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Methadone at tapered doses for the management of opioid withdrawal

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Abstract

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Background

The evidence of tapered methadone's efficacy in managing opioid withdrawal has been systematically evaluated in the previous version of this review that needs to be updated

Objectives

To evaluate the effectiveness of tapered methadone compared with other detoxification treatments and placebo in managing opioid withdrawal on completion of detoxification and relapse rate.

Search methods

We searched: Cochrane Central Register of Controlled Trials (The Cochrane Library 2012, Issue 4), PubMed (January 1966 to May 2012), EMBASE (January 1988 to May 2012), CINAHL (2003‐ December 2007), PsycINFO (January 1985 to December 2004), reference lists of articles.

Selection criteria

All randomised controlled trials that focused on the use of tapered methadone versus all other pharmacological detoxification treatments or placebo for the treatment of opiate withdrawal.

Data collection and analysis

Two review authors assessed the included studies. Any doubts about how to rate the studies were resolved by discussion with a third review author. Study quality was assessed according to the criteria indicated in the Cochrane Handbook for Systematic Reviews of Interventions.

Main results

Twenty‐three trials involving 2467 people were included. Comparing methadone versus any other pharmacological treatment, we observed no clinical difference between the two treatments in terms of completion of treatment, 16 studies 1381 participants, risk ratio (RR) 1.08 (95% confidence interval (CI) 0.97 to 1.21); number of participants abstinent at follow‐up, three studies, 386 participants RR 0.98 (95% CI 0.70 to 1.37); degree of discomfort for withdrawal symptoms and adverse events, although it was impossible to pool data for the last two outcomes. These results were confirmed also when we considered the single comparisons: methadone with: adrenergic agonists (11 studies), other opioid agonists (eight studies), anxiolytic (two studies), paiduyangsheng (one study). Comparing methadone with placebo (two studies) more severe withdrawal and more drop‐outs were found in the placebo group.

The results indicate that the medications used in the included studies are similar in terms of overall effectiveness, although symptoms experienced by participants differed according to the medication used and the program adopted.

Authors' conclusions

Data from literature are hardly comparable; programs vary widely with regard to the assessment of outcome measures, impairing the application of meta‐analysis. The studies included in this review confirm that slow tapering with temporary substitution of long‐ acting opioids, can reduce withdrawal severity. Nevertheless, the majority of patients relapsed to heroin use.

Plain language summary

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Methadone at tapered doses for the management of opioid withdrawal

Abuse of opioid drugs and dependence on them causes major health and social issues that include transmission of HIV and hepatitis C with injection, increased crime and costs for health care and law enforcement, family disruption and lost productivity. Addicts, particularly those aged 15 to 34 years, are also at higher risk of death. Managed withdrawal (or detoxification) is used as the first step in treatment. Withdrawal symptoms include anxiety, chills, muscle pain (myalgia) and weakness, tremor, lethargy and drowsiness, restlessness and irritability, nausea and vomiting and diarrhoea. Persisting sleep disturbances and drug craving can continue for weeks and months after detoxification and often lead to a return to opioid use. The number of addicts who complete detoxification tends to be low, and rates of relapse are high.

For a tapered dose treatment to reduce withdrawal symptoms, illicit opioids are replaced by methadone or another agent using decreasing doses up to 30 days under medical supervision. The review authors searched the medical literature and identified 23 controlled trials involving 2467 adult opioid users in various countries. Trial participants were randomised to receive methadone or another pharmacological treatment. The other treatments were adrenergic agonists such as lofexidine, partial opioid agonists such as buprenorphine, opioid agonists such as LAAM (levo‐α‐acetyl‐methadol) and the anxiolytics chlordiazepoxide and buspirone. In the two studies that compared methadone with placebo, withdrawal symptoms were more severe and more people dropped out in the placebo group.

The studies included in this review confirmed that slow tapering with temporary substitution of long‐ acting opioids, could reduce withdrawal severity. Nevertheless, the majority of patients relapsed to heroin use. The medications used in the included studies were similar in terms of overall effectiveness, although symptoms experienced by participants differed according to the medication used and the program adopted.

The programs varied widely with regard to the assessment of outcome measures. Seventeen of the included trials were conducted in inpatient settings.

Authors' conclusions

Implications for practice

The results indicate that tapered methadone and the other substances used in the included studies are effective in the treatment of heroin withdrawal syndrome, although symptoms presented by participants differed according to the drug used. The studies confirm the issue that with the increasing availability of substances that allow slow tapering and temporary substitution of long‐acting narcotics, with good medical supervision and ancillary medications for tranquillisation and sleep, withdrawal can be relatively painless. Managed withdrawal, or detoxification, is not in itself a treatment for dependence but detoxification remains a required first step for many forms of longer‐term treatment. Moreover, different conditions of detoxification can affect at least an immediate outcome: heroin use during treatment and produce different responses in terms of intensity and time course of withdrawal response.

Nevertheless, a majority of patients relapsed in heroin use, and relapse from the drug‐free state to re‐addiction is the main problem in heroin addiction.

Research suggests that for some important outcomes such as withdrawal symptoms, treatment programs are difficult to compare due to the variability of the methods used to assess them. Withdrawal limited to 30 days has the disadvantage that many persons, due to the rapid tapering, are prematurely withdrawn and consequently resume heroin use.

There has been a general pessimism among both clinicians and researchers about the utility of brief detoxification treatment because many patients soon returned to regular heroin use. This pessimism is probably based on the unrealistic expectation that a brief, inexpensive intervention could dramatically alter the course of a chronic, relapsing disorder such as heroin addiction. Whether people relapse to heroin use again has no bearing on the success or otherwise of a detoxification procedure and the investment in methadone detoxification could be justified if more modest goals were being achieved for example, the reduction, even temporarily, of the daily heroin dosage, with its consequent reduction of dependence on illegal income and the possibility of reaching drug addicts who would otherwise not have applied for treatment.

Implications for research

To enable comparison and pooling of results, standardised criteria for reporting urinalysis results should be used, data should be reported as number of participants with positive or negative samples instead of mean number of positive/negative tests for each group. When different rating instruments are used, researchers should try to utilise only published instruments, indicate the scores to represent boundaries of mild, moderate and severe withdrawal to allow comparison of results between studies and report the standard deviation of the means.

Summary of findings

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Summary of findings for the main comparison. Tapered methadone versus any other treatment for the management of opioid withdrawal

Tapered methadone versus any other treatment for the management of opioid withdrawal

Patient or population: patients with the management of opioid withdrawal
Settings: Inpatient and outpatient
Intervention: Tapered methadone versus any other treatment

Outcomes

Illustrative comparative risks* (95% CI)

Relative effect
(95% CI)

No of Participants
(studies)

Quality of the evidence
(GRADE)

Comments

Assumed risk

Corresponding risk

Control

Tapered methadone versus any other treatment

Completion of treatment
Objective
Follow‐up: mean 30 days

Study population

RR 1.08
(0.97 to 1.21)

1381
(16 studies)

⊕⊕⊕⊕
high

547 per 1000

591 per 1000
(531 to 662)

Moderate

505 per 1000

545 per 1000
(490 to 611)

Number of participants abstinent at follow‐up
Objective
Follow‐up: mean 1.5 months

Study population

RR 0.98
(0.7 to 1.37)

386
(3 studies)

⊕⊕⊕⊕
high

255 per 1000

250 per 1000
(179 to 350)

Moderate

267 per 1000

262 per 1000
(187 to 366)

*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;

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

Recent figures for illicit drug use indicate that the prevalence of opiate abuse among persons from 15 to 64 years old is around 0.5% in most Western countries (EU, USA, Canada and Australia) (UNODC 2011). Opioid dependence is a worldwide health problem that has enormous economic, personal and public health consequences. There are an estimated 15.6 million illicit opioid users in the world, of whom 11 million use heroin (UNODC 2011). Opioids are the main drugs of abuse in Asia, Europe and much of Oceania, and it is estimated that globally the consumption of the opioid class of drugs is increasing (UNODC 2011).

In Europe heroin is still one of the main illegal substance recorded in indicators of problem drug use (EMCDDA 2011). Recent national estimates vary between one and eight cases per 1000 population aged 15–64 (EMCDDA 2011). The average prevalence of problem opioid use in the European Union and Norway, computed from national studies, is estimated to be between 3.6 and 4.4 cases per 1000 population aged 15–64 (EMCDDA 2011). The latest US data, show that, on average, three persons per 100 annual drug users had to undergo treatment for drug use in 2008. Opiates use is far more problematic than the use of other illicit drugs (UNODC 2011). Australia has an estimated 67,000–92,000 illicit heroin users (540–750 per 100,000 population aged 15 to 64) (Hall 1999).

Opioids, mainly heroin, were cited as the primary drug for entering treatment by around 216,000 or 51 % of all those reported entering specialist drug treatment in 29 European countries in 2009. The provision of treatment is central to the reduction of the harms to the individual and the community from opioid dependence.

The effect of chronic opioid exposure on opioid receptor levels has not been well‐defined in humans. Tolerance develops through multiple mechanisms, including an acute desensitisation of the opioid receptor (which develops within minutes of opioid use and resolves within hours after use), and a long‐term desensitisation of the opioid receptor (which persists for several days after removal of opioid agonists). Changes also occur in the number of opioid receptors (Williams 2001), and there is compensatory up‐regulation of the cyclic adenosine monophosphate (cAMP) producing enzymes. When the opioid is withdrawn, the cAMP cascade becomes overactive, leading to the “noradrenergic storm” seen clinically as opioid withdrawal, which may create a drive to reinstate substance use. The intensely dysphoric withdrawal syndrome is characterised by watery eyes, runny nose, yawning, sweating, restlessness, irritability, tremor, nausea, vomiting, diarrhoea, increased blood pressure, chills, cramps and muscles aches that can last seven days or even longer.

