maintenance is improved when sufficient daily methadone

dosages are provided and when patients receiving methadone maintenance treatment are provided drug

counseling and ancillary vocational, medical, or other needed services.

Clinical challenges during methadone maintenance treatment include co-occurring other substance use and

psychiatric or medical disorders. These co-occurring disorders respond to specific treatments, and treatment

for co-occurring disorders is facilitated by integrating or coordinating it with methadone maintenance

treatment.

From a public health standpoint, the most important challenge is to improve the availability and accessibility

of methadone or other opioid agonist maintenance treatment so that all heroin- or other opioid–dependent

patients can receive this treatment for as long as needed.

REFERENCES

Addiction Treatment Forum: Is methadone safe during pregnancy and breastfeeding? Addiction

Treatment Forum 16:6, 2007

Alford DP, Compton P, Samet JH: Acute pain management for patients receiving maintenance

methadone or buprenorphine therapy. Ann Intern Med 144:127–134, 2006 [PubMed]

Alterman AI, Rutherford MJ, Cacciola JS, et al: Response to methadone maintenance and counseling

in antisocial patients with and without major depression. J Nerv Ment Dis 184:695–702, 1996

[PubMed]

Anglin MD, Speckart GR, Booth MW, et al: Consequences and costs of shutting off methadone.Print: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

19 of 26

18/10/2008 10:21

Addict Behav 14:307–326, 1989 [PubMed]

Archie C: Methadone in the management of narcotic addiction in pregnancy. Obstet Gynecol

10:435–440, 1998 [PubMed]

Ashwath ML, Ajjan M, Culclasure T: Methadone-induced bradycardia. J Emerg Med 29:73–75, 2005

[PubMed]

Athanasos P, Smith CS, White JM, et al: Methadone maintenance patients are cross-tolerant to the

antinociceptive effects of very high plasma morphine concentrations. Pain 120:267–275, 2006

[PubMed]

Avants SK, Margolin A, Kosten TR, et al: When is less treatment better? The role of social anxiety in

matching methadone patients to psychosocial treatments. J Consult Clin Psychol 66:924–931, 1998

[PubMed]

Avants SK, Margolin A, Sindelar JL, et al: Day treatment versus enhanced standard methadone

services for opioid-dependent patients: a comparison of clinical efficacy and cost. Am J Psychiatry

156:27–33, 1999 [Full Text] [PubMed]

Bach PB, Lantos J: Methadone dosing, heroin affordability, and the severity of addiction. Am J

Public Health 89:662–665, 1999 [PubMed]

Ball JC, Ross A: The Effectiveness of Methadone Maintenance Treatment. New York,

Springer-Verlag, 1991

Begg EJ, Malpas TJ, Hackett LP, et al: Distribution of R- and S-methadone into human milk during

multiple, medium to high oral dosing. Br J Clin Pharmacol 52:681–685, 2001 [PubMed]

Begre S, von Bardeleben U, Ladewig D, et al: Paroxetine increases steady-state concentrations of

(R)-methadone in CYP2D6 extensive but not poor metabolizers. J Clin Psychopharmacol

22:211–215, 2002 [PubMed]

Brooner RK, King VL, Kidorf M, et al: Psychiatric and substance use comorbidity among

treatment-seeking opioid abusers. Arch Gen Psychiatry 54:71–80, 1997 [PubMed]

Brooner RK, Kidorf MS, King VL, et al: Comparing adaptive stepped care and monetary-based

voucher interventions for opioid dependence. Drug Alcohol Depend 88(suppl):S14–S23, 2007

Brown HL, Britton KA, Mahaffey D, et al: Methadone maintenance in pregnancy: a reappraisal. Am J

Obstet Gynecol 179:459–463, 1998 [PubMed]

Brown R, Balousek S, Mundt M, et al: Methadone maintenance and male sexual dysfunction. J

Addict Dis 24:91–106, 2005 [PubMed]

