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Buprenorphine maintenance versus placebo or methadone maintenance for opioid dependence

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Abstract

Background

Buprenorphine maintenance treatment has been evaluated in randomised controlled trials against placebo medication, and separately as an alternative to methadone for management of opioid dependence.

Objectives

To evaluate buprenorphine maintenance compared to placebo and to methadone maintenance in the management of opioid dependence, including its ability to retain people in treatment, suppress illicit drug use, reduce criminal activity, and mortality.

Search methods

We searched the following databases to January 2013: Cochrane Drugs and Alcohol Review Group Specialised Register, Cochrane Central Register of Controlled Trials, MEDLINE, EMBASE, Current Contents, PsycLIT, CORK, Alcohol and Drug Council of Australia, Australian Drug Foundation, Centre for Education and Information on Drugs and Alcohol, Library of Congress, reference lists of identified studies and reviews. We sought published/unpublished randomised controlled trials (RCTs) from authors.

Selection criteria

Randomised controlled trials of buprenorphine maintenance treatment versus placebo or methadone in management of opioid‐dependent persons.

Data collection and analysis

We used Cochrane Collaboration methodology.

Main results

We include 31 trials (5430 participants), the quality of evidence varied from high to moderate quality.

There is high quality of evidence that buprenorphine was superior to placebo medication in retention of participants in treatment at all doses examined. Specifically, buprenorphine retained participants better than placebo: at low doses (2 ‐ 6 mg), 5 studies, 1131 participants, risk ratio (RR) 1.50; 95% confidence interval (CI) 1.19 to 1.88; at medium doses (7 ‐ 15 mg), 4 studies, 887 participants, RR 1.74; 95% CI 1.06 to 2.87; and at high doses (≥ 16 mg), 5 studies, 1001 participants, RR 1.82; 95% CI 1.15 to 2.90. However, there is moderate quality of evidence that only high‐dose buprenorphine (≥ 16 mg) was more effective than placebo in suppressing illicit opioid use measured by urinanalysis in the trials, 3 studies, 729 participants, standardised mean difference (SMD) ‐1.17; 95% CI ‐1.85 to ‐0.49, Notably, low‐dose, (2 studies, 487 participants, SMD 0.10; 95% CI ‐0.80 to 1.01), and medium‐dose, (2 studies, 463 participants, SMD ‐0.08; 95% CI ‐0.78 to 0.62) buprenorphine did not suppress illicit opioid use measured by urinanalysis better than placebo.

There is high quality of evidence that buprenorphine in flexible doses adjusted to participant need,was less effective than methadone in retaining participants, 5 studies, 788 participants, RR 0.83; 95% CI 0.72 to 0.95. For those retained in treatment, no difference was observed in suppression of opioid use as measured by urinalysis, 8 studies, 1027 participants, SMD ‐0.11; 95% CI ‐0.23 to 0.02 or self report, 4 studies, 501 participants, SMD ‐0.11; 95% CI ‐0.28 to 0.07, with moderate quality of evidence.

Consistent with the results in the flexible‐dose studies, in low fixed‐dose studies, methadone (≤ 40 mg) was more likely to retain participants than low‐dose buprenorphine (2 ‐ 6 mg), (3 studies, 253 participants, RR 0.67; 95% CI: 0.52 to 0.87). However, we found contrary results at medium dose and high dose: there was no difference between medium‐dose buprenorphine (7 ‐ 15 mg) and medium‐dose methadone (40 ‐ 85 mg) in retention, (7 studies, 780 participants, RR 0.87; 95% CI 0.69 to 1.10) or in suppression of illicit opioid use as measured by urines, (4 studies, 476 participants, SMD 0.25; 95% CI ‐0.08 to 0.58) or self report of illicit opioid use, (2 studies, 174 participants, SMD ‐0.82; 95% CI ‐1.83 to 0.19). Similarly, there was no difference between high‐dose buprenorphine (≥ 16 mg) and high‐dose methadone (≥ 85 mg) in retention (RR 0.79; 95% CI 0.20 to 3.16) or suppression of self‐reported heroin use (SMD ‐0.73; 95% CI ‐1.08 to ‐0.37) (1 study, 134 participants).

Few studies reported adverse events ; two studies compared adverse events statistically, finding no difference between methadone and buprenorphine, except for a single result indicating more sedation among those using methadone.

Authors' conclusions

Buprenorphine is an effective medication in the maintenance treatment of heroin dependence, retaining people in treatment at any dose above 2 mg, and suppressing illicit opioid use (at doses 16 mg or greater) based on placebo‐controlled trials.

However, compared to methadone, buprenorphine retains fewer people when doses are flexibly delivered and at low fixed doses. If fixed medium or high doses are used, buprenorphine and methadone appear no different in effectiveness (retention in treatment and suppression of illicit opioid use); however, fixed doses are rarely used in clinical practice so the flexible dose results are more relevant to patient care. Methadone is superior to buprenorphine in retaining people in treatment, and methadone equally suppresses illicit opioid use.

PICOs

Population
Intervention
Comparison
Outcome

The PICO model is widely used and taught in evidence-based health care as a strategy for formulating questions and search strategies and for characterizing clinical studies or meta-analyses. PICO stands for four different potential components of a clinical question: Patient, Population or Problem; Intervention; Comparison; Outcome.

See more on using PICO in the Cochrane Handbook.

Plain language summary

Buprenorphine maintenance versus placebo or methadone maintenance for opioid dependence

Background

Methadone is widely used as a replacement for illicit opioid use such as heroin in medically‐supported opioid substitution maintenance programmes. Two other drugs have been used to help reduce illicit opioid use, specifically buprenorphine and LAAM (levo‐alpha‐acetylmethadol). LAAM is not used in current clinical practice. Buprenorphine is currently used and can reduce illicit opioid use compared with placebo, although it is less effective than methadone. Buprenorphine is an opioid drug that is not as potent as heroin and methadone, although the effects of buprenorphine may last longer. Buprenorphine can be taken once every two days. The trials include different formulations of buprenorphine: sublingual solution, sublingual tablets, combined buprenorphine/naloxone sublingual tablet and an implant.

Key results

The review of trials found that buprenorphine at high doses (16 mg) can reduce illicit opioid use effectively compared with placebo, and buprenorphine at any dose studied retains people in treatment better than placebo.

Buprenorphine appears to be less effective than methadone in retaining people in treatment, if prescribed in a flexible dose regimen or at a fixed and low dose (2 ‐ 6 mg per day). Buprenorphine prescribed at fixed doses (above 7 mg per day) was not different from methadone prescribed at fixed doses (40 mg or more per day) in retaining people in treatment or in suppression of illicit opioid use.

Authors' conclusions

Implications for practice

The implications of this review are clear for clinical practice. Despite the results showing that buprenorphine (especially at high doses) is an effective maintenance therapy for heroin dependence when compared with placebo, methadone maintenance treatment at flexible doses is better able to retain people in treatment. Both treatments suppress heroin use. Buprenorphine should be supported as a medication to use in substitution maintenance treatment, where higher doses of methadone cannot be administered or methadone is not tolerated, or simply to provide patient and clinician choice. Given buprenorphine's different pharmacological properties, it may have advantages in some settings and under some policies where its relative safety and alternate‐day administration are useful clinically compared to methadone.

Implications for research

There does not appear to be any need for further randomised control trials of the relative efficacy of methadone compared with buprenorphine. There does appear to be a need to undertake studies which will clarify factors responsible for retention in the first few weeks or months of treatment in buprenorphine versus methadone. One way of addressing this issue would be to compare a standard induction as used in some of the trials reported herein with a rapid induction onto buprenorphine, with the potential to have a further comparison of induction onto methadone. Problems in the methods of induction onto buprenorphine within the trials analysed might partly explain the inferiority of buprenorphine shown in this review. It would be ideal if such a trial were to be conducted under double‐blind conditions, particularly in terms of the rapid versus standard induction onto buprenorphine. Other outcome measures could be included in future studies, such as self‐reported drug use, criminal activity, physical health, and psychological health, which were too infrequently and irregularly reported in the literature analysed in the current review.

There is enough research evidence to show that buprenorphine in low, medium or high doses is more effective than placebo in retaining people in treatment, and in reducing heroin use at high doses. Future trials involving placebo (or indeed short‐term maintenance where people are terminated from treatment after a few weeks of intervention) should consider the ethical implications of providing substandard (i.e., placebo or short‐term treatment), given the strength of the available evidence.

Summary of findings

Open in table viewer
Summary of findings for the main comparison. Summary of findings: comparison between flexible‐dose methadone and buprenorphine

Buprenorphine maintenance compared with methadone maintenance for opioid dependence

Patient or population: People with opioid dependence.

Settings: Inpatient and outpatient

Intervention: Buprenorphine maintenance at flexible doses

Comparison: Methadone maintenance at flexible doses

Outcomes

Relative effect
(95% CI)

No of Participants
(studies)

Quality of the evidence
(GRADE)

Comments

Retention in treatment

RR 0.83

(0.73 to 0.95)*

11 (1391);

5 double‐blind (788)

6 open‐label (603)

⊕⊕⊕⊕
high

Greater retention in the methadone group.

* the heterogeneity is significant.

When the double‐blind studies are analysed separately the heterogeneity is not significant and the RR is 0.83 (0.72 to 0.95)

Morphine‐positive urines

SMD ‐0.11

(‐0.23 to 0.02)

8 (1027)

⊕⊕⊕⊝
moderate

No difference.