Description of the intervention

Treatment of opioid dependence is a set of pharmacological and psychosocial interventions aimed at reducing or ceasing opioid use, preventing future harms associated with opioid use, improving quality of life and well‐being of the opioid‐dependent patient. Opioid withdrawal can be managed by controlling the rate of cessation of opioids and by providing medication that relieves symptoms, or by a combination of the two. Methadone at adequate doses prevents or reverses withdrawal symptoms (Ward 1992), and thus reduces the need to use illegal heroin (Jaffe 1990). Methadone remains effective for approximately 24 hours, requiring a single daily dose rather than the more frequent administration of three to four times daily that occurs with the shorter‐acting heroin (Jaffe 1990).

How the intervention might work

Methadone can "block" the euphoric effects of heroin, discouraging illicit use and thereby relieving the user of the need or desire to seek heroin (Dole 1969). This allows the opportunity to engage in normative activities, and "rehabilitation" if necessary. Methadone can cause death in overdosage, like other similar medications such as morphine, and for this reason it is a treatment which is dispensed under medical supervision and relatively strict rules. In summary, methadone is a long‐acting opioid analgesic with well‐understood pharmacological characteristics, which make it suitable for stabilising opioid‐dependent patients in a maintenance treatment approach. Methadone was first used to treat heroin dependence as a tapering agent in US facilities after the second world war and had been introduced in the treatment of opioid dependence for maintenance purposes rather than detoxification until the 1960's. Even though now it is often used for detoxification, sometimes this occurs for economical reasons, sometimes for ideological ones. Despite the risk of relapse being high, detoxification with methadone is common in many countries. The upper limit of duration of the tapered methadone withdrawal period appears to be relatively arbitrary; a period of three to four weeks has been recommended and used in clinical practice (Gossop 1987).

Why it is important to do this review

Different pharmacological agents have been used as detoxification agents to ameliorate withdrawal symptoms, however, the rate of completion of detoxification tends to be low, and rates of relapse to opioid use following detoxification are high (Gossop 1989B; Valliant 1988). The present review focuses on detoxification from illicit opiate use through the use of tapered methadone.There are no systematic reviews already published on the effectiveness of methadone at tapered doses on completion of detoxification or relapse rate.

The previous version of this review was published in 2005 and an update is required.

Objectives

To assess the effectiveness of methadone at tapered doses versus placebo or other pharmacological treatments for the management of detoxification on completion and acceptability of the treatment and relapse rate.

Methods

Criteria for considering studies for this review

Types of studies

All randomised controlled trials (RCTs) and controlled clinical trials (CCTs) on tapered methadone treatment (maximum 30 days) to manage withdrawal from opiates.

Types of participants

Opioid users enrolled in short‐term tapered methadone treatment to manage withdrawal from heroin or methadone or buprenorphine, no matter what the characteristic of the setting.Trials including patients with additional diagnoses such as benzodiazepine dependence were also eligible.

Pregnant women, newborn infants with neonatal dependence and people with iatrogenic dependence (e.g. through treatment of chronic pain) were excluded. The absence in these patient groups of social and psychological factors that underlie opioid dependence makes for a substantially different approach to clinical management. This was the basis for excluding these groups from this review (Gowing 2008).

Types of interventions

Experimental Intervention

  1. Methadone aimed at the detoxification from opiates, maximum length of treatment: 30 days

Control Interventions

  1. Other opioid agonists (LAAM (levo‐α‐acetyl‐methadol), Buprenorphine, propoxyphene, etc).

  2. Adrenergic agonists (clonidine, lofexidine, guanfacine).

  3. Opioid antagonists (naltrexone, naloxone).

  4. Placebo.

All aimed at the detoxification from opiate.

The setting in which withdrawal occurs is a factor that can be expected to influence outcomes. The degree of its effect has been explored by examining rate of completion of withdrawal.

Types of outcome measures

Primary outcomes

  1. Completion of treatment as number of participants completing the detoxification program.

  2. Acceptability of the treatment as a) duration and severity of signs and symptoms of withdrawal, including patient self‐rating, b) side effects.

  3. Results at follow‐up as (a) number of participants abstinent at follow‐up, (b) naloxone challenge.

Secondary outcomes

  1. Use of primary substance of abuse as a) number of participants who referred to the use of opioid during the treatment, b) number of participants with urine samples positive for opiate.

Different factors were considered as confounders and taken into account in the analysis wherever possible: setting ( inpatient or outpatient treatment); starting methadone dose/rate and pattern of dose reduction; scheduled duration of treatment; severity of dependence (duration of use, route of administration, frequency of assumption); health status; other treatment offered (psychosocial support); social status; number of previous treatment attempts and previous treatment outcomes.

Search methods for identification of studies

Electronic searches

We identified relevant studies that met the predefined inclusion criteria by searching the following sources from the earliest available date to December 2007. Relevant trials were obtained from the following sources:

  1. Cochrane Central Register of Controlled Trials (The Cochrane Library 2012, Issue 4) which include the Cochrane Drugs and Alcohol Group's Register of Trials.

  2. PubMed (from 2003 ‐ May 2012).

  3. EMBASE (from 2003 ‐ May 2012).

  4. CINAHL (from 2003 ‐ December 2011).

  5. PsycINFO (January 1985 to December 2004).

To see the search strategies seeAppendix 1; Appendix 2; Appendix 3; Appendix 4.

There were no language or publication year restriction.

Searching other resources

We also searched:

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

  2. Some of the main electronic sources of ongoing trials (meta‐Register of Controlled Trials; Clinical Trials.gov).

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

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

We contacted authors of included studies and experts in the field in various countries to find out if they know any other published or unpublished controlled trials

Data collection and analysis

Selection of studies

One review author (Amato) inspected the search hits by reading the titles and the abstracts. We obtained each potentially relevant study located in the search in full text and two review authors (Amato, Minozzi) independently assessed for inclusion. Doubts were resolved by discussion between the review authors.

Data extraction and management

Two review authors (Amato, Minozzi) independently extracted data from published sources using a data extraction form. Where differences in data extracted occurred this was resolved through discussion. Study quality was assessed by Silvia Minozzi according to the criteria indicated in Cochrane Handbook for Systematic Reviews of Interventions 4.2. (Higgins 2008)

Assessment of risk of bias in included studies

The risk of bias assessment  for RCTs and CCTs in this review were performed using the five criteria recommended by the Cochrane Handbook for Systematic Reviews of Interventions (Higgins 2008). The recommended approach for assessing risk of bias in studies included in Cochrane reviews is a two‐part tool, addressing five specific domains (namely sequence generation, allocation concealment, blinding, incomplete outcome data, and other issues). 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 relating to the risk of bias for that entry. This is achieved by answering a pre‐specified question about the adequacy of the study in relation to the entry, such that a judgement of "Yes" indicates low risk of bias, "No" indicates high risk of bias, and "Unclear" indicates unclear or unknown risk of bias. To make these judgments we used the criteria indicated by the handbook adapted to the addiction field.

Blinding of participants, personnel and outcome assessor (avoidance of performance bias and detection bias) were considered separately for objective outcomes (e.g. drop‐out, use of substance of abuse measured by urinalysis, participants relapsed at the end of follow‐up, participants engaged in further treatments) and subjective outcomes (e.g. duration and severity of signs and symptoms of withdrawal, patient self‐reported use of substance, side effects, social functioning as integration at school or at work, family relationship).

Incomplete outcome data (avoidance of attrition bias) were considered for all outcomes except for the drop‐out from the treatment, which is very often the primary outcome measure in trials on addiction. It was assessed separately for results at the end of the study period and for results at follow‐up.

Grading of evidence

The quality of evidence was assessed according to a systematic and explicit method (Guyatt 2008). In order to indicate the extent to which one can be confident that an estimate of effect is correct, judgments about the quality of evidence are made for each comparison and outcome. These judgments consider study design (RCT, quasi‐RCT or observational study), study quality (detailed study design and execution), consistency of results (similarity of estimates of effect across studies), precision of estimates, and directness (the extent to which people, interventions and outcome measures are similar to those of interest). The following definitions in grading the quality of evidence for each outcome are used: High: further research is very unlikely to change our confidence in the estimate of effect. Moderate: further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate. Low: further research is very likely to have an important impact on our confidence in the estimate of effect and may change the estimate. Very low: any estimate of effect is very uncertain.

Measures of treatment effect

We compared the treatment and control groups for outcomes at post‐test and at different follow‐up times. Post‐intervention data were collected immediately after the intervention ended. For continuous data it was not possible to pool data due to the heterogeneity of reporting in the included studies.

Dealing with missing data

Statisticians often use the terms ‘missing at random’, and ‘not missing at random’ to represent different scenarios. Data are said to be ‘missing at random’ if the fact that they are missing is unrelated to actual values of the missing data. Data are said to be ‘not missing at random’ if the fact that they are missing is related to the actual missing data. In cases where we assumed that data were missing at random, we analysed only the available data. If we assumed that the data were not missing at random, we planned to impute the missing data with replacement values, and to treat these as if they were observed. We planned to do this in different ways and compare the results (e.g. last observation carried forward, imputing an assumed outcome such as assuming all were poor outcomes, imputing the mean, imputing based on predicted values from a regression analysis). For the included studies in this review we did not impute data.