Buster MC, van Brussel GH, van den Brink W: An increase in overdose mortality during the first 2

weeks after entering or re-entering methadone treatment in Amsterdam. Addiction 97:993–1001,

2002 [PubMed]

Calsyn DA, Malcy JA, Saxon AJ: Slow tapering from methadone maintenance in a program

encouraging indefinite maintenance. J Subst Abuse Treat 30:159–163, 2006 [PubMed]

Calzavara LM, Burchell AN, Schlossberg J, et al.: Prior opiate injection and incarceration history

predict injection drug use among inmates. Addiction 98:1257–1265, 2003 [PubMed]

Center for Substance Abuse Treatment: Medication-Assisted Treatment for Opioid Addiction in

Opioid Treatment Programs. TIP Series #43 (DHHS Publ No SMA-05-4048). Rockville, MD, Center

for Substance Abuse Treatment, 2005

Clark N, Lintzeris N, Gijsbers A, et al: LAAM maintenance vs methadone maintenance for heroin

dependence. Cochrane Database of Systematic Reviews, Issue 2, Article No:CD002210, 2002

Compton P, Charuvastra VC, Ling W: Pain intolerance in opioid-maintained former opiate addicts:Print: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

20 of 26

18/10/2008 10:21

effect of long-acting maintenance agent. Drug Alcohol Depend 63:139–146, 2001 [PubMed]

Corkery JM, Schifano F, Ghodse AH, et al: The effects of methadone and its role in fatalities. Hum

Psychopharmacol 19:565–576, 2004 [PubMed]

Crettol S, Deglon JJ, Besson J, et al: ABCB1 and cytochrome P450 genotypes and phenotypes:

influence on methadone plasma levels and response to treatment. Clin Pharmacol Ther 80:668–681,

2006 [PubMed]

Curran HV, Kleckham J, Bearn J, et al: Effects of methadone on cognition, mood and craving in

detoxifying opiate addicts: a dose-response study. Psychopharmacology 154:153–160, 2001

[PubMed]

Darke S, Swift W, Hall W, et al: Drug use, HIV risk-taking and psychosocial correlates of

benzodiazepine use among methadone maintenance clients. Drug Alcohol Depend 34:67–70, 1993

Dashe JS, Jackson GL, Olscher DA, et al: Opioid detoxification in pregnancy. Obstet Gynecol

92:854–858, 1998 [PubMed]

Dashe JS, Sheffield JS, Olscher DA, et al: Relationship between maternal methadone dosage and

neonatal withdrawal. Obstet Gynecol 100:1244–1249, 2002 [PubMed]

D’Aunno T, Pollack HA: Changes in methadone treatment practices: results from a national panel

study, 1988–2000. JAMA 288:850–856, 2002 [PubMed]

Deamer RL, Wilson DR, Clark DS, et al: Torsades de pointes associated with high dose levomethadyl

acetate (ORLAAM). J Addict Dis 20:7–14, 2001 [PubMed]

Deck D, Carlson MJ: Retention in publicly funded methadone maintenance treatment in two

Western States. J Behav Health Serv Res 32:43–60, 2005 [PubMed]

Deck DD, Wiitala WL, Laws KE: Medicaid coverage and access to publicly funded opiate treatment. J

Behav Health Serv Res 33:324–334, 2006 [PubMed]

Dolan KA, Shearer J, MacDonald M, et al: A randomised controlled trial of methadone maintenance

treatment versus wait list control in an Australian prison system. Drug Alcohol Depend 72:59–65,

2003 [PubMed]

Donny EC, Walsh SL, Bigelow GE, et al: High-dose methadone produces superior opioid blockade

and comparable withdrawal suppression to lower doses in opioid-dependent humans.

Psychopharmacology 161:202–212, 2002 [PubMed]

Donny EC, Brasser SM, Bigelow GE, et al: Methadone doses of 100 mg or greater are more effective

than lower doses at suppressing heroin self-administration in opioid-dependent volunteers.