Self‐reported heroin use

SMD ‐0.11

(‐0.28 to 0.07)

4 (501)

⊕⊕⊕⊝
moderate

No difference.

Cocaine‐positive urines

SMD 0.10

(‐0.05 to 0.25)

6 (919)

⊕⊕⊕⊝
moderate

No difference.

Benzodiazepine‐positive urines

SMD 0.05

(‐0.09 to 0.18]

6 (859)

⊕⊕⊕⊝
moderate

No difference.

*The basis for the assumed risk (e.g. the median control group risk across studies) is provided in footnotes. The corresponding risk (and its 95% confidence interval) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI).
CI: Confidence interval; RR: Risk Ratio; SMD: standardised mean difference

GRADE Working Group grades of evidence
High quality: Further research is very unlikely to change our confidence in the estimate of effect.
Moderate quality: Further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate.
Low quality: Further research is very likely to have an important impact on our confidence in the estimate of effect and is likely to change the estimate.
Very low quality: We are very uncertain about the estimate.

Open in table viewer
Summary of findings 2. Summary of findings for the comparison between high‐dose buprenorphine and placebo

Buprenorphine maintenance compared with methadone maintenance for opioid dependence

Patient or population: People with opioid dependence.

Settings: Inpatient and outpatient

Intervention: Buprenorphine maintenance at high doses (16 mg)

Comparison: Placebo

Outcomes

Relative effect
(95% CI)

No of Participants
(studies)

Quality of the evidence
(GRADE)

Comments

Retention in treatment

RR 1.82

(1.15 to 2.90)

1001 (5)

⊕⊕⊕⊕
high

Greater retention in buprenorphine group.

Morphine‐positive urines

SMD ‐1.17

(‐1.85 to ‐0.49)

729 (3)

⊕⊕⊕⊝
moderate

Fewer morphine‐positive urines in buprenorphine group.

Benzodiazepine‐positive urines

SMD ‐1.65

(‐4.94 to 1.65)

336 (2)

⊕⊕⊕⊝
moderate

No difference.

*The basis for the assumed risk (e.g. the median control group risk across studies) is provided in footnotes. The corresponding risk (and its 95% confidence interval) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI).
CI: Confidence interval; RR: Risk Ratio; SMD: standardised mean difference

GRADE Working Group grades of evidence
High quality: Further research is very unlikely to change our confidence in the estimate of effect.
Moderate quality: Further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate.
Low quality: Further research is very likely to have an important impact on our confidence in the estimate of effect and is likely to change the estimate.
Very low quality: We are very uncertain about the estimate.

Background

Description of the condition

Opioids are a class of compounds that elicit analgesic effect by binding to opioid receptors within the central and peripheral nervous system. Opioids include natural opiates such as opium (from the poppy) and morphine, and natural derivatives or synthetic compounds such as heroin (diacetylmorphine), oxycodone, buprenorphine and methadone.

Opioids produce euphoria and have been associated with recreational use. They are generally consumed by injection or inhalation of the fumes produced by heating. Regular use of opioids can lead to opioid dependence. Opioid dependence is a medical diagnosis that involves the inability to cease using opioids. The DSM‐IV criteria for dependence (cited here as the studies predominantly use DSM‐IV, whereas DSM‐V was released in 2013) require three or more of the following features:

  1. A strong desire or sense of compulsion to take the drug;

  2. Difficulties in controlling drug‐taking behaviour in terms of its onset, termination, or levels of use;

  3. A physiological withdrawal state when drug use is stopped or reduced, as evidenced by: the characteristic withdrawal syndrome for the substance; or use of the same (or a closely related) substance with the intention of relieving or avoiding withdrawal symptoms;

  4. Evidence of tolerance, such that increased doses of the drug are required in order to achieve effects originally produced by lower doses;

  5. Progressive neglect of alternative pleasures or interests because of drug use, increased amount of time necessary to obtain or take the drug or to recover from its effects;

  6. Persisting with drug use despite clear evidence of overtly harmful consequences, such as harm to the liver, depressive mood states or impairment of cognitive functioning.

The illegality of opioids such as heroin precludes the accurate assessment of how many people use these drugs, but recent estimates suggest there are between 15 and 39 million problem opioid users worldwide (Degenhardt 2012), and although the prevalence of opioid dependence is low (0.6 ‐ 0.8% of the global population; UNODC 2012), the burden to the individual and the community is significant. Illicit opioid dependence is a significant public health problem with heroin use associated with the spread of infectious disease (e.g., HIV, hepatitis B and C) and overdose deaths (Degenhardt 2011; Mathers 2008; Nelson 2011).

Description of the intervention

Dole and Nyswander defined opioid dependence as a "physiological disease characterised by a permanent metabolic deficiency" which was best managed by administering the opioid‐dependent person "a sufficient amount of drug to stabilise the metabolic deficiency" (Dole 1965). In the early 1960s they introduced orally‐administered maintenance doses of the synthetic opioid drug methadone as a treatment for opioid dependence. Maintenance treatment is designed to be an ongoing treatment. The substitution of legal opioids in known doses and purity provides an opportunity to stabilise the person by eliminating withdrawal, craving, participation in obtaining illegal opioids and use of needles.

Methadone maintenance treatment (MMT) has been one of the main forms of treatment for opioid dependence. As described elsewhere (Faggiano 2003; Mattick 1998; Mattick 2009), maintenance treatment with oral methadone appears to be an effective and accepted intervention for illicit opioid (heroin) dependence, and it is widely used in some countries. Yet MMT has a number of negative characteristics which potentially influence its effectiveness and which have led to an interest in alternative pharmacotherapies and methods of treatment delivery (Mattick 1998). The negative aspects of methadone are set out below.

One negative aspect of methadone is its potential to produce and/or maintain dependence on opioids, such that people experience withdrawal if a daily dose is missed, and detoxification can be a lengthy and difficult process which can discourage people from attempting withdrawal (of course, withdrawal from heroin and other opioids have similar problems). Additionally, because methadone is a full opioid agonist, there is no ceiling to the level of respiratory depression or sedation which methadone can induce, and methadone overdose can therefore be fatal (Drummer 1992). Although it is a long‐acting opioid, in some countries and settings, the inconvenience of daily dosing and clinic visits may be unattractive to clients, and restrictions imposed by the daily dosing schedule on clients' general lifestyle and on opportunities to sustain employment may also limit its acceptance to heroin users. The provision of takeaway doses of methadone results in problems of diversion of the drug for illicit use by those not in treatment, although the extent of this problem varies across countries. Finally, heroin users have developed their own 'lore' regarding methadone's negative effects, although their views may not always be accurate or favourable. Thus, despite its many advantages, methadone maintenance appears to have limited suitability for some people. In some countries there may be restrictions on the use of methadone as far as doses and duration are concerned, and this may impair adequate clinical practice. These factors may restrict the ability of methadone to attract certain users into treatment, and the examination of alternative medications to broaden the range of pharmacotherapies has been the focus of research over recent years (e.g., Ling 2003; Mitchell 2004).

How the intervention might work

There are a number of alternatives to methadone as a maintenance agent in the management of opioid dependence, as all opioids show cross‐tolerance. The most promising of these involve pharmacotherapies which treat people with a pharmaceutical‐grade opioid which has a long duration of action. These include the opiate partial agonist buprenorphine, the full agonist levo‐alpha‐acetylmethadol (LAAM) (Clark 2002; Johnson 2000) and sustained released morphine sulphate (Mitchell 2004; White 2007). LAAM is no longer used in clinical practice. In addition, heroin‐assisted treatment has been used in the management of opioid dependence, most notably in Switzerland (Perneger 1998).

This review focuses on the role of buprenorphine as a maintenance therapy in the management of opioid dependence. Buprenorphine is a potent synthetic opioid analgesic initially used for the management of acute pain. Pharmacologically, buprenorphine causes morphine‐like subjective effects and produces cross‐tolerance to other opioids.

Unlike methadone and heroin (which are full agonists), buprenorphine is a partial agonist and exerts weaker opioid effects at opioid receptor sites. This partial agonist action appears to make buprenorphine safer in overdose. Other benefits of buprenorphine may include an easier withdrawal phase and, because of the longer duration of action, the option of alternate‐day dosing.

It was during the initial development of buprenorphine as an analgesic in the 1970s that its potential utility as a substitution agent in the treatment of opioid dependence was recognised. Early work (Jasinski 1978) using buprenorphine administered by the subcutaneous route, characterised it as an opioid with low physical dependence liability with a minimal withdrawal syndrome. Subsequently, others (Fudala 1990) provided evidence that buprenorphine does produce a mild to moderate mu‐agonist withdrawal syndrome. It was thought that at doses somewhat greater than those used for analgesia it could be used in the treatment of opioid dependence (Jasinski 1978). Since that time a substantial international research effort has addressed the efficacy of buprenorphine maintenance therapy in randomised controlled trials (RCTs).

Why it is important to do this review

Clinical trials conducted in the USA. showed buprenorphine to be superior to placebo medication, but when buprenorphine and methadone maintenance were compared in a series of impressive studies using fixed doses of the drugs, the results were mixed. Some of the fixed‐dose studies showed no difference in efficacy, whereas others showed superiority for methadone, and yet others showed the reverse pattern. The investigators in these fixed‐dose studies frequently concluded that the doses of buprenorphine or methadone chosen were too low, or that poor induction regimens led to poor retention and affected trial results. A series of variable‐ (or flexible‐) dose studies have been conducted and shown essentially equivalent results for the two drugs. In these flexible‐dose studies, dose is adjusted to individual need rather than participants being randomly assigned to a set and unchanging dose, as in the fixed‐dose studies.

