Treatment regimens for active tuberculosis (TB) that are intermittent, or use rifampin during only the initial phase, offer practical advantages, but their efficacy has been questioned. We conducted a systematic review of treatment regimens for active TB, to assess the effect of duration and intermittency of rifampin use on TB treatment outcomes.
Methods and Findings
PubMed, Embase, and the Cochrane CENTRAL database for clinical trials were searched for randomized controlled trials, published in English, French, or Spanish, between 1965 and June 2008. Selected studies utilized standardized treatment with rifampin-containing regimens. Studies reported bacteriologically confirmed failure and/or relapse in previously untreated patients with bacteriologically confirmed pulmonary TB. Pooled cumulative incidences of treatment outcomes and association with risk factors were computed with stratified random effects meta-analyses. Meta-regression was performed using a negative binomial regression model. A total of 57 trials with 312 arms and 21,472 participants were included in the analysis. Regimens utilizing rifampin only for the first 1–2 mo had significantly higher rates of failure, relapse, and acquired drug resistance, as compared to regimens that used rifampin for 6 mo. This was particularly evident when there was initial drug resistance to isoniazid, streptomycin, or both. On the other hand, there was little evidence of difference in failure or relapse with daily or intermittent schedules of treatment administration, although there was insufficient published evidence of the efficacy of twice-weekly rifampin administration throughout therapy.
TB treatment outcomes were significantly worse with shorter duration of rifampin, or with initial drug resistance to isoniazid and/or streptomycin. Treatment outcomes were similar with all intermittent schedules evaluated, but there is insufficient evidence to support administration of treatment twice weekly throughout therapy.
Please see later in the article for the Editors' Summary
Citation: Menzies D, Benedetti A, Paydar A, Martin I, Royce S, et al. (2009) Effect of Duration and Intermittency of Rifampin on Tuberculosis Treatment Outcomes: A Systematic Review and Meta-Analysis. PLoS Med 6(9): e1000146. doi:10.1371/journal.pmed.1000146
Academic Editor: Megan Murray, Harvard School of Public Health, United States of America
Received: February 19, 2009; Accepted: July 31, 2009; Published: September 15, 2009
This is an open-access article distributed under the terms of the Creative Commons Public Domain declaration which stipulates that, once placed in the public domain, this work may be freely reproduced, distributed, transmitted, modified, built upon, or otherwise used by anyone for any lawful purpose.
Funding: Partial support for this review came from the WHO, while the Canadian Institutes of Health Research and the Fonds de la Recherche en Santé du Québec provided salary support for some authors. These funding sources had no role in the design or conduct of the study, nor the decision to submit the manuscript for publication.
Competing interests: The authors have declared that no competing interests exist.
Abbreviations: DOT, directly observed therapy; MDR, multi-drug resistance; TB, tuberculosis; WHO, World Health Organization
Tuberculosis—a contagious infection, usually of the lungs—kills nearly two million people annually. It is caused by Mycobacterium tuberculosis, bacteria that are spread in airborne droplets when people with tuberculosis cough. Most people infected with M. tuberculosis do not become ill—their immune system contains the infection. However, the bacteria remain dormant within the body and can cause tuberculosis years later if immunity declines because of, for example, infection with HIV (the virus that causes AIDS). The symptoms of tuberculosis include a persistent cough, weight loss and night sweats. The disease can usually be cured by taking several powerful antibiotics regularly for several months although drug-resistant tuberculosis is increasingly widespread. The standardized drug regimen recommended by the World Health Organization (WHO) for previously uninfected patients consists of an initial treatment phase, in which rifampin, isoniazid, ethambutol, and pyrazinamide are taken daily or thrice weekly for 2 months, and a continuation phase, in which two antibiotics are taken for a further 4–6 months.
Why Was This Study Done?
Resistance to rifampicin, which can develop if this drug is not taken regularly, is associated with poor treatment outcomes, particularly in patients infected with isoniazid-resistant M. tuberculosis. WHO recommends, therefore, that health-care workers watch patients take all their doses of rifampicin (“directly observed therapy”). Treatment regimens for tuberculosis that use rifampicin only during the initial phase and/or give rifampicin several times a week (intermittently) rather than daily would make direct observation of treatment much easier but are such regimens effective? In this study (which, together with two similar studies, was commissioned by WHO to provide the evidence needed for a revision of their treatment guidelines), the researchers undertook a systematic review (a search using specific criteria to identify relevant research studies, which are then appraised and analyzed according to an explicit protocol) and a meta-analysis (a statistical approach that pools the results of several studies) of published trials of various rifampicin-containing regimens for the treatment of tuberculosis in previously untreated patients.