Addiction 100:1496–1509, 2005 [PubMed]

Drozdick J 3rd, Berghella V, Hill M, et al: Methadone trough levels in pregnancy. Am J Obstet

Gynecol 187:1184–1188, 2002 [PubMed]

Drug Addiction Treatment Act of 2000, Public Law 106–310, 106th Cong. (October 17, 2000)

Drug Enforcement Administration: 21 CFR part 1308. Schedules of Controlled Substances:

Rescheduling of Buprenorphine From Schedule V to Schedule III (2002). Federal Register 67, no.

194 (October 7, 2002): 62354–62370

Dyer KR, Foster DJ, White JM, et al: Steady-state pharmacokinetics and pharmacodynamics in

methadone maintenance patients: comparison of those who do and do not experience withdrawal

and concentration-effect relationships. Clin Pharmacol Ther 65:685–694, 1999 [PubMed]

Dyer KR, White JM, Foster DJ, et al: The relationship between mood state and plasma methadone

concentration in maintenance patients. J Clin Psychopharmacol 21:78–84, 2001 [PubMed]

Eap CB, Broly F, Mino A, et al: Cytochrome P450 2D6 genotype and methadone steady-statePrint: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

21 of 26

18/10/2008 10:21

concentrations. J Clin Psychopharmacol 21:229–234, 2001 [PubMed]

Eich-Höchli D, Oppliger R, Golay KP, et al: Methadone maintenance treatment and St. John’s Wort: a

case report. Pharmacopsychiatry 36:35–37, 2003 [PubMed]

Fairbank JA, Dunteman GH, Condelli WS: Do methadone patients substitute other drugs for heroin?

Predicting substance use at 1-year follow-up. Am J Drug Alcohol Abuse 19:465–474, 1993

[PubMed]

Fazel S, Bains P, Doll H: Substance abuse and dependence in prisoners: a systematic review.

Addiction 101:181–191, 2006 [PubMed]

Fiellin DA, O’Connor PG, Chawarski M, et al: Methadone maintenance in primary care: a randomized

controlled trial. JAMA 286:1724–1731, 2001 [PubMed]

Fiellin DA, Pantalon MV, Chawarski MC, et al: Counseling plus buprenorphine-naloxone maintenance

therapy for opioid dependence. N Engl J Med 355:365–374, 2006 [PubMed]

Fiscella K, Moore A, Engerman J, et al: Jail management of arrestees/inmates enrolled in

community methadone maintenance programs. J Urban Health 81:645–654, 2004a

Fiscella K, Pless N, Meldrum S, et al: Alcohol and opiate withdrawal in US jails. Am J Public Health

94:1522–1524, 2004b

Fishbain DA, Cutler RB, Rosomoff HL, et al: Are opioid-dependent/tolerant patients impaired in

driving-related skills? A structured evidence-based review. J Pain Symptom Manage 25:559–577,

2003 [PubMed]

Foster DJ, Somogyi AA, Dyer KR, et al: Steady-state pharmacokinetics of (R)- and (S)-methadone in

methadone maintenance patients. Br J Clin Pharmacol 50:427–440, 2001

Gardell LR, Wang R, Burgess SE, et al: Sustained morphine exposure induces a spinal

dynorphin-dependent enhancement of excitatory transmitter release from primary afferent fibers. J

Neurosci 22:6747–6755, 2002 [PubMed]

George TP, Chawarski MC, Pakes J, et al: Disulfiram versus placebo for cocaine dependence in

buprenorphine-maintained subjects: a preliminary trial. Biol Psychiatry 47:1080–1086, 2000

[PubMed]

Greenwald MK: Heroin craving and drug use in opioid-maintained volunteers: effects of methadone

dose variations. Exp Clin Psychopharmacol 10:39–46, 2002 [PubMed]