Given the mixed results of the early studies, it is important to attempt a systematic integration of the literature. Of particular importance is separately assessing the fixed‐ and flexible‐dose studies and considering the results in the light of the differing doses and other individual trial features. Additionally, this review separately summarises the available placebo‐controlled trial results.

This is an update of a Cochrane review, incorporating additional studies, which was first published in 2002 and updated in 2008.

Objectives

To evaluate buprenorphine maintenance compared to placebo and to methadone maintenance in the management of opioid dependence, including its ability to retain people in treatment, suppress illicit drug use, reduce criminal activity, and mortality.

Methods

Criteria for considering studies for this review

Types of studies

Randomised controlled trials of buprenorphine maintenance versus methadone maintenance or versus placebo medication in the management of opioid dependence.

Types of participants

Individuals dependent on heroin or other opioids. We made no distinction between those using heroin and those in methadone treatment prior to entering the research trial treatment. We excluded trials of pregnant women, as a separate review of opioid maintenance therapy for pregnant women has been completed (Minozzi 2013).

Types of interventions

Experimental interventions: Buprenorphine maintenance therapy (BMT) using doses above 1 mg ("which was adopted to serve essentially as a placebo" dose in the context of heroin/opioid dependence (Ling 1998, p.477)), using sublingual tablets, an ethanol‐based solution and more recently implants, containing buprenorphine.

Control Interventions: Methadone maintenance therapy (MMT) with doses of 20 mg methadone per day or higher, or placebo, or 1 mg of buprenorphine per day (as adopted by Ling to "serve essentially as a placebo" dose in one study (Ling 1998, p.477)).

We excluded studies using methadone or buprenorphine for detoxification without a maintenance phase.

Types of outcome measures

Primary outcomes

  1. Retention in treatment as measured by intention‐to‐treat (i.e., the number of participants still in treatment at the end of the study);

  2. Use of opioids as measured by: a) urinalysis results positive for heroin metabolite (i.e., morphine); b) self‐reported heroin use;

  3. Use of other substances of abuse as measured by: a) urinalysis results positive for cocaine; b) urinalysis results positive for benzodiazepines;

  4. Criminal activity as measured by self report;

  5. Mortality.

Secondary outcomes

  1. Physical health;

  2. Psychological health;

  3. Adverse effects of medication.

Search methods for identification of studies

Electronic searches

In consultation with a drug and alcohol research information specialist, we developed a specific search strategy for each database searched with no language restrictions. We searched the Cochrane Central Register of Controlled Trials (CENTRAL), The Cochrane Library, 2013, Issue 1, PubMed (January 2003 to January 2013), and EMBASE (January 2003 to January 2013); seeAppendix 1; Appendix 2; and Appendix 3.

As several drug and alcohol journals are not indexed on the main electronic databases, we also searched the following databases:

  • Current Contents;

  • PsycLIT;

  • CORK [www.projectcork.org/database_search/search_form.html];

  • Alcohol and Drug Council of Australia (ADCA) [www.adca.org.au];

  • Australian Drug Foundation (ADF ‐VIC) [www.adf.org.au/];

  • Centre for Education and Information on Drugs and Alcohol (CEIDA) [www.ceida.net.au/];

  • Australian Bibliographic Network (ABN).

Searching other resources

We also searched the following:

  1. Some of the main electronic sources of ongoing trials (National Research Register, meta‐Register of Controlled Trials; Clinical Trials.gov; Agenzia Italiana del Farmaco);

  2. Conference proceedings likely to contain trials relevant to the review (US College on Problems of Drug Dependence ‐ CPDD);

  3. Library of Congress databases, for studies and book chapters with the key terms: buprenorphine, methadone, clinical trial, and randomised control trial;

  4. National focal points for drug research (e.g., National Institute of Drug Abuse (NIDA), National Drug & Alcohol Research Centre (NDARC));

  5. Reference lists of all relevant papers to identify further studies.

We consulted authors of identified RCTs for any other published or unpublished RCTs comparing the efficacy of buprenorphine and methadone maintenance as therapies for opioid dependence.

Data collection and analysis

Selection of studies

We obtained each potentially relevant study located in the search, and two of four review authors independently assessed it for inclusion. Studies were eligible irrespective of publication status or language of publication.

Data extraction and management

The two review authors who selected a study for inclusion then independently extracted the data for that study. Each review author assessed the same number of studies. We used a standardised checklist or data extraction, with a third review author acting as arbiter in cases of disagreement, and unresolved disagreements on inclusion, study quality or extraction being referred to the editor. Where required, we sought missing or clarifying information by contacting study authors. We handled multi‐arm studies (e.g., Fudala 2003) by combining relevant groups and avoiding double‐counting of participants. Measurement scales were compatible across studies for the main outcomes, with dichotomous data or means and standard deviations being used in all cases.

Assessment of risk of bias in included studies

We assessed the new studies included in this updated version and reassessed the studies already included in the existing review, using the criteria and the method indicated in the Cochrane Handbook for Systematic Reviews of Interventions (Higgins 2011).

The recommended approach for assessing risk of bias in studies included in Cochrane reviews is a two‐part tool, addressing six specific domains (namely randomisation sequence generation, randomisation allocation concealment, blinding of participants and assessors, incomplete outcome data, selective reporting and other potential biases). The first part of the tool involves describing what was reported to have happened in the study. The second part of the tool involves assigning a judgement, in terms of 'low', 'high' or 'unclear', relating to the risk of bias for that entry. To make these judgements we used the criteria indicated by Chapter 8 of theCochrane Handbook and their applicability to the addiction field.

For this updated review, we considered the following domains to be relevant: sequence generation, allocation concealment (avoidance of selection bias), blinding of participants, personnel and outcome assessor (performance and detection bias) and incomplete outcome data (attrition bias). See Appendix 4 for a detailed description of the criteria used. As sequence generation and allocation concealment were adequately described in only a minority of trials (leaving it unclear whether the process was or was not adequate), it was not possible to meaningfully analyse trials by stratifying on these randomisation variables. To address the better‐reported blinded/unblinded status, we report where possible the open‐label (unblinded) studies separately from the blinded comparisons. Where incomplete data were reported (especially in the case of urine analysis of ongoing drug use), we wrote to the authors of the study seeking those data and included them where available.

Measures of treatment effect

We calculated a standardised effect size for each study, based on the outcome measure reported. As the retention‐in‐treatment data are a dichotomous outcome, we calculated the risk ratio (RR) and its 95% confidence interval (CI). We estimated a standardised mean difference for continuous outcomes (urine results, self‐reported heroin use, and criminal activity). Urine data were provided in reports (or by authors in response to our request) in the form of the average number of positive urines and a standard deviation, by treatment group.

Unit of analysis issues

The urine data are presented as a continuous outcome measure but are based on data requested directly from authors. This was necessary as urine results in the literature are routinely reported as the percentage of urine samples collected per treatment group that were positive or negative for a given drug (e.g., heroin) across the study period. These 'count data' are not compatible with the analysable data fields in Review Manager 5 (RevMan) (i.e., continuous, dichotomous, individual patient data). Based on advice provided by Cochrane statisticians, we asked the study authors to calculate the number of positive urines for each participant in each treatment group and derive a mean number of positive urines with a standard deviation, allowing for analysis of urine results as continuous data. These additional data were not available for four studies at the time of writing this review, and urine results are therefore not presented for these studies (Kosten 1993; Neri 2005; Oliveto 1999; Pani 2000,).

Assessment of heterogeneity

We assessed statistically significant heterogeneity among primary outcome studies with the Chi² test and I² heterogeneity test (Higgins 2003). A significant Chi² ( P < 0.05) and I² of at least 50% was considered as statistical heterogeneity.

Data synthesis

We derived the pooled effect size estimate for each domain of measurement (retention in treatment, urine analysis results for heroin/morphine, urine analysis results for cocaine, and urine analysis results for benzodiazepines). Given the diverse treatment settings and countries of the studies involved, we used a random‐effects model.

We integrated the results from the meta‐analytic review into a discussion, taking into consideration other publications such as studies of the pharmacology of methadone and buprenorphine. We took convergence of evidence from the meta‐analysis and from the narrative review to indicate a robust conclusion.

Results

Description of studies

See the Characteristics of included studies table.

Evidence on the efficacy of buprenorphine has come from placebo‐controlled trials (Ahmadi 2002a; Ahmadi 2003b; Ahmadi 2004; Fudala 2003; Johnson 1995a; Kakko 2003; Kakko 2007; Krook 2002; Ling 1998; Ling 2010; Schottenfeld 2008), from fixed‐dosing studies of buprenorphine versus methadone maintenance treatment (Ahmadi 2003a; Ahmadi 2003b; Bickel 1988; Fischer 1999; Johnson 1992; Kosten 1993; Kristensen 2005; Ling 1996; Oliveto 1999; Pani 2000; Schottenfeld 2005; Uehlinger 1998) and from variable‐ or flexible‐dosing studies of buprenorphine versus methadone maintenance treatment (Fischer 1999; Johnson 2000; Kristensen 2005; Lintzeris 2004; Magura 2009; Mattick 2003; Neri 2005; Petitjean 2001; Soyka 2008a; Strain 1994a; Strain 1994b). Many of the earlier studies used the sublingual solution formulation (Johnson 1992; Johnson 1995a; Ling 1996; Ling 1998; Oliveto 1999; Schottenfeld 1997; Schottenfeld 2005; Strain 1994a; Strain 1994b) and a few more recent studies have used the combined buprenorphine‐naloxone tablet (Fudala 2003; Kakko 2007; Kamien 2008; Magura 2009). One study used buprenorphine implant formulation (Ling 2010). The remaining sixteen studies used the sublingual tablet formulation.