What Did the Researchers Do and Find?
The researchers identified 57 randomized controlled trials (studies in which groups of patients are randomly assigned to different interventions) that reported the treatment failure and/or relapse rates (determined by seeing whether M. tuberculosis could be grown from sputum brought up from the lungs by coughing, so-called bacteriologically confirmed tuberculosis) associated with various rifampicin-containing treatment regimens. In their statistical analysis of the results of these trials (which involved more than 21,000 previously untreated patients), the researchers found that regimens that used rifampicin during only the first 1–2 months of treatment had higher rates of failure, relapse, and acquired drug resistance than regimens that used rifampicin for 6 months. Indeed, relapse rates decreased with the duration of rifampicin treatment up to 8 months of treatment. Furthermore, outcomes were particularly bad with regimens that included rifampicin during only the first 1–2 months of treatment if there was initial resistance to isoniazid and/or streptomycin (another antibiotic). Outcomes were similar, however, in regimens in which rifampicin was given daily throughout treatment, daily during the initial phase then twice or thrice weekly, or thrice weekly throughout treatment; insufficient evidence was available to evaluate the efficacy of regimens in which rifampicin was given twice weekly throughout treatment.
What Do These Findings Mean?
These findings suggest that tuberculosis treatment regimens for previously untreated patients who use rifampicin during only the first two months of treatment should be phased out and replaced by regimens that use rifampicin for 6 months, particularly in settings where there is likely to be resistance to isoniazid and/or streptomycin. This recommendation will be made in the planned 2009 revision of the WHO tuberculosis treatment guidelines. In addition, these findings suggest that giving rifampicin thrice weekly is as effective as giving it daily during the initial phase or throughout treatment. Importantly, these findings also indicate that more trials are needed to investigate other dosing schedules, to determine the optimal duration of treatment, and to determine the best way to manage patients infected with isoniazid-resistant bacteria. Finally, since very few of the trials identified in the systematic review included HIV-positive participants, trials designed to test drug regimens in people infected with both HIV and M. tuberculosis are urgently needed to reduce global deaths from tuberculosis.
Please access these Web sites via the online version of this summary at http://dx.doi.org/10.1371/journal.pmed.1000146.
- The results of another WHO-commissioned study into the treatment of tuberculosis are presented in a separate PLoS Medicine Research Article by Menzies et al. (Menzies D, Benedetti A, Paydar A, Royce S, Pai M, et al. (2009) Standardized Treatment of Active Tuberculosis in Patients with Previous Treatment and/or with Mono-resistance to Isoniazid: A Systematic Review and Meta-analysis. PLoS Med 6(9): e1000150. doi:10.1371/journal.pmed.1000150)
- The US National Institute of Allergy and Infectious Diseases provides information on all aspects of tuberculosis
- The US Centers for Disease Control and Prevention provide several facts sheets and other information resources about tuberculosis
- The American Thoracic Society, US Centers for Disease Control and Prevention, and Infectious Diseases Society of America have published guidelines on TB treatment
- The 2003 (2004 revision) WHO guidelines for national programs for the treatment of tuberculosis are available; WHO also provides information on efforts to reduce the global burden of tuberculosis (in several languages) and its 2009 annual report on global control of tuberculosis describes the current situation (key points are available in several languages)
- The WHO publishes guidelines on TB treatment
When rifampin was first introduced, it held the promise of exceptional potency as an agent for treatment of Mycobacterium tuberculosis (the cause of tuberculosis [TB]). A series of randomized trials, most conducted 20–35 y ago, established that rifampin-containing regimens could achieve high cure rates with as few as 6 mo of therapy, even when given intermittently . These trials ushered in the modern era of short-course chemotherapy and established the scientific rationale for the standardized regimens currently recommended by the World Health Organization (WHO) . WHO recommends direct observation of all doses of rifampin to prevent rifampin resistance, which is associated with much worse treatment outcomes, especially when combined with isoniazid resistance as multi-drug resistance (MDR) ,. This direct observation is facilitated by shorter duration of rifampin, and/or by intermittent dosing schedules.