Greenwald MK: Effects of opioid dependence and tobacco use on ventilatory response to

progressive hypercapnia. Pharmacol Biochem Behav 77:39–47, 2004 [PubMed]

Gruber SA, Tzilos GK, Silveri MM, et al: Methadone maintenance improves cognitive performance

after two months of treatment. Exp Clin Psychopharmacol 14:157–164, 2006 [PubMed]

Gunne LM, Gronbladh L, Ohlund LS: Treatment characteristics and retention in methadone

maintenance: high and stable retention rates in a Swedish two-phase programme. Heroin Addiction

and Related Clinical Problems 4:437–446, 2002

Gutstein HB, Akil H: Opioid analgesics, in Goodman and Gilman’s The Pharmacological Basis of

Therapeutics. Edited by Hardman JG, Limbird LL. New York, McGraw-Hill, 2001, pp 569–619

Harris KA Jr, Arnsten JH, Joseph H, et al: A 5-year evaluation of a methadone medical maintenance

program. J Subst Abuse Treat 31:433–438, 2006 [PubMed]

Hartgers C, van den Hoek A, Krijnen P, et al: HIV prevalence and risk behavior among injecting

drug users who participate in “low-threshold” methadone programs in Amsterdam. Am J Public

Health 82:547–551, 1992 [PubMed]

Herrlin K, Segerdahl M, Gustafsson LL, et al: Methadone, ciprofloxacin, and adverse drug reactions.Print: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

22 of 26

18/10/2008 10:21

Lancet 356:2069–2070, 2000 [PubMed]

Hser YI, Hoffman V, Grella CE, et al: A 33-year follow-up of narcotics addicts. Arch Gen Psychiatry

58:503–508, 2001 [PubMed]

Hubbard RL, Craddock SG, Flynn PM, et al: Overview of 1-year follow-up outcomes in Drug Abuse

Treatment Outcome Study (DATOS). Psychol Addict Behav 11:261–278, 1997

Ilgen MA, Trafton JA, Humphreys K: Response to methadone maintenance treatment of opiate

dependent patients with and without significant pain. Drug Alcohol Depend 82:187–193, 2006

[PubMed]

Institute of Medicine Committee on the Prevention of HIV Infection among Injecting Drug Users in

High Risk Countries: Preventing HIV Infection among Injecting Drug Users in High Risk Countries.

Washington, DC, The National Academies Press, 2006

Johnson RE, Chutuape MA, Strain EC, et al: A comparison of levomethadyl acetate, buprenorphine,

and methadone for opioid dependence. N Engl J Med 343:1290–1297, 2000 [PubMed]

Justo D, Gal-Oz A, Paran Y, et al: Methadone-associated torsades de pointes (polymorphic

ventricular tachycardia) in opioid-dependent patients. Addiction 101:1333–1338, 2006 [PubMed]

Kakko J, Gronbladh L, Svanborg KD, et al: A stepped care strategy using buprenorphine and

methadone versus conventional methadone maintenance in heroin dependence: a randomized

controlled trial. Am J Psychiatry 164:797–803, 2007 [Full Text] [PubMed]

Kaltenbach K, Berghella V, Finnegan L: Opioid dependence during pregnancy: effects and

management. Obstet Gynecol Clin North Am 25:139–151, 1998 [PubMed]

Kantor TG, Cantor R, Tom E: A study of hospitalized surgical patients on methadone maintenance.