Assessment of heterogeneity

Statistically significant heterogeneity among primary outcome studies was assessed with Chi2 (Q) test and I2 (Higgins 2003). A significant Q ( P <.05) and I‐squared of at least 50% was considered as statistical heterogeneity.

Assessment of reporting biases

We used funnel plots for information about possible publication bias. But asymmetric funnel plots are not necessarily caused by publication bias (and publication bias does not necessarily cause asymmetry in a funnel plot). Whenever asymmetry was present, likely reasons were explored.

Data synthesis

Dichotomous outcomes (completion of treatment, number of participants with negative urinalysis) were analysed calculating the risk ratio (RR) for each trial with the uncertainty in each result being expressed by their confidence intervals (CIs). The RRs from the individual trials were combined through meta‐analysis where possible (comparability of intervention between trials) using a random‐effects model. The completion of the treatment was reported as the number of patients who completed the detoxification program. The use of primary substance was reported as the number of participants with consecutive negative urinalysis. The results at follow‐up were reported as the number of participants abstinent at the follow‐up interview (range of follow‐up period: one to six months). We used the Chi2 test to determine the heterogeneity of the results. A P value of the Chi2 test less than 0.005 indicated a significant heterogeneity.

Sensitivity analysis

The following sensitivity analyses were planned a priori: Generation of allocation sequence, concealment of allocation, blinding of patients and providers, blinding of assessors, incomplete outcome data addressed, selective reporting, and other bias.

Results

Description of studies

Results of the search

The literature searching process resulted in the identification of 8545 reports (6860 after duplicates removed), 6754 were excluded on the basis of title and abstract, 106 were retrieved in full text; 74 have been excluded and 23 (32 references) included, 17 studies included in quantitative synthesis (meta‐analysis). SeeFigure 1


Flow chart of studies

Flow chart of studies

Included studies

Twenty‐three studies (32 reports) meet the inclusion criteria for this review seeCharacteristics of included studies.

Duration of trials: range three to 30 days.
Treatment regimens and setting: The countries in which the 23 studies were conducted are: USA (six studies), United Kingdom (five studies), Spain (four studies), China, Irane and Germany (two studies each), Austria and Italy (one study each). Eighteen trials were conducted with inpatients, five with outpatients. Information on methadone doses were available for 19 of the 23 included studies. The mean starting dose of methadone was 29 mg/day (range 15 to 60). The other four studies reported that the starting doses of methadone were variable, tailored on individual body weight or heroin consumption in the previous month.

Participants: 2467 opiate addicts. Age range was 18 to 70 years; one study (Howells 2002) did not report age characteristics only that participants were required to be under 55 years old.

Comparisons:
In the 23 studies included in the review, tapered methadone was compared with the following.

  1. Tapered methadone versus any other treatments: 23 studies, 2467 participants.

  2. Tapered methadone versus adrenergic agonists: 11 studies, (Bearn 1996; Camí 1985; Dawe 1995; Gerra 2000; Howells 2002; Jiang 1993; Kleber 1985; San 1990; San 1994; Umbricht 2003; Washton 1981), 952 participants.

  3. Tapered methadone versus other opioid agonists: eight studies, (Madlung‐Kratzer 2009; Seifert 2002; Sorensen 1982; Steinmann 2007;Tennant 1975; Umbricht 2003; Wright 2011; Zarghami 2012), 869 participants.

  4. Tapered methadone versus anxiolytic: two studies (Buydens‐Branchey 2005; Drummond 1989), 47 participants.

  5. Tapered methadone versus placebo: two studies (Buydens‐Branchey 2005; San 1992), 38 participants.

  6. Tapered methadone versus paiduyangsheng: one study (Yang 2006), 580 participants.

One study (Umbricht 2003) has three arms, comparing methadone (arm 1) with buprenorphine (arm 2) and with clonidine (arm 3). For this study the participants in the methadone arm (21 people) are considered both in the comparison with adrenergic agonists and in the comparison with other opioid agonists. Another study (Buydens‐Branchey 2005) has four arms comparing methadone (arm 1) with placebo (arm 2), buspirone 30 mg (arm 3), buspirone 45 mg (arm 4). For this study the participants in the methadone arm (eight people) are considered in all the comparisons.

Two studies (Gerra 2000; San 1994) had three arms comparing methadone with different dosages of adrenergic agonist. For these studies we summarised the results of the two different dosages of adrenergic agonists. One study (San 1990) compared methadone with two different adrenergic agonists and we summarised the results of the two different adrenergic agonists.

Outcomes:
Outcomes were either dichotomous or continuous, as reported by authors. The following principal outcomes were considered by the authors.

  1. Completion of treatment as number of participants completing the detoxification program (16/23 studies).

  2. Withdrawal scores (21/23 studies).

  3. Side effects (16/23 studies).

  4. Use of primary substance measured as number of opiate positive urine samples (3/23 studies).

  5. Results at follow‐up as (a) number of participants abstinent at follow‐up (4/23 studies) and (b) naloxone challenge (2/23 studies).

Scales
The 23 studies that used withdrawal scales to assess withdrawal symptoms used 22 different scales (see Table 1 ), of which 15 were published. Furthermore, four studies considered craving using four different methods to assess it: Craving questionnaire (Dawe 1995), Craving Scale (Gerra 2000), Severity of Dependence Scale (SDS) (Howells 2002) and Addiction Severity Index ( Kleber 1985). Five studies use questionnaires to assess psychological and behavioural characteristics: State Trait Anxiety Inventory (Camí 1985; San 1990; San 1994), Beck Depression Inventory (Kleber 1985, San 1994), Eysenck Personality Questionnaire (San 1994), Hamilton Anxiety Rating Scale (Yang 2006) Profile of Mood State (San 1990), Hospital Anxiety Depression (San 1994). One study used an Intelligence Quotient test: Wechsler Adult Intelligence Scale (San 1990).

Open in table viewer
Table 1. Withdrawal scales

Author

Name of Scale

Published

n° items

n° scores

Bearn 1996

Short Opiate Withdrawal Scale (Gossop 1990)

yes

10

4

Buydens‐Branchey 2005

Subjective Opiate Withdrawal Scale (Handelsman 1987)

yes

16

5

Buydens‐Branchey 2005

Objective Opiate Withdrawal Scale (Handelsman 1987)

yes

13

3

Camí 1985

Abstinence Rating Scale

no

17

present/absent

Dawe 1995

Symptom Checklist (Powell 1990)

yes

10

4

Drummond 1989

Subjective Measures Questionnaire

no

16

not reported

Drummond 1989

Objective Opiate Withdrawal Scale (Himmelsbach 1942)

yes

10

4

Gerra 2000

List of Withdrawal Symptoms (Gerra 1995)

yes

9

5

Howells 2002

Withdrawal Problem Scale (Gossop 1990)

yes

20

4

Howells 2002

Short Opiate Withdrawal Scale (Gossop 1990)

yes

8

4

Jiang 1993

Himmelsbach Drug Withdrawal Symptoms Assessment Chart (Himmelsbach 1941)

yes

14

3

Kleber 1985

Himmelsbach Drug Withdrawal Symptoms Assessment Chart (Himmelsbach 1941)

yes

14

3

Kleber 1985

Self Rated Withdrawal Scale (Haertzen 1968)

yes

32

4

Kleber 1985

Observer rating scale (Kolb 1938)

yes

10

3

Madlung‐Kratzer 2009

Short OpioidWithdrawal Scale [German version] (Gossop 1990)

yes

12

4

Salehi 2007

Short Opioid Withdrawal Scale (Gossop 1990)

yes

16

4

San 1990

Daily Abstinence Rating Scale

no

21

present/absent

San 1990

Abstinence Signs

no

11

not reported

San 1990

Abstinence Symptoms

no

10

not reported

San 1992

Opiate Withdrawal Checklist (Schubert 1984)

yes

21

3

San 1994

Opiate Withdrawal Checklist (Schubert 1984)

yes

21

3

San 1994

Opiate Withdrawal Syndrome (Bradley 1987)

yes

not reported

11

Seifert 2002

Short Opiate Witdrawal Scale (Gossop 1990)

yes

not reported

not reported

Sorensen 1982

Detoxification Symptom Scale (Fulwiler 1979)

yes

20

not reported

Steinmann 2007

Clinical Opiate Withdrawal Scale (Wesson 2003)

yes

11

not reported

Steinmann 2007

Witdrawal Syndrome Scale

no

24

4

Tennant 1975

Himmelsbach Drug Withdrawal Symptoms Assessment Chart (Himmelsbach 1941)

yes

14

3

Umbricht 2003

Short Opiate Withdrawal Scale (Gossop 1990)

yes

10

4

Umbricht 2003

Observer Opioid Withdrawal Scale (Peachey 1988)

yes

11

not reported

Yang 2006

Opiate Withdrawal Scale

no

not reported

4

Zarghami 2012

Objective Opioid Withdrawal Scale (Handelsman 1987)

yes

13

3

Excluded studies

Seventhy‐four studies did not meet the criteria for inclusion in this review. The grounds for exclusion were: type of intervention: 39 studies; study design: 29 studies; study design and type of intervention: three studies; type of participants:one study; type of intervention and type of participants: one study, type of intervention and type of outcomes: one study; seeCharacteristics of excluded studies

Risk of bias in included studies

Overall the quality of the included studies was good, see Figure 2; Figure 3. Below the results of the single risk of bias are considered.