However, the frequency of all forms of drug resistance has steadily increased in many countries over the last 20 y –. The effectiveness of current empiric regimens in treating patients with unrecognized initial drug resistance of any form, including isoniazid mono-resistance, is unclear since this was not a focus of earlier trials. In particular, the adequacy of regimens that use rifampin only in the initial phase, or are intermittent throughout, may be questionable in settings with increasing drug resistance. In addition, the individual trials that form the scientific basis for current therapy were mostly small trials with limited power to evaluate the duration and intermittency of rifampin use. Hence meta-analysis of these trials can allow evaluation of factors that may have a small but clinically relevant effect on treatment outcomes.
In light of these uncertainties, we have conducted a systematic review of treatment regimens for active TB, to provide a basis for recommendations for revised treatment guidelines.
Our systematic review aimed to address two specific questions:
- What are the rates of treatment failure, relapse, and acquired drug resistance if rifampin is given only in the initial intensive phase (the first 1–2 mo), compared to longer duration?
- What are the rates of treatment failure, relapse, and acquired drug resistance with different dose administration schedules of therapy?
We searched three electronic databases—PubMed, Embase, and the Cochrane CENTRAL database—for studies of treatment of active TB (i.e., disease). The search was restricted to randomized controlled trials published in English, French, and Spanish from 1965 up to June 2008. Our keywords included tuberculosis or TB, treatment or therapy, failure or relapse, or drug resistance. To identify additional relevant articles, we searched reference lists of identified original articles, recent systematic reviews –, a review of all the British Medical Research Council trials , recent treatment guidelines ,, and texts ,.
We included original reports of randomized controlled trials that reported treatment outcomes of bacteriologically confirmed failure and/or relapse. In selected trials, all patients had active pulmonary TB that was bacteriologically confirmed by AFB smear microscopy and/or mycobacterial culture, and had not been previously treated (i.e., were new cases). Treatment was standardized and included at least isoniazid and rifampin. We excluded trials or arms that included rifapentine or rifabutin therapy or non-drug therapy (e.g., immunotherapeutic vaccines). We also excluded trials, or arms, that involved once-weekly or mono-drug therapy, as these are now considered inadequate ,.
The selection of articles for review was done independently by two investigators in three stages: titles alone, followed by abstracts, and then full text articles. Decisions were compared and disagreements about study selection were resolved by consensus or by involving a third reviewer.
Data Extraction and Quality Assessment
We reviewed all selected studies using standardized forms to extract data about patient population and characteristics, treatment regimens, pretreatment drug-susceptibility testing, supervision of treatment, funding source, and number of patients who started treatment, defaulted or were otherwise lost, died, failed, or relapsed. Two reviewers extracted the data, with disagreements resolved by consensus.
We restricted the studies reviewed to randomized trials with bacteriologic confirmation of initial diagnosis, failure, and/or relapse—considered high-quality methods. Included studies were considered of high quality if less than 10% of patients refused therapy, dropped out, moved away, or were otherwise unaccounted for during therapy. In addition, randomized trials were considered high quality if they used an allocation concealment approach such as central randomization, numbered opaque sealed envelopes, sealed envelopes from a closed bag, numbered or coded bottles or containers, or if treatments were assigned by a central pharmacy.
In line with internationally accepted definitions , treatment failure was defined as sputum smears and/or cultures that were consistently positive or requiring treatment at the end of therapy (if less than 5 mo) or after at least 5 mo of therapy. Relapse was defined as recurrence of positive smears and/or cultures that required therapy after completion of treatment with apparent cure. Initial drug resistance was defined as pretreatment resistance in patients without a history of previous treatment, and categorized as pan-sensitive, isoniazid resistant, streptomycin resistant, or resistant to both—termed poly-drug resistance. Patients with initial rifampin resistance, including MDR, were excluded from analysis, if identified in the published report. Acquired drug resistance was defined as new or additional resistance to one or more of the TB drugs received, among failures or relapses.
Data Synthesis and Analysis
We were interested in understanding the efficacy of different regimens in preventing failure, relapse, and acquired drug resistance—end-points with objective microbiological definitions that were consistent across trials. Therefore, we used a per-protocol analysis, excluding patients who did not complete therapy because they developed serious adverse reactions, died, defaulted, dropped out, or were otherwise not accounted for.