Results of the search

We identified 6495 studies through the electronic and other searches. Of these, we discarded 1794 studies as they were identified as duplicates. We eliminated a further 1733 studies after reviewing titles. We examined the full text of 61 studies, and eliminated a further 36, leaving 31 studies included in the analysis. See Figure 1.


Study flow diagram.

Study flow diagram.

Included studies

We include 31 studies (5430 participants) in this review.

Country of origin of the included studies
Fifteen studies were from North America (Fudala 2003; Johnson 1992; Johnson 1995a; Johnson 2000; Kamien 2008; Kosten 1993; Ling 1996; Ling 1998; Ling 2010; Magura 2009; Oliveto 1999; Schottenfeld 1997; Schottenfeld 2005; Strain 1994a; Strain 1994b), nine were from Europe (Fischer 1999; Kakko 2003; Kakko 2007; Kristensen 2005; Krook 2002; Neri 2005; Pani 2000; Petitjean 2001; Soyka 2008a), four from the Middle East (Ahmadi 2002a; Ahmadi 2003a; Ahmadi 2003b; Ahmadi 2004), two from Australia (Lintzeris 2004;Mattick 2003) and one from Asia (Schottenfeld 2008).

Characteristics of the participants
The majority of participants in these studies were male, consistent with the profile of heroin‐dependant users generally. They tended to be approximately 30 years of age, with different previous treatment histories and prevalence of use of other drugs, again consistent with what is known about heroin users presenting for treatment. The number of participants in these studies varied between 40 in one study (Kakko 2003) up to 736 in the study by Ling 1998. The largest comparative trial of methadone versus buprenorphine included was reported by Mattick 2003, with 405 participants. Many of the studies had quite small numbers of participants in each individual treatment group. The characteristics of the participants and the inclusion and exclusion criteria were well described in all of the studies.

Duration of intervention
The interventions ranged in duration from 2 weeks through to 52 weeks. By and large, the interventions used clinically relevant doses of medication, although as noted earlier a number of the studies used predetermined fixed doses of medication (i.e., not tailored to individual treatment preference or need) and this created some limitations in terms of generalisability to day‐to‐day clinical practice, where flexible dosing is used.

Characteristics of the intervention and types of comparisons

Twenty studies involved comparisons of methadone and buprenorphine. The remaining eleven studies compared buprenorphine with placebo, where placebo was defined as either true placebo (Fudala 2003; Johnson 1995a; Kakko 2003; Kakko 2007; Krook 2002; Ling 2010; Schottenfeld 2008) or a 1 mg dose of buprenorphine (Ahmadi 2002a; Ahmadi 2003a; Ahmadi 2004; Ling 1998). Because of the use of 1 mg buprenorphine as a placebo dose, it is possible that we have underestimated the effect of buprenorphine at active doses. However, the approach is conservative and unlikely to bias results in favour of buprenorphine.

The studies selected for this review had two distinct dosing approaches. Eleven studies used flexible dosing (Fischer 1999; Johnson 2000; Kristensen 2005; Lintzeris 2004; Magura 2009; Mattick 2003; Neri 2005; Petitjean 2001; Soyka 2008a;Strain 1994a; Strain 1994b) where dose is titrated according to participant preference within a broad upper and lower dose limit. The remaining studies used fixed‐dosing schedules where participants were randomised to receive a fixed dose or a dose with a narrow dose range, without dose adjustment after stabilisation.

As most of the studies with fixed‐dosing schedules had more than one dose comparison, we have broadly classified the treatment groups as 'low dose', 'medium dose' and 'high dose' for the respective pharmacotherapy. These categories are arbitrary, driven by the doses used in the studies, and they do not reflect dose equivalence between methadone and buprenorphine. In the case of methadone, dose ranges up to 40 mg were classified as low dose, between 40 mg and 85 mg as medium dose, and more than 85 mg as high dose. In the case of buprenorphine studies where methadone was the comparator, dose ranges for buprenorphine between 2 mg and 6 mg were classified as low dose and between 7 mg and 15 mg as medium dose, and 16 mg as high dose. In the case of the buprenorphine studies where placebo (i.e. 0 mg or 1 mg) is the comparator (Johnson 1995a; Ling 1998) we included three buprenorphine dose levels; 0 ‐ 1 mg versus 2 ‐ 6 mg (Ahmadi 2002a; Ahmadi 2003a; Ahmadi 2004; Johnson 1995a; Ling 1998), 0 ‐ 1 mg versus 7 ‐ 15 mg (Ahmadi 2003a; Ahmadi 2004; Johnson 1995a; Ling 1998), and 0 ‐ 1 mg versus 16 mg (Fudala 2003; Kakko 2003; Krook 2002; Ling 1998).

Because of the design of the studies included in the review, we were also able to conduct analyses of:

  • low‐dose buprenorphine versus low‐dose methadone;

  • low‐dose buprenorphine versus medium‐dose methadone;

  • medium‐dose buprenorphine versus medium‐dose methadone;

  • high‐dose buprenorphine versus high‐dose methadone;

  • buprenorphine (low‐dose, medium‐dose and high‐dose) versus placebo medication.

Again, we used 1 mg of buprenorphine as a placebo dose, as it has been defined in this way by others (Ling 1998) who refer to this dose as being "adopted to serve essentially as a placebo".

The study by Johnson 2000 is classified as a flexible‐dose study and we did not include the 20 mg methadone fixed‐dose group from that study in the analyses as we did not choose to compare a low‐dose fixed methadone maintenance treatment (MMT) dose with a flexible buprenorphine maintenance treatment (BMT) dose. Specific study doses are provided in the Characteristics of included studies table.

The number of positive urines in each treatment group used to derive the mean number of positive urines with a standard deviation was not available for four studies (Kosten 1993; Neri 2005; Oliveto 1999; Pani 2000), and urine results are therefore not presented for these studies.

The reader should be aware that some of the studies used an aqueous ethanol‐based buprenorphine solution which has been reported by some to have a higher bioavailability than the marketed tablet. As the literature on dose equivalence of the solution and the tablet was sparse, and the pharmacodynamics and pharmacokinetics and dosing practices within trials were not well‐articulated, we used the doses as defined by the study authors rather than trying to estimate the dose equivalence per study. It is also noted that intra‐ and inter‐individual differences in metabolism, effects of pregnancy, and concurrent illicit drug use will all affect blood levels of medications. This approach seemed reasonable as no blood levels of the medication were given in the studies.

Four studies (Fudala 2003; Kakko 2007; Kamien 2008; Magura 2009) used the buprenorphine‐naloxone formulation.

  • Fudala 2003: fixed high‐dose buprenorphine‐naloxone versus placebo;

  • Kakko 2007: fixed medium‐dose buprenorphine‐naloxone versus placebo;

  • Kamien 2008: fixed medium‐dose buprenorphine‐naloxone versus medium‐dose methadone and high‐dose buprenorphine‐naloxone versus high‐dose methadone;

  • Magura 2009: flexible‐dose buprenorphine‐naloxone versus methadone.

We considered empirically testing these four studies separately but they involve different dosing regimens. To be consistent with the analysis in this review where studies were grouped by dosage (both the dose size and whether they are flexible or fixed), we did not combine the buprenorphine‐naloxone studies. The results from all four studies that use the combination formula showed results favouring the buprenorphine‐naloxone combination.

Excluded studies

We excluded 36 studies. Four studies (Bickel 1988; Meader 2010; Resnick 1992; Woody 2008) were essentially trials of detoxification or withdrawal. The study of Bouchez 1998 was a non‐randomised comparison of methadone, buprenorphine and morphine sulphate. Giacomuzzi 2003 was an open‐label, non‐randomised comparison of methadone and buprenorphine. Two studies involved treating people with chronic pain and iatrogenic opioid dependence (Neumann 2013; Weiss 2011).

Three studies were trials of dosing schedules (Johnson 1995b; Marsch 2005; Montoya 2004). Three studies were feasibility or efficacy trials that did not report doses or outcome variables of interest (Bond 2004; Gerra 2004; Sigmon 2004). One study was of the transfer to opioid replacement therapy (Jones 2005a), and papers by O'Connor 1998 and Lucas 2010 were trials of treatment setting, not of medication. Four studies involved pregnant women (Fischer 2006; Jones 2005b; Jones 2010b). The Pinto 2008 study was a feasibility trial and no participants were randomised, and the studies by Sacerdote 2008, Gryczynski 2013 and McKeganey 2013 were not randomised trials.

The remaining studies were a number of interim reports or secondary analysis of trials already included in this review, and data from only one article for each trial were included in the review (Eder 1998; Harris 2005; Kosten 2004; Lott 2006; Oliveto 1994; Schottenfeld 1998; Soyka 2008b; Stine 1994; Strain 1996; Uehlinger 1998; Warden 2012).

Risk of bias in included studies

See 'Risk of bias' tables in the Characteristics of included studies Table, Figure 2 and Figure 3.


Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.


Risk of bias summary: review authors' judgements about each risk of bias item for each included study.

Risk of bias summary: review authors' judgements about each risk of bias item for each included study.

Allocation

Thirteen studies provided an adequate sequence generation for the randomisation process, including a random number table from a textbook or computer‐generated or the use of sealed envelopes. One study randomised by consecutive numerical order which we considered inadequate (Ahmadi 2003b). The remainder of the trials (n = 17) did not describe the randomisation process in sufficient detail to be clear whether the method was adequate, and are rated as being at unclear risk of bias.