Methodological quality graph: review authors' judgements about each methodological quality item presented as percentages across all included studies.

Methodological quality graph: review authors' judgements about each methodological quality item presented as percentages across all included studies.


Methodological quality summary: review authors' judgements about each methodological quality item for each included study.

Methodological quality summary: review authors' judgements about each methodological quality item for each included study.

Allocation

Random Sequence Generation: three studies (Madlung‐Kratzer 2009; Sorensen 1982; Wright 2011) were judged at low risk of selection bias because the investigators described a random component in the sequence generation process. The other 20 studies were judged as having an unclear risk of bias because there was insufficient information about the sequence generation process to permit judgement.

Allocation concealment: seven studies (Drummond 1989; Howells 2002; Madlung‐Kratzer 2009; San 1992; San 1994; Sorensen 1982; Wright 2011) were judged at low risk of selection bias because investigators enrolling participants could not foresee assignment and the method of allocation concealment was described. The other 16 studies were judged at unclear risk because they did not describe the method of concealment or did not describe it in sufficient detail to allow a definite judgement.

Blinding

Blinding of participants and personnel: 18 studies (Bearn 1996; Buydens‐Branchey 2005; Camí 1985; Dawe 1995; Drummond 1989; Howells 2002; Kleber 1985; Madlung‐Kratzer 2009; Salehi 2007; San 1990; San 1992; Seifert 2002; Sorensen 1982; Tennant 1975; Umbricht 2003; Washton 1981; Wright 2011; Yang 2006) were judged to be at low risk of performance bias because participants and  providers were blinded and it was unlikely that the blinding could have been broken. One study (Gerra 2000) was judged at high risk of bias because it was not blinded and the remaining four studies (Jiang 1993; San 1994; Steinmann 2007; Zarghami 2012) were judged at unclear risk because it was not clear if a blinding condition had been undertaken.

Blinding of outcomes assessor: 12 studies (Bearn 1996; Buydens‐Branchey 2005; Camí 1985; Howells 2002; Kleber 1985; Salehi 2007; San 1990; San 1992; Sorensen 1982; Washton 1981; Wright 2011; Yang 2006) were judged at low risk of detection bias because it was specified that the outcome assessor was blinded. One study (Gerra 2000) was judged at high risk of bias because there was no blinding of outcome assessment. The remaining 10 studies were judged as having an unclear risk of bias because it was not clear if the outcome assessor was blind to treatment allocation.

Incomplete outcome data

Fiftheen studies (Bearn 1996; Camí 1985; Drummond 1989; Gerra 2000; Madlung‐Kratzer 2009; Salehi 2007; San 1990; San 1992; San 1994; Seifert 2002; Steinmann 2007; Tennant 1975; Umbricht 2003; Washton 1981; Wright 2011) were judged at low risk of attrition bias because all randomised patients were reported/analysed in the group to which they were allocated by randomisation, irrespective of non‐compliance and co‐interventions (intention‐to‐treat) or had no missing outcome data. Two studies (Buydens‐Branchey 2005; Zarghami 2012) were judged at high risk and the remaining six studies were judged at unclear risk.

Nevertheless, many outcomes could not be summarised because they were presented in graphical form or only provided statistical tests and P values. For most of the continuous variables standard deviation was not provided. Furthermore, the authors used different scales to compare the same or very similar outcomes and this makes it impossible to compare them.

In particular for the outcomes which we considered as possible confounders such as setting, starting methadone dose, severity of dependence, health status etc. and for others for example, patients' motivation at enrolment, it was not possible to perform statistical analysis because many authors did not report the relevant data and, were these were available, the data were heterogeneously reported.

Effects of interventions

See: Summary of findings for the main comparison Tapered methadone versus any other treatment for the management of opioid withdrawal

The results were summarised, with comparison of quantitative data where possible, first for methadone versus any other treatment and then comparing separately methadone versus single different treatments.

1. Tapered methadone versus any other pharmacological treatment

1.1 Completion of treatment

Sixteen studies (Bearn 1996; Buydens‐Branchey 2005; Drummond 1989; Howells 2002; Kleber 1985; Madlung‐Kratzer 2009; Salehi 2007; San 1990; San 1994; Seifert 2002; Sorensen 1982; Steinmann 2007; Tennant 1975; Umbricht 2003; Washton 1981; Wright 2011), 1381 participants risk ratio (RR) 1.08 (95% confidence interval (CI) 0.97 to 1.21); the difference was not statistically significant, seeFigure 4 or Analysis 1.1,


Forest plot of comparison: 1 Tapered methadone versus any other treatment, outcome: 1.1 Completion of treatment.

Forest plot of comparison: 1 Tapered methadone versus any other treatment, outcome: 1.1 Completion of treatment.

1.2 Results at follow‐up as number of participants abstinent at follow‐up

Three studies (Kleber 1985; Tennant 1975; Wright 2011), 386 participants (RR 0.98; 95% CI 0.70 to 1.37); the difference was not statistically significant, seeFigure 5 or Analysis 1.2


Forest plot of comparison: 1 Tapered methadone versus any other treatment, outcome: 1.2 Number of participants abstinent at follow‐up.

Forest plot of comparison: 1 Tapered methadone versus any other treatment, outcome: 1.2 Number of participants abstinent at follow‐up.

Results at follow‐up as naloxone challenge

Two studies reported data on this outcome, but only Gerra 2000 reported the rate of participants who accepted and continued naltrexone treatment: in the methadone group 9/34, in clonidine five days 17/32; RR 0.50 (95% CI 0.26 to 0.95), the difference was statistically significant in favour of clonidine.
Washton 1981 referred data for all the participants without distinction between the groups: of the eight participants who were opiate free at completion of the study, six began treatment with naltrexone.

Duration and severity of signs and symptoms of withdrawal

The diversity of approaches used for rating withdrawal severity, prevented a direct comparison of scores across studies. Different rating instruments were utilised and for many of them, the authors did not indicate the scores considered to represent boundaries of mild, moderate and severe to allow comparison of results between studies. The 21/23 studies that considered this outcome varied in how severity was rated and in the form in which results were reported. In some studies withdrawal was assessed by observers only, in others it was reported by participants and in others by both. In one study (Washton 1981), withdrawal was not systematically assessed and it was unclear how the assessment was undertaken. The diversity of approaches used for rating withdrawal severity prevented a direct comparison of scores across studies, consequently, we have not been able to make a quantitative analysis of the intensity of withdrawal. We tried to summarise the results in Table 2; Table 3; Table 4; Table 5; Table 6.

Open in table viewer
Table 2. Withdrawal symptoms and side effects methadone versus adrenergic agonists

Study

Withdrawal symptoms

Side effects

Bearn 1996

Mean scores higher for (1) on days 13‐21 and for (2) days 2‐12. Peak score on (1) day 13 and (2) day 10.

(2) 2 both female, experienced dizziness due to postural hypotension.

Camí 1985

Muscular aching, flatulence and drowsiness more common in (1). Sleep disturbance & weeping in (2).

1 of (2) had transferred loss of consciousness. (2) 4 (1) 1 experienced orthostatic hypotension. A graph shows a steady decline and similar magnitude in both groups regarding adverse effects, from days 1 to 6. After day 6, the scores for (1) increased, while in (2) continued to decline.

Dawe 1995

Minimum withdrawal scores, mean (1) 25 (2) 33; maximum (1) 69 (2) 53. Time points minimum (1) day 1 (2) day 7, maximum (1) day 10 (2) day 2/3.

Not reported.

Gerra 2000

In (2) mean scores slightly lower but not significantly lower than (3). During the last 4 days of treatment and after the first 4 days after methadone discontinuation; (1) mean scores significantly higher (2) than (3).

Mean daily blood pressure only for (2) & (3): no significant differences at any point. (2) 3 (3) 2 experienced side effects necessitate dose reduction.

Howells 2002

Lowest daily score: mean (1) 49.4 (2) 50.0 ; Highest daily score: mean (1) 67.6 (2) 69.3; Total mean (1) 572.1 (2) 596.1

Sitting blood pressure in (2) 4/32 lowest 61 mmHg, in (1) 3/36 lowest 80 mmHg, NS Depressive symptoms in 2 patients, one in each treatment group.

Jiang 1993

On day 1 no significant differences in the two groups, between days 2 and 4 higher in (2), between days 8 and 12 lower in (2).

The scores higher in (2) compared to (1) from days 1 to 7, the greatest difference occurred on day 2 of treatment when the mean side effects scores was (1) 1.9 and (2) 8.2. The score subsequently declined in both groups. Comparison of each undesirable side effect suggests that general tiredness, weakness in walking, dizziness in standing position, dry mouth and lethargy are most common occurrences in (2), while in (1) only a small numbers of patients experienced general tiredness, weakness in walking, dry mouth and lethargy . In (2) 89 experienced dizziness on standing, mostly in the second and third days of treatment. Anxiety scores were significantly lower in (2) by day 11.

Kleber 1985

Mean withdrawal scores at baseline and weeks 1‐2‐3‐4: at baseline no differences, during the first 2 weeks (1) 7.6, (2) 19.0, during the second two weeks (1) 13,0 (2) 12,0 ; Rates of withdrawal symptoms: (2) higher than (1); Comparison of withdrawal characteristics of success and failure in the groups were not statistically different.