We restricted our first analysis to those trials within which regimens differed by the duration of rifampin, or dosing schedule (intermittency), but were otherwise comparable. To increase the number of trials with head-to-head comparisons analyzed, regimens were considered comparable even if they differed by ethambutol or thiacetazone. For each trial with head-to-head comparisons, we calculated cumulative incidence of failure, relapse, and acquired drug resistance, and the Mantel-Haenszel pooled difference in cumulative incidence and 95% confidence interval (CI) for each comparison . One advantage of this method is that 0-cell corrections are not necessary to calculate the MH pooled risk difference . We assessed heterogeneity of risk differences for each comparison, by estimating the I2 statistic and associated 95% CIs . For this calculation, studies in which both arms had no events were corrected by 0.5.
Because few trials with head-to-head comparisons were identified, in our second analysis we pooled results across all trials, effectively treating each arm within each trial as an independent cohort. For the across-trial analysis, we used a random effects meta-analysis to estimate the overall pooled estimates of cumulative incidence and 95% CI of failure, relapse, and acquired drug resistance using Proc Nlmixed in SAS (SAS Institute, Carey, NC, USA) . We used the exact binomial likelihood approach , which uses a binomial distribution to approximate the distribution of the outcome of interest. This approach accounts for study size and includes a random effect to account for between-study heterogeneity. When proportions are the outcome measure, this approach has been demonstrated to produce less-biased estimates of the pooled effect and the between-study variability . We assessed heterogeneity of proportions of participants with outcomes of interest, within subgroups defined by covariates of interest by estimating the I2 statistic and associated 95% CIs . To calculate I2, 0-cells were corrected by 0.5.
To minimize heterogeneity, we performed subgroup analyses stratified by predefined covariates of interest. These included duration and dosing schedule of rifampin, initial drug resistance, use of pyrazinamide or streptomycin, and number of drugs to which the organism was susceptible used in the initial or continuation phase (the initial intensive phase was defined as the initial period when more drugs were used—usually the first 1–2 mo—while the continuation phase was the remainder of therapy). We also examined the effect of supervision of therapy (i.e. directly observed therapy [DOT]), proportion that were smear positive, and default or other losses during treatment phase follow-up.
Finally, meta-regression was used to estimate the effect of the treatment factors of interest, after adjustment for other potentially confounding patient and treatment covariates. Because the outcomes we were pooling were proportions rather than odds ratios, and because these proportions were usually small, we performed meta-regression using the Poisson model  that allowed for overdispersion (i.e., negative binomial regression). In this meta-regression, each arm in each study was the unit of analysis, cumulative incidence of TB treatment outcomes was the dependent variable, and TB treatment characteristics were the independent variables. An offset was used to account for size of study. In this approach, residual heterogeneity between studies is accounted for in the dispersion parameter. As such we interpreted the dispersion parameter as indicating there was no remaining unexplained heterogeneity if the value was not significantly different from zero and as minimal heterogeneity if the value was less than 1.0 . Effect estimates of the meta-regression model were interpreted as adjusted incidence rate ratios (IRR) . We tested the significance of each factor in the models using the likelihood ratio test. Two models were used. The first included rifampin duration, intermittent schedule, use of pyrazinamide and streptomycin, number of drugs in initial or continuation phases to which organisms were susceptible, length of follow-up after end of treatment (for relapse and acquired drug resistance), directly observed therapy (DOT), and non-completion of therapy because of protocol violations, patient refusal, default, moved, or lost. The second model included initial drug resistance with all the same factors, except the number of sensitive drugs in initial or continuation phases—which could not be included because of substantial co-linearity between these factors and drug resistance.