Eleven studies provided an adequate method of concealment of allocation, including the use of an independent external agency, often the pharmacy. Nineteen studies did not describe the concealment of allocation process in sufficient detail to be clear that the allocation concealment method was adequate, and are rated as being at unclear risk of bias. One study reported a concealment method defined as inadequate, i.e., at high risk of bias.

Blinding

Of the 31 studies included in this review, 22 were reportedly conducted under double‐blind conditions. Ten studies (Ahmadi 2002a; Ahmadi 2003b; Ahmadi 2004;Fischer 1999; Kakko 2007; Kristensen 2005; Lintzeris 2004; Magura 2009; Neri 2005;Soyka 2008a) were open comparative trials. All the studies, including the open‐label, have been judged as being at low risk of bias for performance and detection bias because the objective outcomes are considered not to be influenced by lack of blinding. In order to maintain the double‐blind where methadone was compared with buprenorphine, participants were given both an oral solution of either active or placebo methadone syrup and a sublingual preparation of active or placebo buprenorphine (a double‐blind, double‐dummy design). In a few trials the method of maintaining the blinding was not given. Additionally, the success of the blinding was not reported in the trials.

Incomplete outcome data

All the studies have been judged to be at low risk of bias because all used the intention‐to‐treat (ITT) principle.

Effects of interventions

See: Summary of findings for the main comparison Summary of findings: comparison between flexible‐dose methadone and buprenorphine; Summary of findings 2 Summary of findings for the comparison between high‐dose buprenorphine and placebo

See summary of findings Table for the main comparison; summary of findings Table 2

(01) Retention in treatment:

Comparison 01: Flexible‐dose buprenorphine versus flexible‐dose methadone:

As noted earlier, the flexible‐dose studies probably provide the best estimate of the likely impact of methadone and buprenorphine in day‐to‐day clinical practice, as they mirror clinical practice in terms of dose adjustments and in terms of the doses employed in the studies. The 11 studies (Fischer 1999; Johnson 2000; Kristensen 2005; Lintzeris 2004; Magura 2009; Mattick 2003; Neri 2005; Petitjean 2001; Soyka 2008b; Strain 1994a; Strain 1994b); 1391 participants included in the analysis, showed results in favour of methadone: risk ratio (RR) 0.83; 95% confidence interval (CI) 0.73 to 0.95. The Chi² test for heterogeneity was significant (I² = 56%, P = 0.01). Because of differences in methodology potentially creating heterogeneity among the 11 flexible‐dose studies, we conducted separate meta‐analyses of the double‐blind studies and open‐label studies. The results of these separate analyses indicated that in the double‐blind studies (five studies, 788 participants) there was a lower rate of retention for participants treated with buprenorphine: RR 0.83; 95% CI 0.72 to 0.95, with very little heterogeneity (I² = 19.0%, P = 0.29). However, very high heterogeneity was observed among open‐label studies (six studies, 603 participants; I² = 73%, P < 0.005). The results are presented in Analysis 1.1 and Figure 4


Forest plot of comparison: 1 Flexible dose buprenorphine versus flexible dose methadone, outcome: 1.1 Retention in treatment.

Forest plot of comparison: 1 Flexible dose buprenorphine versus flexible dose methadone, outcome: 1.1 Retention in treatment.

Comparison 02: Low‐dose buprenorphine versus low‐dose methadone:

The comparison indicated that low‐dose methadone was more likely to retain participants than low‐dose buprenorphine; RR 0.67; 95% CI 0.52 to 0.87; three studies, 253 participants (Ahmadi 2003a; Kosten 1993; Schottenfeld 1997). See Analysis 2.1.

Comparison 03: Medium‐dose buprenorphine versus medium‐dose methadone:

There was no difference between medium‐dose buprenorphine and medium‐dose methadone in the ability to retain participants in treatment, RR 0.87; 95% CI 0.69 to 1.10; seven studies, 780 participants (Johnson 1992; Kamien 2008; Ling 1996; Oliveto 1999; Pani 2000; Schottenfeld 1997; Schottenfeld 2005). See Analysis 3.1.

Comparison 04: High‐dose buprenorphine versus high‐dose methadone:

There were no differences between high‐dose buprenorphine and high‐dose methadone in retention: RR 0.79; 95% CI 0.20 to 3.16; one study, 134 participants (Kamien 2008). See Analysis 4.1

Comparison 05: Low‐dose buprenorphine maintenance versus placebo:

The results showed a benefit for low‐dose buprenorphine over placebo in terms of retaining participants in treatment: RR 1.50; 95% CI 1.19 to 1.88); five studies, 1131 participants (Ahmadi 2002a; Ahmadi 2003a; Ahmadi 2004; Johnson 1995a; Ling 1998). SeeAnalysis 5.1.

Comparison 06: Medium‐dose buprenorphine maintenance versus placebo:

The results showed a benefit for medium‐dose buprenorphine over placebo in terms of retaining participants in treatment: RR 1.74; 95% CI 1.06 to 2.87; four studies, 887 participants (Ahmadi 2003a; Ahmadi 2004; Johnson 1995a; Ling 1998). SeeAnalysis 6.1.

Comparison 07: High dose buprenorphine maintenance versus placebo:

The results showed a benefit for high‐dose buprenorphine over placebo in terms of retaining participants in treatment: RR 1.82; 95% CI 1.15 to 2.90, five studies, 1001 participants (Fudala 2003; Kakko 2003; Krook 2002; Ling 1998; Ling 2010). SeeAnalysis 7.1.

(02) Use of opioids (urinalysis):

Comparison 01: Flexible‐dose buprenorphine versus flexible‐dose methadone:

There was no difference between the two interventions in terms of heroin use, based on results of morphine urinalysis: SMD ‐0.11; 95% CI ‐0.23 to 0.02; eight studies, 1027 participants (Fischer 1999; Johnson 2000; Kristensen 2005; Mattick 2003; Petitjean 2001; Soyka 2008a; Strain 1994a; Strain 1994b; ). See Analysis 1.2.

Comparison 02: Low‐dose buprenorphine versus low‐dose methadone:

We found no differences in morphine‐positive urine; SMD ‐0.35; 95% CI ‐0.87 to 0.16; one study, 59 participants (Schottenfeld 1997) . See Analysis 2.2.

Comparison 03: Medium‐dose buprenorphine versus medium‐dose methadone:

We found no difference between medium‐dose buprenorphine and medium‐dose methadone in terms of heroin use, based on results of morphine urinalysis: SMD 0.25; 95% CI ‐0.08 to 0.58; four studies, 476 participants (Johnson 1992; Ling 1996; Schottenfeld 1997; Schottenfeld 2005). SeeAnalysis 3.2.

Comparison 04: High‐dose buprenorphine versus high‐dose methadone:

No studies reporting urine data.

Comparison 05: Low‐dose buprenorphine maintenance versus placebo:

We found no difference between low‐dose buprenorphine and placebo as indexed by morphine‐positive urines: SMD 0.10; 95% CI ‐0.80 to 1.01; two studies, 487 participants (Johnson 1995a; Ling 1998). See Analysis 5.2.

Comparison 06: Medium‐dose buprenorphine maintenance versus placebo:

We found no difference between medium‐dose buprenorphine and placebo in terms of heroin use as indexed by morphine‐positive urines: SMD ‐0.08; 95% CI ‐0.78 to 0.62; two studies, 463 participants (Johnson 1995a; Ling 1998) . See Analysis 6.2.

Comparison 07: High‐dose buprenorphine maintenance versus placebo:

Participants on high‐dose buprenorphine treatment had less heroin use as indexed by morphine‐positive urines than those on placebo: SMD ‐1.17; 95% CI ‐1.85 to ‐0.49; three studies, 729 participants (Fudala 2003; Kakko 2003; Ling 1998). See Analysis 7.2.

(03) Use of opioids (self‐reported):

Comparison 01: Flexible‐dose buprenorphine versus flexible‐dose methadone:

We found no difference between the two interventions in terms of self‐reported heroin use: SMD ‐0.11; 95% CI ‐0.28 to 0.07; four studies, 501 participants (Johnson 2000; Lintzeris 2004; Magura 2009; Mattick 2003). See Analysis 1.3.

Comparison 02: Low‐dose buprenorphine versus low‐dose methadone:

There was no difference between low‐dose buprenorphine and low‐dose methadone in self‐reported heroin use: SMD ‐0.29; 95% CI ‐0.38 to 0.96; one study, 37 participants (Kosten 1993). See Analysis 2.3.

Comparison 03: Medium‐dose buprenorphine versus medium‐dose methadone:

There was no difference in self‐reported heroin use between medium doses of buprenorphine and methadone, but again the Chi² test for heterogeneity was significant (P = 0.006): SMD ‐0.82; 95% CI ‐1.83 to 0.19; two studies, 174 participants (Kamien 2008; Pani 2000). See Analysis 3.3.

Comparison 04: High‐dose buprenorphine versus high‐dose methadone:

We found no differences between high‐dose buprenorphine and high‐dose methadone in self‐reported heroin use: SMD ‐0.73; 95% CI ‐1.08 to ‐0.37; one study, 134 participants (Kamien 2008). See Analysis 4.2.

Theree were no data on self‐reported heroin use for the remaining comparisons.