Incidence of side effects, rated by physicians and nurses: (1) 11,5 (2) 16,8. Characteristics of side effects: for the majority of symptoms there were no differences among the two groups. Number using sleep medications: (1) 70% (2) 63%; Scores of Beck Depression Inventory between successfully drug‐free or not patients in the 2 groups were respectively: 54% and 17%. For the same groups, the percentage above the median for each ASI area were as follows: for medical area 62% and 46%, for employment 50% and 22%, for legal 35% and 22% , for family/social 31% and 28%, for psychological 31% and 28%.

San 1990

Mean daily withdrawal scores (graph): Significant differences between (1) and (2) on days 2, 3, 4 and 5, higher in (1); between (1) and (3) on days 2, 3, 4 and 11, higher in (3); no significant differences between (2) and (3); the maximum mean was (1) 4.9, (2) 8.1, (3) 7.6 all on day 2.

Hypotensive effect more intense in (2); changes in heart rate more pronounced in (2) than in (3); (1) and (3) most frequent side effects: asthenia, dry mouth, flushing, mental clouding, thirst. . Differences in personality tests and patient's mood: NS

San 1994

Mean daily withdrawal scores (graph): from day 9 higher in (2) and (3) for three days and in (1) after day 11, statistically significant between (1) and (3) on days 10,11 higher in (3); and between (1) and (2) on days 11,15, higher in (1); on day 20 higher in (3) compared with (1) and (2).

Differences in blood pressure and heart rate: for blood pressure, in (3) after day 13 grater decrease than in (1) and (2); for heart rate, in (3) bradycardia from day 9 with lowest rate on day 11, (62 beats per min); statistical significant difference between (3) compared with (1) and (2) in days 9, 10,11, 12,16, 17, 18, 19. Differences in personality tests and patient's mood: NS.

Umbricht 2003

Mean withdrawal scores at baseline, after the first dose of medication and during the treatment no significant differences in the magnitude of the decrease in withdrawal between the groups.

2 patients in (3) had to withdraw from the study because of decreased systolic blood pressure (< 90 mmHg) and bradycardia (HR < 50 BPM)

Washton 1981

Major symptomatic complaints, specifically lethargy, restlessness and insomnia were identical for both groups. The main items contributing to scores in both groups were sleep problems, anxiety/nervousness, irritability, lack of energy, aches/pains and feeling cold. (2) reported symptoms during the 1° week of the study whereas (1) in the last week.

Lethargy and sluggishness most consistent complaints in (2).

Open in table viewer
Table 3. Withdrawal symptoms and side effects methadone versus other opioid agonists

Study

Withdrawal symptoms

Side effects

Madlung‐Kratzer 2009

Changes in signs and symptoms of opioid withdrawal [12‐item German version of the Short Opioid Withdrawal Scale] assessed on days 0, 3, 7, 10, 14, 18 and 22 by patient self‐rating.

At study entry signs and symptoms of withdrawal were mild but deteriorated steadily over time (day 0 versus day 22, P < 0.001). The only difference between the groups was found on day 18 (P = 0.022). All symptoms showed a homogeneous pattern of changes. (1) day 0 8.15 6.48 (7.00), day 22 16.00 7.81(15.00) P < 0.001; (2) day 0: 8.07 6.09 (7.00) day 22:18.32 8.98 (18.00) P < 0.001

The incidence of adverse events was low; 16 (16%) patients in the SRM group and 13 (13%) patients in the methadone group experienced at least one adverse event (c2 test, P = 0.586). Thirty of 45 (67%) of all adverse events were rated as being unrelated, nine (20%) as possibly related (SRM: six patients; methadone: three patients) and one (2%) (methadone group) as probably related to the study drug. The majority of adverse events (23 of 45) were gastrointestinal system disorders, such as
nausea (three), vomiting (10), dentalgia (five), followed by psychiatric disorders (seven of 45, e.g. dysphoria, agitation, depression, panic attacks).

Seifert 2002

SOWS score (days 0‐2): no differences; weeks 1‐2 (2) fewer symptoms than (1); no differences in self‐rating scales

Not assessed.

Sorensen 1982

Mean symptom discomfort index initially declined then increased with drug taper. Initial, stabilisation and final ratings by graph: (1)18, 10, 15 (2) 16, 7, 16.

1 overdose incident, possibly due to combination with alcohol.

Steinmann 2007

Results in favour of buprenorphine only in the first day of treatment

Not assessed.

Tennant 1975

Mean daily withdrawal scores (1) 6.6 (2) 9.6. Difference significant on days 8, 12, 15, 16, 17.

Only one statistically significant difference. (1)6 [16.7%], (2)17 [47%] reported euphoria.

Umbricht 2003

Participant and observer rating scales: after first‐dose effect, further improvements were minimal, and overall mean scores during treatment were not significantly lower than scores after one treatment dose. The overall mean time averaged decreases ranged from‐5.1 to ‐6.0 for OOWS and ‐3.3 to ‐4.7 for SOWS. No significant differences in the magnitude of the decrease in the withdrawal between the treatment groups. At no time during treatment did withdrawal scores exceed baseline scores for any individual.

No major changes in blood pressure or heart rate during the observation time interval of the study. There was a trend (P = 0.06) toward myosis in the buprenorphine and methadone groups, consistent with a pharmacologic effect of treatment. Systolic blood pressure decreased significantly in the buprenorphine group.

Zarghami 2012

Statistical analysis revealed that significant decreases (P ≤ .04) were found in the OOWS scores in both treatment methods up to day 14; no statistically significant difference was found between OOWS scores of the treatment methods at different intervals (P ≥ .1), except for day 6 of the study (P = .03) where results were in favour of tramadol.

No significant differences were observed in side effects scores for dizziness, somnolence, ataxia, constipation, nausea, seizures, and respiratory depression between two treatment methods, except for perspiration and pain, which were significantly higher in tramadol (P = .02) and methadone (P = 0.01) treatment methods, respectively

OOWS: Objective Opioid Withdrawal Scale; SOWS: Short Opioid Withdrawal Scale

Open in table viewer
Table 4. Withdrawal symptoms and side effects methadone versus anxiolytics

Study

Withdrawal symptoms

Side effects

Buydens‐Branchey 2005

Subjective and Objective withdrawal scale: no significant differences between methadone and buspirone doses

Not assessed.

Drummond 1989

Significant higher scores in the chlordiazepoxide group only on day 3; at the end of the study, the scores were higher in the methadone group but not statistically significant. Analysis of individual items in the OWS (Opiate Withdrawal Scale) failed to implicate any particular item as being responsible for the difference between the two groups.

In methadone group relative bradycardia is more present in the first days of treatment and the difference with respect to the chlordiazepoxide group became statistically significant on days 4 and 7. As methadone was gradually withdrawn, the mean heart rate returned to a level comparable to the beginning period. Mean pupil size was less in methadone group during the treatment period and the difference was statistically significant on day 5, similarly mean temperature was lower in this group on day 3.

Open in table viewer
Table 5. Withdrawal symptoms and side effects methadone versus placebo

Study

Withdrawal symptoms

Side effects

Buydens‐Branchey 2005

Subjective and Objective scales: symptoms in placebo group were significantly more pronounced

Not assessed

San 1992

Higher scores in the placebo groups, with the most severe symptoms on day 1 to 15. 8/11 placebo‐treated patients needed to be switched from placebo to methadone because the OWC (Opiate Withdrawal Checklist) daily score was > 15. With respect to features of the withdrawal syndrome in placebo patients, two stages were observed: anxiety, chills, gooseflesh, myalgia and weakness were the most common on day 1 to 5 and sleep disturbance persisted on day 6 to 13.

Not assessed

Open in table viewer
Table 6. Withdrawal symptoms and side effects methadone versus paiduyangsheng

Study

Withdrawal symptoms

Side effects

Yang 2006

No differences between the two groups

Not assessed

Side effects

Adverse effects were reported in 12/23 studies and assessed in different ways. This variability prevented quantitative analysis of this outcome. Data are reported in Table 2; Table 3; Table 4; Table 5.

Use of primary substance as Number of participants with opiate positive urinalysis during the treatment

Only 3/22 studies (Gerra 2000; Sorensen 1982; Tennant 1975) reported data on the use of opiate during the treatment but their modalities of reporting results of urinalysis was heterogeneous, making meta‐analysis difficult to be carried out. Results as reported in the articles are hardly informative, and data presented as number of positive tests over number of tests cannot be properly analysed through meta‐analysis. In fact using tests instead of the participants as the unit of analysis violates the hypothesis of independence among observations, and makes the results of tests done in each patient not independent.

2. Tapered methadone versus adrenergic agonists

2.1 Completion of treatment

Seven studies (Bearn 1996; Howells 2002; Kleber 1985; San 1990; San 1994; Umbricht 2003; Washton 1981), 577 participants RR 1.10 (95% CI 0.91to 1.32); the difference was not statistically significant, seeAnalysis 2.1,

Use of primary substance as number of participants with opiate positive urinalysis during the treatment

One study (Gerra 2000), reported results of urine screening that showed a significantly higher rate of positive samples for morphine catabolites in the methadone and clonidine five‐days groups in respect of clonidine three days plus oxazepam, baclofen and ketoprofen group. No significant difference was found between the first two groups. In the methadone group, the positive urine rate increased significantly from day one to day 10.

Results at follow‐up as number of participants abstinent at follow‐up

One study (Kleber 1985), reported the number of participants abstinent at follow‐up at one month: 6/18 in methadone group and 4/15 in the clonidine group; at three months 5/19 in methadone and 4/15 in clonidine groups; at six months 7/18 in methadone and 3/13 in clonidine group. The differences were never statistically significant.