Description of Included Trials
As seen in Figure 1, 2,215 citations were identified from the search of the three electronic databases. Of these, 237 were retained for abstract review and 166 for full text review. An additional 135 full texts were identified from the search of the references of the original articles and other sources. After full text review, 75 papers describing 57 randomized trials were selected for this analysis. These trials, summarized in Appendix Table 1 in Text S1 –, included a total of 21,472 participants in 312 different treatment arms. Of these, 612 patients died and 2,775 dropped out, were lost, or were otherwise not accounted for. This left 18,701 analyzable participants in all trials. Failure was analyzed for 18,085 participants in 56 studies; relapse was reported for 15,558 participants in 53 trials, while acquired drug resistance was reported for 11,400 participants in 39 trials (Table 1). All trials involved adults, and in 42 all patients were smear positive, although cultures were used to define study end-points in all but three trials ,,. Only four trials included HIV-infected persons, with a total of 522 HIV-infected participants. Rifampin dose was not stated in two trials ,, was 450 mg/d in three trials with a total of 618 patients ,,, and was 600 mg/d (or 10–12 mg/kg) in all the remaining studies. In 30 trials (52%) all treatment doses were supervised, and in 29 (51%) less than 10% refused, defaulted, or were lost during treatment. Randomization was described in 41 trials, and was adequate in 40, but not described in 16 trials. Median post-treatment follow-up was 24 mo (interquartile range: 18–30).
Figure 1. Summary of literature search and study selection.doi:10.1371/journal.pmed.1000146.g001
Table 1. Summary of studies reviewed (all randomized controlled trials with rifampin-containing regimens in new cases).doi:10.1371/journal.pmed.1000146.t001
Results of Head-to-Head Comparisons
As seen in Table 2, in the studies with head-to-head comparisons, rates of failure (Table 2) were significantly higher in patients who received only 1–2 mo of rifampin than in patients who received longer durations of rifampin. Rates of relapse (Table 3) were progressively lower with longer duration of rifampin up to 8 mo or more. In the only trial which compared four different durations of rifampin (6 versus 9, 12, and 18 mo), all outcomes were the same with the three longer regimens ,. Acquired drug resistance (Table 4) was not associated with shorter duration of rifampin, but this outcome was uncommon and reported in fewer trials—limiting power. All five of the studies with head-to-head comparisons of intermittent schedules compared different regimens and schedules, so results could not be pooled (Table 5).
Table 2. Pooled risk differences from direct head-to-head comparisons of rifampin duration or intermittent schedules in otherwise comparable regimens: Failure.doi:10.1371/journal.pmed.1000146.t002
Table 3. Pooled risk differences from direct head-to-head comparisons of rifampin duration or intermittent schedules in otherwise comparable regimens: Relapse.doi:10.1371/journal.pmed.1000146.t003
Table 4. Pooled risk differences from direct head-to-head comparisons of rifampin duration or intermittent schedules in otherwise comparable regimens: Acquired drug resistance.doi:10.1371/journal.pmed.1000146.t004
Table 5. Pooled risk differences from direct head-to-head comparisons of rifampin duration or intermittent schedules otherwise comparable regimens.doi:10.1371/journal.pmed.1000146.t005
Pooled Results across Trials
When results were pooled across all 57 trials, rifampin was given for 1 mo in 12 arms, 2 mo in 60, 5 mo in 6, 6 mo in 170, and 7 mo in 2. Regimens with 1–2 mo of rifampin had higher failure (Table 6) and relapse (Table 7) rates than regimens with longer duration rifampin. Relapse rates were progressively lower with longer rifampin duration, up to 8 mo or more of rifampin (see Figure S1).
Table 6. Stratified estimates of treatment failures in RCT in new cases.doi:10.1371/journal.pmed.1000146.t006
Table 7. Stratified estimates of relapse in RCT in new cases.doi:10.1371/journal.pmed.1000146.t007
With regard to the different intermittent schedules compared, evidence regarding therapy given twice weekly throughout was limited to a single study of 223 patients who received 12 mo of isoniazid and rifampin—daily or twice weekly ,. Rates of failure, relapse, and acquired drug resistance were less than 1%. Because this was a single study, these results could not be pooled and are not considered further in stratified or multivariate analyses. The other schedules, of daily, daily then thrice weekly, daily then twice weekly, and thrice weekly throughout, were evaluated in numerous studies. As seen in Tables 6–8, there were no significant differences in outcomes between these four different treatment schedules.