(04) Use of cocaine:

Comparison 01: Flexible‐dose buprenorphine versus flexible‐dose methadone:

We found no difference between six studies of flexible dosing with buprenorphine or methadone for cocaine‐positive urines; SMD 0.10; 95% CI ‐0.05 to 0.25; 929 participants (Fischer 1999; Johnson 2000; Mattick 2003Soyka 2008a; Strain 1994al Strain 1994b). SeeAnalysis 1.4.

Comparison 02: Low‐dose buprenorphine versus low‐dose methadone:

There were no differences in cocaine‐positive urines between low‐dose usage of buprenorphine and methadone; SMD 0.08; 95% CI ‐0.43 to 0.59; one study, 59 participants (Schottenfeld 1997). See Analysis 2.4.

Comparison 03: Medium‐dose buprenorphine versus medium‐dose methadone:

We found no difference between medium dosage of buprenorphine and methadone for cocaine‐positive urines: SMD 0.21; 95% CI ‐0.06 to 0.47; two studies, 57 participants (Schottenfeld 1997; Schottenfeld 2005). See Analysis 3.4.

Comparison 4: High‐dose buprenorphine versus high‐dose methadone:

There were no data for this comparison on cocaine‐positive urines.

Comparison 05: Low‐dose buprenorphine maintenance versus placebo:

We found no difference between low‐dose buprenorphine and placebo for cocaine‐positive urines: SMD 0.26; 95% CI ‐0.10 to 0.62; one study, 120 participants (Johnson 1995a). See Analysis 5.3.

Comparison 06: Medium‐dose buprenorphine maintenance versus placebo:

There was an advantage for placebo over medium‐dose buprenorphine for cocaine‐positive urines: SMD 0.50; 95% CI 0.05 to 0.94; one study, 90 participants (Johnson 1995a). See Analysis 6.3.

Comparison 07: High‐dose buprenorphine maintenance versus placebo:

We found no difference between high‐dose buprenorphine and placebo for cocaine‐positive urines: SMD 0.08; 95% CI ‐0.16 to 0.32; one study, 296 participants (Fudala 2003). See Analysis 7.3.

(05) Use of benzodiazepines:

Comparison 01: Flexible‐dose buprenorphine versus flexible‐dose methadone:

We found no difference across six studies comparing flexible dosing of buprenorphine and methadone for benzodiazepine‐positive urines: SMD 0.05; 95% CI ‐0.12 to 0.22; 859 participants (Fischer 1999; Kristensen 2005; Mattick 2003; Soyka 2008a; Strain 1994a; Strain 1994b).SeeAnalysis 1.5.

Comaprison 02: Low‐dose buprenorphine versus low‐dose methadone:

No data available for benzodiazepine‐positive urines.

Comparison 03: medium‐dose buprenorphine versus medium‐dose methadone:

No data available for benzodiazepine‐positive urines.

Comparison 04: high‐dose buprenorphine versus high‐dose methadone:

No data available for benzodiazepine‐positive urines.

Comparison 05: Low‐dose buprenorphine maintenance versus placebo:

We found no difference between low‐dose buprenorphine and placebo for benzodiazepine‐positive urines: SMD 0.03; 95% CI ‐0.33 to 0.38; one study, 120 participants (Johnson 1995a). See Analysis 5.4.

Comparison 06: Medium‐dose buprenorphine maintenance versus placebo:

Buprenorphine was superior to placebo for benzodiazepine‐positive urines; SMD ‐0.81; 95% CI ‐1.27 to ‐0.36; one study, 90 participants (Johnson 1995a). See Analysis 6.4.

Comparison 07: High‐dose buprenorphine maintenance versus placebo:

We found no difference between high‐dose buprenorphine and placebo for benzodiazepine‐positive urines: SMD ‐1.65; 95% CI ‐4.94 to 1.65; two studies, 336 participants (Fudala 2003; Kakko 2003). See Analysis 7.4.

(06) Criminal activity:

Comparison 01: Flexible‐dose buprenorphine versus flexible‐dose methadone:

We found no difference between the buprenorphine and methadone groups: SMD ‐0.10; 95% CI ‐0.31 to 0.12; two studies, 328 participants (Magura 2009; Mattick 2003). See Analysis 1.6.

For the other comparisons, no data on criminal activity were reported in the included studies.

(07) Mortality:

Five studies provided mortality data (Kakko 2003; Krook 2002; Ling 1996; Ling 1998; Schottenfeld 2008). No deaths were reported in the Krook 2002; Ling 1998 or Schottenfeld 2008 studies. Kakko 2003 reported a 20% mortality in control participants at one year while the Ling 1996study reported two deaths unrelated to the study medication (i.e., stab wounds and cancer).

(08) Adverse events:

Ten studies report collecting data on adverse events or side effects (Fudala 2003; Johnson 2000; Kamien 2008; Krook 2002; Ling 1996; Ling 1998; Mattick 2003; Pani 2000; Petitjean 2001; Soyka 2008b).The frequency and types of adverse events varied by study. There were no attempts to compare the adverse events statistically in Mattick 2003, Fudala 2003 or Ling 1996. Ling 1996 reported there were "numerous and diverse adverse events reported for both groups" and "adverse events equally represented in all groups" (Ling 1998). Those studies that did compare adverse events statistically found no difference between groups in the frequency of adverse events (Pani 2000; Petitjean 2001). The methadone group in Petitjean 2001 reported significantly more sedation (58% versus 26%). Krook 2002 reported that the two groups were statistically similar, with the exception that more of the placebo group reported exanthema. The side effects were reportedly "similar among groups" (Johnson 2000).

Discussion

Summary of main results

Buprenorphine is an effective medication for maintenance treatment of opioid dependence, as it is superior to placebo in retaining people in treatment based on all the 14 placebo‐controlled comparisons. However, based on objective urinanalysis results, buprenorphine is only superior to placebo in suppression of heroin use at high doses (defined here as 16 mg or more) but not at low or medium doses (defined here as 15 mg or less).

Before discussing the results of the buprenorphine and methadone comparisons, we remind the reader that we have distinguished between the fixed‐dose studies and flexible‐dose studies, as the former do not relate to clinical reality, where doses are in fact titrated by the clinician in response to individual need. The flexible‐dose studies are more clinically relevant and deserve more attention in consideration of the meta‐analytic review findings. The results of the meta‐analyses here clearly indicate that methadone is better able to retain participants than buprenorphine in flexible‐dosing approaches (at least in the double‐blind efficacy trials). Turning to reduction in heroin use, within the flexible‐dose studies, there was no evidence of any difference between methadone and buprenorphine in their ability to suppress heroin use (self‐reported or urinanalysis results).

One explanation which has been advanced by authors in some of the studies included here for the poorer retention in buprenorphine treatment (Fischer 1999; Petitjean 2001) is that they inducted participants too slowly onto buprenorphine, and that this was the cause of the poorer retention in that medication group. It is possible that retention is affected by too‐slow induction, and given the apparent relative safety of buprenorphine it may be possible to induct people to higher doses at a more rapid rate and to overcome the problem of slightly poorer retention for buprenorphine compared with methadone. However, there are a number of other possible explanations for the poorer retention on buprenorphine than methadone. In particular, it may well be that buprenorphine, being a partial agonist, does not retain people because it does not have a full opioid effect and is less satisfying to those allocated to it. Another possibility is that people in the initial stages of dosing who have recently ingested heroin suffer a mild withdrawal syndrome by virtue of buprenorphine (a partial agonist) displacing heroin (a full agonist) from opioid receptors in the central nervous system, and this mild withdrawal may lead to leaving treatment. A further possibility is that buprenorphine is simply easier to withdraw from and, on that basis, those using it are more at liberty to leave treatment without the severe withdrawal syndrome that can accompany methadone withdrawal. These factors may all act together to cause buprenorphine to have a slightly poorer outcome for retention than methadone. Future research should be undertaken to address this particular issue.

Turning to other outcomes, the results from two trials suggest there is no difference between methadone and buprenorphine for reducing criminal activity. There is evidence from other literature showing criminal activity is decreased in those who are in methadone treatment (Lind 2005). The majority of the studies that reported mortality data reported no deaths, and the two studies that reported deaths were among the controls (Kakko 2003) or not related to study medication (Ling 1998). Other research suggests that mortality is decreased among those in opioid substitution treatment (Soyka 2011), although methadone dosing in the first two weeks of induction is associated with heightened risk of death from methadone overdose (Clausen 2008; Degenhardt 2009; Degenhardt 2011; Gibson 2008).

The majority of studies did not compare adverse events statistically, although those that did found only one difference between methadone and buprenorphine with one study reporting more sedation among participants on methadone (Johnson 2000).

Overall completeness and applicability of evidence

The evidence is reasonably complete with regard to the effectiveness of buprenorphine relative to placebo, and buprenorphine relative to methadone, in maintenance for the important outcomes of retention and illicit opioid use. More data on the impacts on criminal activity, mortality and adverse events would be desirable. However, it may not be possible to generate such data from randomised trials, especially for impacts on crime and mortality, as randomised controlled trials are typically too short in duration to show differential effects in these domains.

Quality of the evidence

The clinical trials represented in this review are of reasonable quality, and whilst many of them did not fully explain how randomisation was concealed, they appear to have used doses which are clinically relevant and to have treated participants for significant periods of time. Moreover, despite the tendency of randomised studies to include selected populations, characteristics of drug users enrolled in the studies included in this review appear to be heterogeneous enough to allow generalisability of the results across different clinical and cultural settings. Based on the nature of the trials, it would appear the external validity or generalisability of the results is quite good, particularly from those trials which have used large sample sizes and adequate doses.