3. Tapered methadone versus any other opioid agonist

3.1 Completion of treatment

Seven studies (Madlung‐Kratzer 2009; Seifert 2002; Sorensen 1982; Steinmann 2007; Tennant 1975; Umbricht 2003; Wright 2011), 695 participants RR 1.10 (95% CI 0.89 to 1.37); the difference was not statistically significant, seeAnalysis 3.1.

Use of primary substance as number of participants with opiate positive urinalysis during the treatment

Two studies (Sorensen 1982; Tennant 1975) considered this outcome.

  • Sorensen 1982, (tapered methadone versus LAAM) reported that the proportion of participants using opiates never dropped below 50% for any group at any time. Exact figures were not reported, data were presented only in a graph. The groups did not differ in the percentage of urine samples that contained opiates overall.

  • Tennant 1975, (tapered methadone versus propoxyphene) reported the number of participants who had opiate‐negative urine on at least one occasion: 27/36 (75%) in methadone group and 19/36 (53%) in propoxyphene group; the difference is not statistically significant.

Results at follow‐up as number of participants abstinent at follow‐up

Three studies reported this outcome.

  • Sorensen 1982: (tapered methadone versus LAAM), the data were reported for all the participants without distinction between the groups of treatment 57/61 participants gave consent to be interviewed: 24/49 reported that they abstained from heroin > one day after detoxification, at three months 2/49 abstinent, 25/49 sought further treatment and 9/49 enrolled in methadone maintenance treatment.

  • Tennant 1975: (tapered methadone versus propoxyphene) reported that at one month follow‐up the number of abstinent were 15/32 in the methadone group and 13/32 in propoxyphene group; the difference is not statistically significant.

  • Wright 2011: (tapered methadone versus tapered buprenorphine) reported that at eight days post detoxification, there was no statistically significant difference in the odds of achieving abstinence between the methadone and buprenorphine arms (odds ratio (OR) = 1.69; 95% CI = 0.81 to 3.51; P = 0.163). Similarly, there was no statistically significant difference at one month (OR = 0.38; 95% CI = 0.13 to 1.10; P = 0.074) or three months (OR = 0.38; 95% CI = 0.13 to 1.10; P = 0.074), and insufficient data at the six‐month time point to undertake statistical analysis.

3.2 Tapered methadone versus buprenorphine
Completion of treatment

Four studies (Seifert 2002; Steinmann 2007; Umbricht 2003; Wright 2011) 390 participants RR 0.97 (CI 95% 0.69 to 1.37), the difference was not statistically significant, seeAnalysis 3.2.

3.3 Furthermore, single studies considered completion of treatment for the following comparisons

  • versus LAAM (Sorensen 1982), 5/15 patients in the methadone group and 4/13 in the LAAM group completed the treatment; RR 1.08 (CI 95% 0.37 to 3.21), the difference was not statistically significant but showed a trend in favour of LAAM;

  • versus propoxyphene (Tennant 1975), 25/36 in the methadone group and 15/36 in the propoxyphene group completed the treatment; RR 1.67 (CI 95% 1.07 to 2.60), the difference was statistically significant in favour of methadone group;

  • versus slow release morphine (Madlung‐Kratzer 2009), 49/100 in the methadone group and 50/102 in the slow release morphine group completed the treatment, RR 1.00 (CI 95% 0.75 to 1.32), the difference was not statistically significant.

4. Tapered methadone versus anxiolytic

4.1 Completion of treatment

Two studies (Buydens‐Branchey 2005; Drummond 1989), 47 participants RR 0.63 (CI 95% 0.18 to 2.24), the difference was not statistically significant and it should be considered that in one of the two studies (Buydens‐Branchey 2005) all the participants in both groups completed the treatment, seeAnalysis 4.1.

5.Tapered methadone versus placebo

5.1 Completion of treatment

Two studies (Buydens‐Branchey 2005; San 1992), 38 participants RR 1.95 (CI 95% 1.21 to 3.13), in favour of methadone, see Analysis 5.1,

Discussion

Summary of main results

Comparing methadone with other pharmacological treatments aimed at detoxification, studies showed no substantial clinical difference between the treatments in terms of completion of treatment, 16 studies 1381 participants, risk ratio (RR) 1.08 (95% confidence interval (CI) 0.97 to 1.21), number of participants abstinent at follow‐up, three studies, 386 participants (RR 0.98; 95% CI 0.70 to 1.37) and degree of discomfort for withdrawal symptoms and adverse events.

Comparing methadone with adrenergic agonists, studies showed no substantial clinical difference between the treatments in terms of completion of treatment, seven studies, 577 participants RR 1.10 (95% CI 0.91 to 1.32). with regard to the withdrawal symptoms and side effects, early withdrawal symptoms were less adequately controlled with lofexidine than methadone; in the methadone groups the symptoms were experienced only in the latter stages of treatment when the dosage of the substance was drastically reduced. Only in two single studies (San 1990; San 1994) was methadone more effective than adrenergic agonists in decreasing withdrawal signs and symptoms and causing fewer side effects.

Comparing methadone with other opioid agonists, the results did not show differences between the groups with regard to completion of treatment, seven studies, 695 participants RR 1.10 (95% CI 0.89 to 1.37) and the acceptability of the treatment. Comparing methadone with buprenorphine, no differences were found for completion of treatment, four studies, 390 participants RR 0.97 (CI 95% 0.69 to 1.37).

Comparing methadone with the anxiolytic buspirone (Buydens‐Branchey 2005) and chlordiazepoxide (Drummond 1989) results did not show differences between the groups in terms of completion of treatment, two studies, 47 participants RR 0.91 (95% CI 0.47 to 1.77).

Comparing tapered methadone with placebo, studies showed, as expected, results in favour of methadone for completion of treatment, two studies, 38 participants RR1.95 (95% CI 1.21 to 3.13) and control of withdrawal symptoms.

Overall completeness and applicability of evidence

The extent to which a Cochrane review can draw conclusions about the effects of an intervention depends on whether the data and results from the included studies are valid. However, systematic reviews should evaluate and take into account not only the internal validity (i.e., the extent to which systematic errors or bias are avoided) of each trial included but also the applicability and generalisability or external validity (i.e., whether the results of a trial can be reasonably applied to a definable group of patients in a particular setting in routine practice) (Dekkers 2009). The main threat to external validity comes from the clinical setting, and the social and cultural context in which the studies were conducted, and this is particularly true in the field of addiction, where these contexts can actively affect the overall treatment outcome.

In this review, besides the limits in external validity due to the general requirement of RCTs in terms of strict inclusion criteria, highly homogenous study groups, limitations in dose adjustment, etc., the types of participants (adults abusers/dependents on opioids) are quite representative of the general population of opioid dependents. Moreover, the interventions, the settings and the outcomes investigated (completion of treatment, abstinence during the treatment and at follow‐up, adverse events) are important to populations, practitioners and decision makers, and relevant for the context of current practice.

However, there are general questions difficult to answer on the basis of our results such as what are the treatment expectations? what defines treatment success? is success strictly limited to suppression of withdrawal symptoms? The studies included did not examine any carried over effects bearing on sustained abstinence or eventual remission of disease and this certanly is a limit. Furthermore onether important limitation to the generalisation of the evidence is the impossibility to cumulate results of very important outcomes such as abstinence at follow‐up and control of withdrawal symptoms due the different ways in which these outcomes are rated and reported in the single studies. Finally 17 out of 22 included trials were conducted in an inpatients' setting, which is probably not the most common setting in clinical practice for this type of intervention, and this could act as an effect modifier in the estimation of efficacy of treatment.

Quality of the evidence

The quality of evidence, assessed according to the GRADE method, may be judged as high for the efficacy of tapered methadone versus any other treatment for the management of opioid withdrawal, see Summary of findings table 1. In respect of risk of bias, the quality of evidence was moderate to high, the percentage of included studies judged at low risk of bias were as follow: selection bias 13% for sequence generation and 30% for allocation concealment; performance bias 78%; detection bias 52% and 65% for attrition bias.

Finally, the great heterogeneity of the scales used in the primary studies and the way in which results were reported made it not possible to undertake a cumulative analysis.

Potential biases in the review process

None known.

Flow chart of studies
Figures and Tables -
Figure 1

Flow chart of studies

Methodological quality graph: review authors' judgements about each methodological quality item presented as percentages across all included studies.
Figures and Tables -
Figure 2

Methodological quality graph: review authors' judgements about each methodological quality item presented as percentages across all included studies.

Methodological quality summary: review authors' judgements about each methodological quality item for each included study.
Figures and Tables -
Figure 3

Methodological quality summary: review authors' judgements about each methodological quality item for each included study.

Forest plot of comparison: 1 Tapered methadone versus any other treatment, outcome: 1.1 Completion of treatment.
Figures and Tables -
Figure 4

Forest plot of comparison: 1 Tapered methadone versus any other treatment, outcome: 1.1 Completion of treatment.

Forest plot of comparison: 1 Tapered methadone versus any other treatment, outcome: 1.2 Number of participants abstinent at follow‐up.
Figures and Tables -
Figure 5

Forest plot of comparison: 1 Tapered methadone versus any other treatment, outcome: 1.2 Number of participants abstinent at follow‐up.