Table 8. Stratified estimates of acquired drug resistance in RCT in new cases.doi:10.1371/journal.pmed.1000146.t008
Of the other factors considered, initial drug resistance was associated with increased risk of failure, relapse, and acquired drug resistance. In the presence of initial isoniazid or isoniazid and streptomycin resistance (poly-drug resistance ), regimens using 1–2 mo of rifampin had failure rates of 6.5% (95% CI: 0.7%–12.3%) or 29% (10%–53%), respectively, in comparison with 0.2% (0%–0.5%) in pan-sensitive TB, and relapse rates of 38% (29%–46%) or 27% (10%–44%), respectively, compared to 8.2% (4.5%–11.9%) in pan-sensitive TB. Acquired drug resistance was also increased if there was initial drug resistance, but this effect appeared similar with all durations of rifampin. Interestingly, failure and acquired drug resistance were progressively lower with use of more drugs to which the organisms were sensitive in the initial phase (up to four drugs), and also associated (but less strongly) with the number of drugs to which the organisms were sensitive in the continuation phase.
When adjusted for potentially confounding treatment factors in multivariate regression, regimens with 1–2 mo of rifampin were associated with significantly higher failure, relapse, and acquired drug resistance rates than the reference group of 6 mo of rifampin (Table 9). Interestingly, adjusted relapse rates were lower with regimens using rifampin for at least 8 mo than with the 6-mo rifampin reference group. None of the intermittent schedules was significantly associated with failure or relapse, although acquired drug resistance was increased with two of the three intermittent regimens. Streptomycin use was protective against failure, relapse, and acquired drug resistance, while pyrazinamide use was protective only for relapse.
Table 9. Adjusted incidence rate ratios of failure, relapse, and acquired drug resistance (from negative binomial regression).doi:10.1371/journal.pmed.1000146.t009
The proportion smear positive, proportion HIV infected, and duration of post-treatment follow-up were not associated with treatment outcomes and were not included in final regression models. Poor completion of treatment was associated with failure or relapse, whereas supervision of therapy was not; both factors were included in final multivariate models, although estimates are not shown. Dispersion estimates for all three final models were less than 1, suggesting that the treatment factors included in these models accounted for the majority of the heterogeneity in outcomes seen.
In this review of 57 trials with rifampin-containing regimens, use of rifampin only initially rather than throughout treatment was associated with worse treatment outcomes (higher rates of failure, relapse, and acquired drug resistance). Thrice-weekly intermittent dosing schedules during the initial treatment phase were associated with increased adjusted risk of acquired drug resistance, but not relapse or failure. Initial drug resistance was strongly associated with increased risk of poor treatment outcomes, particularly if rifampin was used only in the initial intensive phase. These findings have important implications for TB treatment.
The most important finding of this review is that all three treatment outcomes were significantly worse with regimens that used rifampin for the first 1–2 mo rather than throughout therapy. This finding adds considerable weight to similar findings by Jindani and colleagues, who compared regimens containing 2 mo versus 6 mo of rifampin . This review includes many more studies with a variety of regimens, making these results more robust and generalizable. In this review, the failure and relapse rates progressively declined with long duration of rifampin; such a dose–response relationship strengthens the conclusions that a longer duration of rifampin treatment is responsible for better outcomes. Finally, this review included studies where drug sensitivity testing was performed, which permitted us to detect an increased risk of acquired drug resistance with shorter rifampin duration and also permitted stratified analysis by underlying drug resistance, which proved to be a very important determinant of treatment outcomes. According to the most recent information from WHO , the 8-mo regimen was the recommended initial therapy in 24 high-incidence countries. Based on the pooled risk differences from within trial analyses, we estimate that treatment of 100 patients with the regimen of 2HRZE/6HE (the “8-mo” regimen) would result in 13 more failures and relapses than if they received 2HRZE/4HR (the “6-mo” regimen). As a result, forthcoming recommendations by WHO will recommend only the 6-mo (rifampin throughout) regimen, and the 8-mo regimen will no longer be recommended . Results of this review suggest that the public health benefits of switching from the 8-mo to the 6-mo regimen should be very considerable.
The lower risk of relapse with regimens using rifampin for at least 8 mo is consistent with subgroup analyses of other trials  and a recent cohort report from Hong Kong . These have shown that patients with extensive cavitary pulmonary disease have increased risk of relapse with 6-mo regimens. Taken together these findings support recommendations to extend therapy for patients at high risk of relapse . However, accurate identification of high-risk patients is imprecise, and provision of extended therapy may be challenging in high-burden settings.