Potential biases in the review process

To overcome bias at the study level, we have used: (a) predetermined main outcomes; (b) the main outcomes being independent of the study reporting; (c) including all the reported main outcomes from the studies; and (d) additional data from the authors (which was generally provided).

At the review level, to reduce our risks of bias, we (a) used predetermined study inclusion criteria; (b) employed wide‐ranging and thorough searches of the literature; (c) relied on independent coding of the data, with separate resolution of disagreements; and (d) subjected the review to repeated independent refereeing and comment through Cochrane Collaboration methods. For example, as mentioned above, we addressed the potential problem of selective outcome reporting by contacting the authors of the studies to obtain results for main outcome variables. We note that we have reported data for retention for all but one study (Johnson 1995a), where retention was reported by dose change and not by remaining in the treatment condition. There is no evidence of selective reporting for the retention measure. The data for urine results were included, after we asked authors to provide such data and there was good compliance with this request, so that measured outcomes were provided to us and included in the review.

We have also included in the review an indication of which studies contributed data to the outcomes, for the interested reader (see Figures and Tables, Data Analysis, and elsewhere in text).

Agreements and disagreements with other studies or reviews

Similar conclusions have been reached by other meta‐analytic reviews of these treatments (Barnett 2001; Connock 2007; West 2000), and the dose‐response of methadone is well‐established (Faggiano 2003).

Study flow diagram.
Figures and Tables -
Figure 1

Study flow diagram.

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.
Figures and Tables -
Figure 2

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.

Risk of bias summary: review authors' judgements about each risk of bias item for each included study.
Figures and Tables -
Figure 3

Risk of bias summary: review authors' judgements about each risk of bias item for each included study.

Forest plot of comparison: 1 Flexible dose buprenorphine versus flexible dose methadone, outcome: 1.1 Retention in treatment.
Figures and Tables -
Figure 4

Forest plot of comparison: 1 Flexible dose buprenorphine versus flexible dose methadone, outcome: 1.1 Retention in treatment.

Comparison 1 Flexible‐dose buprenorphine versus flexible‐dose methadone, Outcome 1 Retention in treatment.
Figures and Tables -
Analysis 1.1

Comparison 1 Flexible‐dose buprenorphine versus flexible‐dose methadone, Outcome 1 Retention in treatment.

Comparison 1 Flexible‐dose buprenorphine versus flexible‐dose methadone, Outcome 2 Morphine‐positive urines.
Figures and Tables -
Analysis 1.2

Comparison 1 Flexible‐dose buprenorphine versus flexible‐dose methadone, Outcome 2 Morphine‐positive urines.

Comparison 1 Flexible‐dose buprenorphine versus flexible‐dose methadone, Outcome 3 Self‐reported heroin use.
Figures and Tables -
Analysis 1.3

Comparison 1 Flexible‐dose buprenorphine versus flexible‐dose methadone, Outcome 3 Self‐reported heroin use.

Comparison 1 Flexible‐dose buprenorphine versus flexible‐dose methadone, Outcome 4 Cocaine‐positive urines.
Figures and Tables -
Analysis 1.4

Comparison 1 Flexible‐dose buprenorphine versus flexible‐dose methadone, Outcome 4 Cocaine‐positive urines.

Comparison 1 Flexible‐dose buprenorphine versus flexible‐dose methadone, Outcome 5 Benzodiazepine‐positive urines.
Figures and Tables -
Analysis 1.5

Comparison 1 Flexible‐dose buprenorphine versus flexible‐dose methadone, Outcome 5 Benzodiazepine‐positive urines.

Comparison 1 Flexible‐dose buprenorphine versus flexible‐dose methadone, Outcome 6 Criminal activity.
Figures and Tables -
Analysis 1.6

Comparison 1 Flexible‐dose buprenorphine versus flexible‐dose methadone, Outcome 6 Criminal activity.

Comparison 2 Low‐dose buprenorphine versus low‐dose methadone, Outcome 1 Retention in treatment.
Figures and Tables -
Analysis 2.1

Comparison 2 Low‐dose buprenorphine versus low‐dose methadone, Outcome 1 Retention in treatment.

Comparison 2 Low‐dose buprenorphine versus low‐dose methadone, Outcome 2 Morphine‐positive urines.
Figures and Tables -
Analysis 2.2

Comparison 2 Low‐dose buprenorphine versus low‐dose methadone, Outcome 2 Morphine‐positive urines.

Comparison 2 Low‐dose buprenorphine versus low‐dose methadone, Outcome 3 Self‐reported heroin use.
Figures and Tables -
Analysis 2.3

Comparison 2 Low‐dose buprenorphine versus low‐dose methadone, Outcome 3 Self‐reported heroin use.

Comparison 2 Low‐dose buprenorphine versus low‐dose methadone, Outcome 4 Cocaine‐positive urines.
Figures and Tables -
Analysis 2.4

Comparison 2 Low‐dose buprenorphine versus low‐dose methadone, Outcome 4 Cocaine‐positive urines.

Comparison 3 Medium‐dose buprenorphine versus medium‐dose methadone, Outcome 1 Retention in treatment.
Figures and Tables -
Analysis 3.1

Comparison 3 Medium‐dose buprenorphine versus medium‐dose methadone, Outcome 1 Retention in treatment.

Comparison 3 Medium‐dose buprenorphine versus medium‐dose methadone, Outcome 2 Morphine‐positive urines.
Figures and Tables -
Analysis 3.2

Comparison 3 Medium‐dose buprenorphine versus medium‐dose methadone, Outcome 2 Morphine‐positive urines.

Comparison 3 Medium‐dose buprenorphine versus medium‐dose methadone, Outcome 3 Self‐reported heroin use.
Figures and Tables -
Analysis 3.3

Comparison 3 Medium‐dose buprenorphine versus medium‐dose methadone, Outcome 3 Self‐reported heroin use.

Comparison 3 Medium‐dose buprenorphine versus medium‐dose methadone, Outcome 4 Cocaine‐positive urines.
Figures and Tables -
Analysis 3.4

Comparison 3 Medium‐dose buprenorphine versus medium‐dose methadone, Outcome 4 Cocaine‐positive urines.

Comparison 4 High‐dose buprenorphine versus high‐dose methadone, Outcome 1 Retention in treatment.
Figures and Tables -
Analysis 4.1

Comparison 4 High‐dose buprenorphine versus high‐dose methadone, Outcome 1 Retention in treatment.

Comparison 4 High‐dose buprenorphine versus high‐dose methadone, Outcome 2 Self‐reported heroin use.
Figures and Tables -
Analysis 4.2

Comparison 4 High‐dose buprenorphine versus high‐dose methadone, Outcome 2 Self‐reported heroin use.

Comparison 5 Low‐dose buprenorphine versus placebo, Outcome 1 Retention in treatment.
Figures and Tables -
Analysis 5.1

Comparison 5 Low‐dose buprenorphine versus placebo, Outcome 1 Retention in treatment.

Comparison 5 Low‐dose buprenorphine versus placebo, Outcome 2 Morphine‐positive urines.
Figures and Tables -
Analysis 5.2

Comparison 5 Low‐dose buprenorphine versus placebo, Outcome 2 Morphine‐positive urines.

Comparison 5 Low‐dose buprenorphine versus placebo, Outcome 3 Cocaine‐positive urines.
Figures and Tables -
Analysis 5.3

Comparison 5 Low‐dose buprenorphine versus placebo, Outcome 3 Cocaine‐positive urines.

Comparison 5 Low‐dose buprenorphine versus placebo, Outcome 4 Benzodiazepine‐positive urines.
Figures and Tables -
Analysis 5.4

Comparison 5 Low‐dose buprenorphine versus placebo, Outcome 4 Benzodiazepine‐positive urines.

Comparison 6 Medium‐dose buprenorphine versus placebo, Outcome 1 Retention in treatment.
Figures and Tables -
Analysis 6.1

Comparison 6 Medium‐dose buprenorphine versus placebo, Outcome 1 Retention in treatment.

Comparison 6 Medium‐dose buprenorphine versus placebo, Outcome 2 Morphine‐positive urines.
Figures and Tables -
Analysis 6.2

Comparison 6 Medium‐dose buprenorphine versus placebo, Outcome 2 Morphine‐positive urines.

Comparison 6 Medium‐dose buprenorphine versus placebo, Outcome 3 Cocaine‐positive urines.
Figures and Tables -
Analysis 6.3

Comparison 6 Medium‐dose buprenorphine versus placebo, Outcome 3 Cocaine‐positive urines.

Comparison 6 Medium‐dose buprenorphine versus placebo, Outcome 4 Benzodiazepine‐positive urines.
Figures and Tables -
Analysis 6.4

Comparison 6 Medium‐dose buprenorphine versus placebo, Outcome 4 Benzodiazepine‐positive urines.

Comparison 7 High‐dose buprenorphine versus placebo, Outcome 1 Retention in treatment.
Figures and Tables -
Analysis 7.1

Comparison 7 High‐dose buprenorphine versus placebo, Outcome 1 Retention in treatment.

Comparison 7 High‐dose buprenorphine versus placebo, Outcome 2 Morphine‐positive urines.
Figures and Tables -
Analysis 7.2

Comparison 7 High‐dose buprenorphine versus placebo, Outcome 2 Morphine‐positive urines.

Comparison 7 High‐dose buprenorphine versus placebo, Outcome 3 Cocaine‐positive urines.
Figures and Tables -
Analysis 7.3

Comparison 7 High‐dose buprenorphine versus placebo, Outcome 3 Cocaine‐positive urines.