Drug Alcohol Depend 6:163–173, 1980 [PubMed]

Kim TW, Alford DP, Malabanan A, et al: Low bone density in patients receiving methadone

maintenance treatment. Drug Alcohol Depend 85:258–262, 2006 [PubMed]

King VL, Stoller KB, Hayes M, et al: A multicenter randomized evaluation of methadone medical

maintenance. Drug Alcohol Depend 65:137–148, 2002 [PubMed]

King VL, Kidorf MS, Stoller KB, et al: A 12-month controlled trial of methadone medical maintenance

integrated into an adaptive treatment model. J Subst Abuse Treat 31:385–393, 2006 [PubMed]

Kling MA, Carson RE, Borg L, et al: Opioid receptor imaging with positron emission tomography and

[18F]cyclofoxy in long-term, methadone-treated former heroin addicts. J Pharm Exp Ther

295:1070–1076, 2000 [PubMed]

Krantz MJ, Lewkowiez L, Hays H, et al: Torsades de pointes associated with very-high-dose

methadone. Ann Intern Med 137:501–504, 2002 [PubMed]

Kreek MJ: Methadone-related opioid agonist pharmacotherapy for heroin addiction: history, recent

molecular and neurochemical research and future in mainstream medicine. Ann NY Acad Sci

909:186–216, 2000 [PubMed]

Kreek MJ, Koob GF: Drug dependence: stress and dysregulation of brain reward pathways. Drug

Alcohol Depend 51:23–47, 1998 [PubMed]

Leri F, Zhou Y, Goddard B, et al: Effects of high-dose methadone maintenance on cocaine place

conditioning, cocaine self-administration, and mu-opioid receptor mRNA expression in the rat brain.

Neuropsychopharmacology 31:1462–1474, 2006 [PubMed]

Litwin AH, Soloway I, Gourevitch MN: Integrating services for injection drug users infected with

hepatitis C virus with methadone maintenance treatment: challenges and opportunities. Clin Infect

Dis 40(suppl):S339–S345, 2005Print: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

23 of 26

18/10/2008 10:21

Macalino GE, Vlahov D, Sanford-Colby S, et al: Prevalence and incidence of HIV, hepatitis B virus,

and hepatitis C virus infections among males in Rhode Island prisons. [Erratum appears in Am J

Public Health 94:1847, 2004]. Am J Public Health 94:1218–1223, 2004 [PubMed]

Magura S, Rosenblum A, Lewis C, et al: The effectiveness of in-jail methadone maintenance. J Drug

Issues 23:75–99, 1993

Maremmani I, Pacini M, Cesaroni C, et al: QTc interval prolongation in patients on long-term

methadone maintenance therapy. Eur Addict Res 11:44–49, 2005 [PubMed]

Mattick RP, Kimber J, Breen C, et al: Buprenorphine maintenance versus placebo or methadone

maintenance for opioid dependence. Cochrane Database of Systematic Reviews, Issue 3, Article

No:CD002207, 2004

Mauss S, Berger F, Goelz J, et al: A prospective controlled study of interferon-based therapy of

chronic hepatitis C in patients on methadone maintenance. Hepatology 40:120–124, 2004

[PubMed]

McCarthy JJ, Leamon MH, Parr MS, et al: High-dose methadone maintenance in pregnancy:

maternal and neonatal outcomes. Am J Obstet Gynecol 193:606–610, 2005 [PubMed]

McLellan AT, Arndt IO, Metzger DS, et al: The effects of psychosocial services in substance abuse

treatment. JAMA 269:1953–1959, 1993 [PubMed]

McRae AL, Sonne SC, Brady KT, et al: A randomized, placebo-controlled trial of buspirone for the

treatment of anxiety in opioid-dependent individuals. Am J Addict 13:53–63, 2004 [PubMed]

Mehta V, Langford RM: Acute pain management for opioid dependent patients. Anaesthesia

61:269–276, 2006 [PubMed]

Merrill JO, Jackson TR, Schulman BA, et al: Methadone medical maintenance in primary care: an

implementation evaluation. J Gen Intern Med 20:344–349, 2005 [PubMed]

Metzger DS, Woody GE, McLellan AT, et al: Human immunodeficiency virus seroconversion among

intravenous drug users in- and out-of-treatment: an 18-month prospective follow-up. J Acquir

Immune Defic Syndr 6:1049–1056, 1993 [PubMed]

Mitchell TB, Dyer KR, Newcombe D, et al: Subjective and physiological responses among

racemic-methadone maintenance patients in relation to relative (S)- vs. (R)-methadone exposure.