Comparison 1 Tapered methadone versus any other treatment, Outcome 1 Completion of treatment.
Figures and Tables -
Analysis 1.1

Comparison 1 Tapered methadone versus any other treatment, Outcome 1 Completion of treatment.

Comparison 1 Tapered methadone versus any other treatment, Outcome 2 Number of participants abstinent at follow‐up.
Figures and Tables -
Analysis 1.2

Comparison 1 Tapered methadone versus any other treatment, Outcome 2 Number of participants abstinent at follow‐up.

Comparison 2 Tapered methadone versus adrenergic agonists, Outcome 1 Completion of treatment.
Figures and Tables -
Analysis 2.1

Comparison 2 Tapered methadone versus adrenergic agonists, Outcome 1 Completion of treatment.

Comparison 3 Tapered methadone versus other opioid agonists, Outcome 1 Completion of treatment methadone versus any other opioid agonist.
Figures and Tables -
Analysis 3.1

Comparison 3 Tapered methadone versus other opioid agonists, Outcome 1 Completion of treatment methadone versus any other opioid agonist.

Comparison 3 Tapered methadone versus other opioid agonists, Outcome 2 Completion of treatment methadone versus buprenorphine.
Figures and Tables -
Analysis 3.2

Comparison 3 Tapered methadone versus other opioid agonists, Outcome 2 Completion of treatment methadone versus buprenorphine.

Comparison 4 Tapered methadone versus anxiolytic, Outcome 1 Completion of treatment.
Figures and Tables -
Analysis 4.1

Comparison 4 Tapered methadone versus anxiolytic, Outcome 1 Completion of treatment.

Comparison 5 Tapered methadone versus placebo, Outcome 1 Completion of treatment.
Figures and Tables -
Analysis 5.1

Comparison 5 Tapered methadone versus placebo, Outcome 1 Completion of treatment.

Summary of findings for the main comparison. Tapered methadone versus any other treatment for the management of opioid withdrawal

Tapered methadone versus any other treatment for the management of opioid withdrawal

Patient or population: patients with the management of opioid withdrawal
Settings: Inpatient and outpatient
Intervention: Tapered methadone versus any other treatment

Outcomes

Illustrative comparative risks* (95% CI)

Relative effect
(95% CI)

No of Participants
(studies)

Quality of the evidence
(GRADE)

Comments

Assumed risk

Corresponding risk

Control

Tapered methadone versus any other treatment

Completion of treatment
Objective
Follow‐up: mean 30 days

Study population

RR 1.08
(0.97 to 1.21)

1381
(16 studies)

⊕⊕⊕⊕
high

547 per 1000

591 per 1000
(531 to 662)

Moderate

505 per 1000

545 per 1000
(490 to 611)

Number of participants abstinent at follow‐up
Objective
Follow‐up: mean 1.5 months

Study population

RR 0.98
(0.7 to 1.37)

386
(3 studies)

⊕⊕⊕⊕
high

255 per 1000

250 per 1000
(179 to 350)

Moderate

267 per 1000

262 per 1000
(187 to 366)

*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;

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. Tapered methadone versus any other treatment for the management of opioid withdrawal
Table 1. Withdrawal scales

Author

Name of Scale

Published

n° items

n° scores

Bearn 1996

Short Opiate Withdrawal Scale (Gossop 1990)

yes

10

4

Buydens‐Branchey 2005

Subjective Opiate Withdrawal Scale (Handelsman 1987)

yes

16

5

Buydens‐Branchey 2005

Objective Opiate Withdrawal Scale (Handelsman 1987)

yes

13

3

Camí 1985

Abstinence Rating Scale

no

17

present/absent

Dawe 1995

Symptom Checklist (Powell 1990)

yes

10

4

Drummond 1989

Subjective Measures Questionnaire

no

16

not reported

Drummond 1989

Objective Opiate Withdrawal Scale (Himmelsbach 1942)

yes

10

4

Gerra 2000

List of Withdrawal Symptoms (Gerra 1995)

yes

9

5

Howells 2002

Withdrawal Problem Scale (Gossop 1990)

yes

20

4

Howells 2002

Short Opiate Withdrawal Scale (Gossop 1990)

yes

8

4

Jiang 1993

Himmelsbach Drug Withdrawal Symptoms Assessment Chart (Himmelsbach 1941)

yes

14

3

Kleber 1985

Himmelsbach Drug Withdrawal Symptoms Assessment Chart (Himmelsbach 1941)

yes

14

3

Kleber 1985

Self Rated Withdrawal Scale (Haertzen 1968)

yes

32

4

Kleber 1985

Observer rating scale (Kolb 1938)

yes

10

3

Madlung‐Kratzer 2009

Short OpioidWithdrawal Scale [German version] (Gossop 1990)

yes

12

4

Salehi 2007

Short Opioid Withdrawal Scale (Gossop 1990)

yes

16

4

San 1990

Daily Abstinence Rating Scale

no

21

present/absent

San 1990

Abstinence Signs

no

11

not reported

San 1990

Abstinence Symptoms

no

10

not reported

San 1992

Opiate Withdrawal Checklist (Schubert 1984)

yes

21

3

San 1994

Opiate Withdrawal Checklist (Schubert 1984)

yes

21

3

San 1994

Opiate Withdrawal Syndrome (Bradley 1987)

yes

not reported

11

Seifert 2002

Short Opiate Witdrawal Scale (Gossop 1990)

yes

not reported

not reported

Sorensen 1982

Detoxification Symptom Scale (Fulwiler 1979)

yes

20

not reported

Steinmann 2007

Clinical Opiate Withdrawal Scale (Wesson 2003)

yes

11

not reported

Steinmann 2007

Witdrawal Syndrome Scale

no

24

4

Tennant 1975

Himmelsbach Drug Withdrawal Symptoms Assessment Chart (Himmelsbach 1941)

yes

14

3

Umbricht 2003

Short Opiate Withdrawal Scale (Gossop 1990)

yes

10

4

Umbricht 2003

Observer Opioid Withdrawal Scale (Peachey 1988)

yes

11

not reported

Yang 2006

Opiate Withdrawal Scale

no

not reported

4

Zarghami 2012

Objective Opioid Withdrawal Scale (Handelsman 1987)

yes

13

3

Figures and Tables -
Table 1. Withdrawal scales
Table 2. Withdrawal symptoms and side effects methadone versus adrenergic agonists

Study

Withdrawal symptoms

Side effects

Bearn 1996

Mean scores higher for (1) on days 13‐21 and for (2) days 2‐12. Peak score on (1) day 13 and (2) day 10.

(2) 2 both female, experienced dizziness due to postural hypotension.

Camí 1985

Muscular aching, flatulence and drowsiness more common in (1). Sleep disturbance & weeping in (2).

1 of (2) had transferred loss of consciousness. (2) 4 (1) 1 experienced orthostatic hypotension. A graph shows a steady decline and similar magnitude in both groups regarding adverse effects, from days 1 to 6. After day 6, the scores for (1) increased, while in (2) continued to decline.

Dawe 1995

Minimum withdrawal scores, mean (1) 25 (2) 33; maximum (1) 69 (2) 53. Time points minimum (1) day 1 (2) day 7, maximum (1) day 10 (2) day 2/3.

Not reported.

Gerra 2000

In (2) mean scores slightly lower but not significantly lower than (3). During the last 4 days of treatment and after the first 4 days after methadone discontinuation; (1) mean scores significantly higher (2) than (3).

Mean daily blood pressure only for (2) & (3): no significant differences at any point. (2) 3 (3) 2 experienced side effects necessitate dose reduction.

Howells 2002

Lowest daily score: mean (1) 49.4 (2) 50.0 ; Highest daily score: mean (1) 67.6 (2) 69.3; Total mean (1) 572.1 (2) 596.1

Sitting blood pressure in (2) 4/32 lowest 61 mmHg, in (1) 3/36 lowest 80 mmHg, NS Depressive symptoms in 2 patients, one in each treatment group.

Jiang 1993

On day 1 no significant differences in the two groups, between days 2 and 4 higher in (2), between days 8 and 12 lower in (2).

The scores higher in (2) compared to (1) from days 1 to 7, the greatest difference occurred on day 2 of treatment when the mean side effects scores was (1) 1.9 and (2) 8.2. The score subsequently declined in both groups. Comparison of each undesirable side effect suggests that general tiredness, weakness in walking, dizziness in standing position, dry mouth and lethargy are most common occurrences in (2), while in (1) only a small numbers of patients experienced general tiredness, weakness in walking, dry mouth and lethargy . In (2) 89 experienced dizziness on standing, mostly in the second and third days of treatment. Anxiety scores were significantly lower in (2) by day 11.

Kleber 1985

Mean withdrawal scores at baseline and weeks 1‐2‐3‐4: at baseline no differences, during the first 2 weeks (1) 7.6, (2) 19.0, during the second two weeks (1) 13,0 (2) 12,0 ; Rates of withdrawal symptoms: (2) higher than (1); Comparison of withdrawal characteristics of success and failure in the groups were not statistically different.

Incidence of side effects, rated by physicians and nurses: (1) 11,5 (2) 16,8. Characteristics of side effects: for the majority of symptoms there were no differences among the two groups. Number using sleep medications: (1) 70% (2) 63%; Scores of Beck Depression Inventory between successfully drug‐free or not patients in the 2 groups were respectively: 54% and 17%. For the same groups, the percentage above the median for each ASI area were as follows: for medical area 62% and 46%, for employment 50% and 22%, for legal 35% and 22% , for family/social 31% and 28%, for psychological 31% and 28%.