Comparison 7 High‐dose buprenorphine versus placebo, Outcome 4 Benzodiazepine‐positive urines.
Figures and Tables -
Analysis 7.4

Comparison 7 High‐dose buprenorphine versus placebo, Outcome 4 Benzodiazepine‐positive urines.

Summary of findings for the main comparison. Summary of findings: comparison between flexible‐dose methadone and buprenorphine

Buprenorphine maintenance compared with methadone maintenance for opioid dependence

Patient or population: People with opioid dependence.

Settings: Inpatient and outpatient

Intervention: Buprenorphine maintenance at flexible doses

Comparison: Methadone maintenance at flexible doses

Outcomes

Relative effect
(95% CI)

No of Participants
(studies)

Quality of the evidence
(GRADE)

Comments

Retention in treatment

RR 0.83

(0.73 to 0.95)*

11 (1391);

5 double‐blind (788)

6 open‐label (603)

⊕⊕⊕⊕
high

Greater retention in the methadone group.

* the heterogeneity is significant.

When the double‐blind studies are analysed separately the heterogeneity is not significant and the RR is 0.83 (0.72 to 0.95)

Morphine‐positive urines

SMD ‐0.11

(‐0.23 to 0.02)

8 (1027)

⊕⊕⊕⊝
moderate

No difference.

Self‐reported heroin use

SMD ‐0.11

(‐0.28 to 0.07)

4 (501)

⊕⊕⊕⊝
moderate

No difference.

Cocaine‐positive urines

SMD 0.10

(‐0.05 to 0.25)

6 (919)

⊕⊕⊕⊝
moderate

No difference.

Benzodiazepine‐positive urines

SMD 0.05

(‐0.09 to 0.18]

6 (859)

⊕⊕⊕⊝
moderate

No difference.

*The basis for the assumed risk (e.g. the median control group risk across studies) is provided in footnotes. The corresponding risk (and its 95% confidence interval) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI).
CI: Confidence interval; RR: Risk Ratio; SMD: standardised mean difference

GRADE Working Group grades of evidence
High quality: Further research is very unlikely to change our confidence in the estimate of effect.
Moderate quality: Further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate.
Low quality: Further research is very likely to have an important impact on our confidence in the estimate of effect and is likely to change the estimate.
Very low quality: We are very uncertain about the estimate.

Figures and Tables -
Summary of findings for the main comparison. Summary of findings: comparison between flexible‐dose methadone and buprenorphine
Summary of findings 2. Summary of findings for the comparison between high‐dose buprenorphine and placebo

Buprenorphine maintenance compared with methadone maintenance for opioid dependence

Patient or population: People with opioid dependence.

Settings: Inpatient and outpatient

Intervention: Buprenorphine maintenance at high doses (16 mg)

Comparison: Placebo

Outcomes

Relative effect
(95% CI)

No of Participants
(studies)

Quality of the evidence
(GRADE)

Comments

Retention in treatment

RR 1.82

(1.15 to 2.90)

1001 (5)

⊕⊕⊕⊕
high

Greater retention in buprenorphine group.

Morphine‐positive urines

SMD ‐1.17

(‐1.85 to ‐0.49)

729 (3)

⊕⊕⊕⊝
moderate

Fewer morphine‐positive urines in buprenorphine group.

Benzodiazepine‐positive urines

SMD ‐1.65

(‐4.94 to 1.65)

336 (2)

⊕⊕⊕⊝
moderate

No difference.

*The basis for the assumed risk (e.g. the median control group risk across studies) is provided in footnotes. The corresponding risk (and its 95% confidence interval) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI).
CI: Confidence interval; RR: Risk Ratio; SMD: standardised mean difference

GRADE Working Group grades of evidence
High quality: Further research is very unlikely to change our confidence in the estimate of effect.
Moderate quality: Further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate.
Low quality: Further research is very likely to have an important impact on our confidence in the estimate of effect and is likely to change the estimate.
Very low quality: We are very uncertain about the estimate.

Figures and Tables -
Summary of findings 2. Summary of findings for the comparison between high‐dose buprenorphine and placebo
Comparison 1. Flexible‐dose buprenorphine versus flexible‐dose methadone

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Retention in treatment Show forest plot

11

1391

Risk Ratio (M‐H, Random, 95% CI)

0.83 [0.73, 0.95]

1.1 Double‐blind flexible dose studies

5

788

Risk Ratio (M‐H, Random, 95% CI)

0.83 [0.72, 0.95]

1.2 Open label flexible dose studies

6

603

Risk Ratio (M‐H, Random, 95% CI)

0.80 [0.63, 1.02]

2 Morphine‐positive urines Show forest plot

8

1027

Std. Mean Difference (IV, Random, 95% CI)

‐0.11 [‐0.23, 0.02]

3 Self‐reported heroin use Show forest plot

4

501

Std. Mean Difference (IV, Random, 95% CI)

‐0.11 [‐0.28, 0.07]

4 Cocaine‐positive urines Show forest plot

6

919

Std. Mean Difference (IV, Random, 95% CI)

0.10 [‐0.05, 0.25]

5 Benzodiazepine‐positive urines Show forest plot

6

859

Std. Mean Difference (IV, Random, 95% CI)

0.05 [‐0.12, 0.22]

6 Criminal activity Show forest plot

2

328

Std. Mean Difference (IV, Fixed, 95% CI)

‐0.10 [‐0.31, 0.12]

Figures and Tables -
Comparison 1. Flexible‐dose buprenorphine versus flexible‐dose methadone
Comparison 2. Low‐dose buprenorphine versus low‐dose methadone

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Retention in treatment Show forest plot

3

253

Risk Ratio (M‐H, Random, 95% CI)

0.67 [0.52, 0.87]

2 Morphine‐positive urines Show forest plot

1

Std. Mean Difference (IV, Random, 95% CI)

Totals not selected

3 Self‐reported heroin use Show forest plot

1

Std. Mean Difference (IV, Random, 95% CI)

Totals not selected

4 Cocaine‐positive urines Show forest plot

1

Std. Mean Difference (IV, Random, 95% CI)

Totals not selected

Figures and Tables -
Comparison 2. Low‐dose buprenorphine versus low‐dose methadone
Comparison 3. Medium‐dose buprenorphine versus medium‐dose methadone

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Retention in treatment Show forest plot

7

780

Risk Ratio (M‐H, Random, 95% CI)

0.87 [0.69, 1.10]

2 Morphine‐positive urines Show forest plot

4

476

Std. Mean Difference (IV, Random, 95% CI)

0.25 [‐0.08, 0.58]

3 Self‐reported heroin use Show forest plot

2

174

Std. Mean Difference (IV, Random, 95% CI)

‐0.82 [‐1.83, 0.19]

4 Cocaine‐positive urines Show forest plot

2

219

Std. Mean Difference (IV, Random, 95% CI)

0.21 [‐0.06, 0.47]

Figures and Tables -
Comparison 3. Medium‐dose buprenorphine versus medium‐dose methadone
Comparison 4. High‐dose buprenorphine versus high‐dose methadone

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Retention in treatment Show forest plot

1

Risk Ratio (M‐H, Random, 95% CI)

Totals not selected

2 Self‐reported heroin use Show forest plot

1

Std. Mean Difference (IV, Random, 95% CI)

Totals not selected

Figures and Tables -
Comparison 4. High‐dose buprenorphine versus high‐dose methadone
Comparison 5. Low‐dose buprenorphine versus placebo

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Retention in treatment Show forest plot

5

1131

Risk Ratio (M‐H, Random, 95% CI)

1.50 [1.19, 1.88]

2 Morphine‐positive urines Show forest plot

2

487

Std. Mean Difference (IV, Random, 95% CI)

0.10 [‐0.80, 1.01]

3 Cocaine‐positive urines Show forest plot

1

Std. Mean Difference (IV, Random, 95% CI)

Totals not selected

4 Benzodiazepine‐positive urines Show forest plot

1

Std. Mean Difference (IV, Random, 95% CI)

Totals not selected

Figures and Tables -
Comparison 5. Low‐dose buprenorphine versus placebo
Comparison 6. Medium‐dose buprenorphine versus placebo

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Retention in treatment Show forest plot

4

887

Risk Ratio (M‐H, Random, 95% CI)

1.74 [1.06, 2.87]

2 Morphine‐positive urines Show forest plot

2

463

Std. Mean Difference (IV, Random, 95% CI)

‐0.08 [‐0.78, 0.62]

3 Cocaine‐positive urines Show forest plot

1

Std. Mean Difference (IV, Random, 95% CI)

Totals not selected

4 Benzodiazepine‐positive urines Show forest plot

1

Std. Mean Difference (IV, Random, 95% CI)

Totals not selected

Figures and Tables -
Comparison 6. Medium‐dose buprenorphine versus placebo
Comparison 7. High‐dose buprenorphine versus placebo

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Retention in treatment Show forest plot

5

1001

Risk Ratio (M‐H, Random, 95% CI)

1.82 [1.15, 2.90]

2 Morphine‐positive urines Show forest plot

3

729

Std. Mean Difference (IV, Random, 95% CI)

‐1.17 [‐1.85, ‐0.49]

3 Cocaine‐positive urines Show forest plot

1

Std. Mean Difference (IV, Random, 95% CI)

Totals not selected

4 Benzodiazepine‐positive urines Show forest plot

2

336

Std. Mean Difference (IV, Random, 95% CI)

‐1.65 [‐4.94, 1.65]

Figures and Tables -
Comparison 7. High‐dose buprenorphine versus placebo