Br J Clin Pharmacol 58:609–617, 2004 [PubMed]

Murrill CS, Weeks H, Castrucci BC, et al: Age-specific seroprevalence of HIV, hepatitis B virus, and

hepatitis C virus infection among injection drug users admitted to drug treatment in 6 US cities. Am

J Public Health 92:385–387, 2002 [PubMed]

Nahvi S, Richter K, Li X, et al: Cigarette smoking and interest in quitting in methadone maintenance

patients. Addict Behav 31:2127–2134, 2006 [PubMed]

National Institute on Drug Abuse: Research Report: Heroin Abuse and Addiction (NIH Publ No

05-4105). Rockville, MD, National Institute on Drug Abuse, 2005

Neaigus A: Trends in the noninjected use of heroin and factors associated with the transition to

injecting, in Heroin in the Age of Crack Cocaine. Edited by Inciardi JA, Harrison LD. Thousand Oaks,

CA, Sage Publications, 1998, pp 131–159

Neff JA, Moody DE: Differential N-demethylation of L- -acetylmethadol (LAAM) and norLAAM by

cytochrome P450s 2B6, 2C18, and 3A4. Biochem Biophys Res Commun 284:751–756, 2001

[PubMed]

Nirenberg TD, Cellucci T, Liepman MR, et al: Cannabis versus other illicit drug use among

methadone maintenance patients. Psychol Addict Behav 10:222–227, 1996

Nunes EV, Quitkin FM, Donovan SJ, et al: Imipramine treatment of opiate-dependent patients withPrint: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

24 of 26

18/10/2008 10:21

depressive disorders: a placebo-controlled trial. Arch Gen Psychiatry 55:153–160, 1998 [PubMed]

Nunes EV, Sullivan MA, Levin FR: Treatment of depression in patients with opiate dependence. Biol

Psychiatry 56:793–802, 2004 [PubMed]

Pearson EC, Woosley RL: QT prolongation and torsades de pointes among methadone users: reports

to the FDA spontaneous reporting system. Pharmacoepidemiol Drug Saf 14:747–753, 2005

[PubMed]

Peles E, Bodner G, Kreek MJ, et al.: Corrected-QT intervals as related to methadone dose and serum

level in methadone maintenance treatment (MMT) patients: a cross sectional study. Addiction

102:289–300, 2006

Petrakis IL, Carroll KM, Nich C, et al: Disulfiram treatment for cocaine dependence in

methadone-maintained opioid addicts. Addiction 95:219–228, 2000 [PubMed]

Prosser J, Cohen LJ, Steinfeld M, et al: Neuropsychological functioning in opiate-dependent subjects

receiving and following methadone maintenance treatment. Drug Alcohol Depend 84:240–247,

2006 [PubMed]

Rainey PM: HIV drug interactions: the good, the bad, and the other. Ther Drug Monit 24:26–31,

2002 [PubMed]

Rich JD, Boutwell AE, Shield DC, et al: Attitudes and practices regarding the use of methadone in US

state and federal prisons. J Urban Health 82:411–419, 2005 [PubMed]

Richter KP, Choi WS, McCool RM, et al: Smoking cessation services in U.S. methadone maintenance

facilities. Psychiatr Serv 55:1258–1264, 2004 [Full Text] [PubMed]

Rosenblum A, Joseph H, Fong C, et al: Prevalence and characteristics of chronic pain among

chemically dependent patients in methadone maintenance and residential treatment facilities.