San 1990

Mean daily withdrawal scores (graph): Significant differences between (1) and (2) on days 2, 3, 4 and 5, higher in (1); between (1) and (3) on days 2, 3, 4 and 11, higher in (3); no significant differences between (2) and (3); the maximum mean was (1) 4.9, (2) 8.1, (3) 7.6 all on day 2.

Hypotensive effect more intense in (2); changes in heart rate more pronounced in (2) than in (3); (1) and (3) most frequent side effects: asthenia, dry mouth, flushing, mental clouding, thirst. . Differences in personality tests and patient's mood: NS

San 1994

Mean daily withdrawal scores (graph): from day 9 higher in (2) and (3) for three days and in (1) after day 11, statistically significant between (1) and (3) on days 10,11 higher in (3); and between (1) and (2) on days 11,15, higher in (1); on day 20 higher in (3) compared with (1) and (2).

Differences in blood pressure and heart rate: for blood pressure, in (3) after day 13 grater decrease than in (1) and (2); for heart rate, in (3) bradycardia from day 9 with lowest rate on day 11, (62 beats per min); statistical significant difference between (3) compared with (1) and (2) in days 9, 10,11, 12,16, 17, 18, 19. Differences in personality tests and patient's mood: NS.

Umbricht 2003

Mean withdrawal scores at baseline, after the first dose of medication and during the treatment no significant differences in the magnitude of the decrease in withdrawal between the groups.

2 patients in (3) had to withdraw from the study because of decreased systolic blood pressure (< 90 mmHg) and bradycardia (HR < 50 BPM)

Washton 1981

Major symptomatic complaints, specifically lethargy, restlessness and insomnia were identical for both groups. The main items contributing to scores in both groups were sleep problems, anxiety/nervousness, irritability, lack of energy, aches/pains and feeling cold. (2) reported symptoms during the 1° week of the study whereas (1) in the last week.

Lethargy and sluggishness most consistent complaints in (2).

Figures and Tables -
Table 2. Withdrawal symptoms and side effects methadone versus adrenergic agonists
Table 3. Withdrawal symptoms and side effects methadone versus other opioid agonists

Study

Withdrawal symptoms

Side effects

Madlung‐Kratzer 2009

Changes in signs and symptoms of opioid withdrawal [12‐item German version of the Short Opioid Withdrawal Scale] assessed on days 0, 3, 7, 10, 14, 18 and 22 by patient self‐rating.

At study entry signs and symptoms of withdrawal were mild but deteriorated steadily over time (day 0 versus day 22, P < 0.001). The only difference between the groups was found on day 18 (P = 0.022). All symptoms showed a homogeneous pattern of changes. (1) day 0 8.15 6.48 (7.00), day 22 16.00 7.81(15.00) P < 0.001; (2) day 0: 8.07 6.09 (7.00) day 22:18.32 8.98 (18.00) P < 0.001

The incidence of adverse events was low; 16 (16%) patients in the SRM group and 13 (13%) patients in the methadone group experienced at least one adverse event (c2 test, P = 0.586). Thirty of 45 (67%) of all adverse events were rated as being unrelated, nine (20%) as possibly related (SRM: six patients; methadone: three patients) and one (2%) (methadone group) as probably related to the study drug. The majority of adverse events (23 of 45) were gastrointestinal system disorders, such as
nausea (three), vomiting (10), dentalgia (five), followed by psychiatric disorders (seven of 45, e.g. dysphoria, agitation, depression, panic attacks).

Seifert 2002

SOWS score (days 0‐2): no differences; weeks 1‐2 (2) fewer symptoms than (1); no differences in self‐rating scales

Not assessed.

Sorensen 1982

Mean symptom discomfort index initially declined then increased with drug taper. Initial, stabilisation and final ratings by graph: (1)18, 10, 15 (2) 16, 7, 16.

1 overdose incident, possibly due to combination with alcohol.

Steinmann 2007

Results in favour of buprenorphine only in the first day of treatment

Not assessed.

Tennant 1975

Mean daily withdrawal scores (1) 6.6 (2) 9.6. Difference significant on days 8, 12, 15, 16, 17.

Only one statistically significant difference. (1)6 [16.7%], (2)17 [47%] reported euphoria.

Umbricht 2003

Participant and observer rating scales: after first‐dose effect, further improvements were minimal, and overall mean scores during treatment were not significantly lower than scores after one treatment dose. The overall mean time averaged decreases ranged from‐5.1 to ‐6.0 for OOWS and ‐3.3 to ‐4.7 for SOWS. No significant differences in the magnitude of the decrease in the withdrawal between the treatment groups. At no time during treatment did withdrawal scores exceed baseline scores for any individual.

No major changes in blood pressure or heart rate during the observation time interval of the study. There was a trend (P = 0.06) toward myosis in the buprenorphine and methadone groups, consistent with a pharmacologic effect of treatment. Systolic blood pressure decreased significantly in the buprenorphine group.

Zarghami 2012

Statistical analysis revealed that significant decreases (P ≤ .04) were found in the OOWS scores in both treatment methods up to day 14; no statistically significant difference was found between OOWS scores of the treatment methods at different intervals (P ≥ .1), except for day 6 of the study (P = .03) where results were in favour of tramadol.

No significant differences were observed in side effects scores for dizziness, somnolence, ataxia, constipation, nausea, seizures, and respiratory depression between two treatment methods, except for perspiration and pain, which were significantly higher in tramadol (P = .02) and methadone (P = 0.01) treatment methods, respectively

OOWS: Objective Opioid Withdrawal Scale; SOWS: Short Opioid Withdrawal Scale

Figures and Tables -
Table 3. Withdrawal symptoms and side effects methadone versus other opioid agonists
Table 4. Withdrawal symptoms and side effects methadone versus anxiolytics

Study

Withdrawal symptoms

Side effects

Buydens‐Branchey 2005

Subjective and Objective withdrawal scale: no significant differences between methadone and buspirone doses

Not assessed.

Drummond 1989

Significant higher scores in the chlordiazepoxide group only on day 3; at the end of the study, the scores were higher in the methadone group but not statistically significant. Analysis of individual items in the OWS (Opiate Withdrawal Scale) failed to implicate any particular item as being responsible for the difference between the two groups.

In methadone group relative bradycardia is more present in the first days of treatment and the difference with respect to the chlordiazepoxide group became statistically significant on days 4 and 7. As methadone was gradually withdrawn, the mean heart rate returned to a level comparable to the beginning period. Mean pupil size was less in methadone group during the treatment period and the difference was statistically significant on day 5, similarly mean temperature was lower in this group on day 3.

Figures and Tables -
Table 4. Withdrawal symptoms and side effects methadone versus anxiolytics
Table 5. Withdrawal symptoms and side effects methadone versus placebo

Study

Withdrawal symptoms

Side effects

Buydens‐Branchey 2005

Subjective and Objective scales: symptoms in placebo group were significantly more pronounced

Not assessed

San 1992

Higher scores in the placebo groups, with the most severe symptoms on day 1 to 15. 8/11 placebo‐treated patients needed to be switched from placebo to methadone because the OWC (Opiate Withdrawal Checklist) daily score was > 15. With respect to features of the withdrawal syndrome in placebo patients, two stages were observed: anxiety, chills, gooseflesh, myalgia and weakness were the most common on day 1 to 5 and sleep disturbance persisted on day 6 to 13.

Not assessed

Figures and Tables -
Table 5. Withdrawal symptoms and side effects methadone versus placebo
Table 6. Withdrawal symptoms and side effects methadone versus paiduyangsheng

Study

Withdrawal symptoms

Side effects

Yang 2006

No differences between the two groups

Not assessed

Figures and Tables -
Table 6. Withdrawal symptoms and side effects methadone versus paiduyangsheng
Comparison 1. Tapered methadone versus any other treatment

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Completion of treatment Show forest plot

16

1381

Risk Ratio (M‐H, Random, 95% CI)

1.08 [0.97, 1.21]

2 Number of participants abstinent at follow‐up Show forest plot

3

386

Risk Ratio (M‐H, Random, 95% CI)

0.98 [0.70, 1.37]

Figures and Tables -
Comparison 1. Tapered methadone versus any other treatment
Comparison 2. Tapered methadone versus adrenergic agonists

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Completion of treatment Show forest plot

7

577

Risk Ratio (M‐H, Random, 95% CI)

1.10 [0.91, 1.32]

Figures and Tables -
Comparison 2. Tapered methadone versus adrenergic agonists
Comparison 3. Tapered methadone versus other opioid agonists

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Completion of treatment methadone versus any other opioid agonist Show forest plot

7

695

Risk Ratio (M‐H, Random, 95% CI)

1.10 [0.89, 1.37]

2 Completion of treatment methadone versus buprenorphine Show forest plot

4

390

Risk Ratio (M‐H, Random, 95% CI)

0.97 [0.69, 1.37]

Figures and Tables -
Comparison 3. Tapered methadone versus other opioid agonists
Comparison 4. Tapered methadone versus anxiolytic

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Completion of treatment Show forest plot

2

47

Risk Ratio (M‐H, Random, 95% CI)

0.91 [0.47, 1.77]

Figures and Tables -
Comparison 4. Tapered methadone versus anxiolytic
Comparison 5. Tapered methadone versus placebo

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Completion of treatment Show forest plot

2

38

Risk Ratio (M‐H, Fixed, 95% CI)

1.95 [1.21, 3.13]

Figures and Tables -
Comparison 5. Tapered methadone versus placebo