JAMA 289:2370–2378, 2003 [PubMed]

Rounsaville BJ, Weissman MM, Kleber H, et al: Heterogeneity of psychiatric diagnosis in treated

opiate addicts. Arch Gen Psychiatry 39:161–168, 1982 [PubMed]

Saxon AJ, Malte CA, Sloan KL, et al: Randomized trial of onsite versus referral primary medical care

for veterans in addictions treatment. Med Care 44:334–342, 2006 [PubMed]

Saxon AJ, Calsyn DA, Greenberg D, et al: Urine screening for marijuana among

methadone-maintained patients. Am J Addict 2:207–211, 1993

Schluger JH, Bart G, Green M, et al: Corticotropin-releasing factor testing reveals a dose-dependent

difference in methadone maintained vs control subjects. Neuropsychopharmacology 28:985–994,

2003 [PubMed]

Schottenfeld RS, Chawarski MC, Pakes J, et al: Methadone vs. buprenorphine with contingency

management or performance feedback for cocaine and opioid dependence. Am J Psychiatry

162:340–349, 2005 [Full Text] [PubMed]

Schwartz RP, Highfield DA, Jaffe JH, et al: A randomized controlled trial of interim methadone

maintenance. Arch Gen Psychiatry 63:102–109, 2006 [PubMed]

Schwartz RP, Jaffe JH, Highfield DA, et al: A randomized controlled trial of interim methadone

maintenance: 10-month follow-up. Drug Alcohol Depend 86:30–36, 2007 [PubMed]

Sees KL, Delucchi KL, Masson C, et al: Methadone maintenance vs 180-day psychosocially enriched

detoxification for treatment of opioid dependence: a randomized controlled trial. JAMA

283:1303–1310, 2000 [PubMed]

Sheerin IG, Green FT, Sellman JD: What is the cost-effectiveness of hepatitis C treatment for

injecting drug users on methadone maintenance in New Zealand? Drug Alcohol Rev 23:261–272,

2004 [PubMed]Print: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

25 of 26

18/10/2008 10:21

Spiga R, Huang DB, Meisch RA, et al: Human methadone self-administration: effects of diazepam

pretreatment. Exp Clin Psychopharmacol 9:40–46, 2001 [PubMed]

Stine SM, Kosten TR: Use of drug combinations in treatment of opioid withdrawal. J Clin

Psychopharmacol 12:203–209, 1992 [PubMed]

Stitzer ML, Griffiths RR, McLellan AT, et al: Diazepam use among methadone maintenance patients:

patterns and dosages. Drug Alcohol Depend 8:189–199, 1981 [PubMed]

Strain EC, Stitzer ML, Liebson IA, et al: Dose-response effects of methadone in the treatment of

opioid dependence. Ann Intern Med 119:23–27, 1993 [PubMed]

Strain EC, Bigelow GE, Liebson IA, et al: Moderate- vs high-dose methadone in the treatment of

opioid dependence: a randomized trial (see comments). JAMA 281:1000–1005, 1999 [PubMed]

Srivastava A, Kahan M: Methadone induction doses: are our current practices safe? J Addict Dis

25:5–13, 2006 [PubMed]

Substance Abuse and Mental Health Services Administration (SAMHSA): Results from the 2005

National Survey on Drug Use and Health: National Findings, Vol. NSDUH, Series H-30 (DHHS Publ

No SMA-06-4194). Rockville, MD, Substance Abuse and Mental Health Services Administration,

2006

Substance Abuse and Mental Health Services Administration (SAMHSA): Results from the 2006

National Survey on Drug Use and Health: National Findings, Vol. NSDUH, Series H-32 (DHHS Publ

No SMA-07-4293). Rockville, MD, Substance Abuse and Mental Health Services Administration,

2007

Sulkowski M, Wright T, Rossi S, et al: Peginterferon alfa-2a does not alter the pharmacokinetics of

methadone in patients with chronic hepatitis C undergoing methadone maintenance therapy. Clin

Pharmacol Ther 77:214–224, 2005 [PubMed]

U.S. Department of Health and Human Services Substances Abuse and Mental Health Services

Administration (USDHHS). Opioid drugs in maintenance and detoxification treatment of opioid

addiction. Federal Register 66(11):4076–4102, 2001

U.S. Food and Drug Administration: Patient information: Dolophine Hydrochloride CII (methadone

hydrochloride tablets), 5 mg and 10 mg. Available at

http://www.fda.gov/cder/drug/infopage/methadone/dolophine_PI.pdf. Accessed December 7,

2007.  

Vaillant GE: A 20-year follow-up of New York narcotic addicts. Arch Gen Psychiatry 29:237–241,

1973 [PubMed]

Warren E, Viney R, Shearer J, et al: Value for money in drug treatment: economic evaluation of

prison methadone. Drug Alcohol Depend 84:160–166, 2006 [PubMed]

Weinrieb RM, Barnett R, Lynch KG, et al: A matched comparison study of medical and psychiatric

complications and anesthesia and analgesia requirements in methadone-maintained liver

transplant recipients. Liver Transpl 10:97–106, 2004 [PubMed]

Weizman T, Gelkopf M, Melamed Y, et al: Treatment of benzodiazepine dependence in methadone

maintenance treatment patients: a comparison of two therapeutic modalities and the role of

psychiatric comorbidity. Aust NZ J Psychiatry 37:458–463, 2003 [PubMed]

Wines JD Jr, Weiss RD: Opioid withdrawal during risperidone treatment. J Clin Psychopharmacol

19:265–267, 1999 [PubMed]

Wolff K: Characterization of methadone overdose: clinical considerations and the scientific

evidence. Ther Drug Monit 24:457–470, 2002 [PubMed]

Wolff K, Rostami-Hodjegan A, Shires S, et al: The pharmacokinetics of methadone in healthyPrint: Chapter 20. Opioid Maintenance Treatment http://www.psychiatryonline.com/popup.aspx?aID=351951&print=yes…

26 of 26

18/10/2008 10:21

subjects and opiate users. Br J Clin Pharmacol 44:325–334, 1997 [PubMed]

Wolff K, Rostami-Hodjegan A, Hay AW, et al: Population-based pharmacokinetic approach for

methadone monitoring of opiate addicts: potential clinical utility. Addiction 95:1771–1783, 2000

[PubMed]

Yancovitz SR, Des Jarlais DC, Peyser NP, et al: A randomized trial of an interim methadone

maintenance clinic. Am J Public Health 81:1185–1191, 1991 [PubMed]

Zamani S, Kihara M, Gouya MM, et al: High prevalence of HIV infection associated with

incarceration among community-based injecting drug users in Tehran, Iran. J Acquir Immune Defic

Syndr 42:342–346, 2006 [PubMed]

SUGGESTED READING

Addiction Treatment Forum, includes newsletter with up-to-date information on methadone maintenance

treatment: http://www.atforum.com/index.shtml

Hser YI, Hoffman V, Grella CE, et al: A 33-year follow-up of narcotics addicts. Arch Gen Psychiatry

58:503–508, 2001

McLellan AT, Arndt IO, Metzger DS, et al: The effects of psychosocial services in substance abuse treatment.

JAMA 269:1953–1959, 1993

Schottenfeld RS, Chawarski MC, Pakes J, et al: Methadone vs. buprenorphine with contingency management or

performance feedback for cocaine and opioid dependence. Am J Psychiatry 162:340–349, 2005

Schwartz RP, Highfield DA, Jaffe JH, et al.: A randomized controlled trial of interim methadone maintenance.

Arch Gen Psychiatry 63:102–109, 2006

Sees KL, Delucchi KL, Masson C, et al: Methadone maintenance vs 180-day psychosocially enriched

detoxification for treatment of opioid dependence: a randomized controlled trial. JAMA 283:1303–1310, 2000

Treatment Improvement Protocols developed for the Center on Substance Abuse Treatment:

http://www.treatment.org/Externals/tips.html

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