The lack of effect of intermittency is interesting but has several caveats. The timing of intermittent dosing may be quite important, as suggested by the finding of increased risk of acquired resistance associated with thrice-weekly therapy throughout. A cohort study from New York City reported that patients with HIV–TB coinfection had an increased risk of acquired rifamycin resistance if they were treated with twice-weekly therapy during the initial intensive phase but not if they were treated with intermittent dosing only during the continuation phase .
Te other important finding is the previously underestimated impact of primary isoniazid resistance on failure, relapse, and acquired resistance. This important effect is a powerful argument for widespread availability of rapid, inexpensive testing for resistance to isoniazid (as well as for rifampin), or for regimens that do not require optimal activity from isoniazid. The influence of primary streptomycin resistance is likely to be less important, since streptomycin has been replaced by ethambutol in most settings.
The primary objective of this review was to compare the efficacy of different durations and dosing schedule of rifampin. To accomplish this, we have analyzed the per-protocol results from each trial, using standardized microbiological definitions. All studies reviewed reported adverse events, dropouts, and defaulters separately, facilitating our approach. However, we did not include these outcomes because they are not as well defined nor standardized, potentially creating greater between-study variability. As well, inter-study differences in providers and populations could have very important influences on these outcomes—even greater than any biologic differences in disease response. These would be balanced within each trial but could have created substantial bias with our analytic approach. If dropout, default, or side effects were associated with the same characteristics as failure or relapse, then excluding these outcomes could underestimate the poor outcomes associated with shorter rifampin exposures. But if not, then including these outcomes would simply reduce all differences between regimens.
This review had several limitations. First, we could identify few trials with direct head-to-head comparisons of rifampin duration, and even fewer directly comparing intermittent regimens. Hence, we had to pool results across studies; this increases potential confounding from differences in treatment, patients' disease severity, or other differences in the study populations, since the studies were conducted in many different countries. The advantage of this approach is that we are able to include many more trials, thereby increasing the precision and avoiding selection bias . However, the disadvantage is the greater potential for bias due to between-trial differences in participant characteristics, treatment regimens, as well as the differential impact of dropouts and other losses to follow-up . Concern about this latter problem should be alleviated by the consistent results from three analytic approaches—within the smaller set of trials with head-to-head comparisons, across all 57 trials, and the multivariate analysis. Also, the dispersion estimates from multivariable analysis suggest that treatment factors and underlying drug resistance accounted for almost all the differences in outcomes observed.
Most trials were initiated before 1980, limiting the number of participants with HIV infection and drug resistance. The lack of trials in HIV infected persons with active TB meant that the question of rifampin duration in treatment of HIV-TB could not be answered, due to insufficient power. This underscores the paucity of recent TB treatment trials and the urgent need for trials in drug resistant and/or HIV infected populations. There were no trials in children, reflecting a lack of rigorous trials in this population and the difficulties of microbiologic confirmation in this population. Death was not analyzed, because most TB-related deaths occur soon after diagnosis and are determined by comorbidity, age, severity of illness, and delay in diagnosis ,. Deaths later in treatment are often from other causes ,. Hence, differences in the TB treatment regimen may have relatively little impact on mortality. We endeavored to minimize language bias by including studies published in French and Spanish as well as English. Interestingly, this yielded only three additional trials, or 5% of all trials included. In a recent review , of all TB related papers listed in PubMed over 10 y, papers published in English, French, and Spanish represented 84% of all published literature worldwide. Hence, this review can be considered reasonably representative of publications in this field. However, in some fields, such as mental health, PubMed will fail to list a substantial proportion of relevant publications from low- to middle-income countries , so we may have missed some important trials.
Finally, we were not able to distinguish between relapse of the same strain of M. tuberculosis that caused the initial infection and reinfection with a new strain of the bacillus. In settings with high rates of ongoing exposure to M. tuberculosis, particularly if HIV seroprevalence is also high, a relatively high proportion of cases of recurrent TB following initial apparent cure may be due to reinfection . However, very few participants had HIV coinfection in the studies reviewed, and in studies with longer follow-up, the great majority of relapses occurred in the first 1–2 y, with very few occurring in the third to fifth years. This suggests that reinfection should have accounted for very few of the disease recurrences. Because follow-up was adequate in almost all studies—only four studies had less than 1-y follow-up—unequal follow-up should not have affected results—supported by the finding that duration of post-treatment follow-up was not associated with relapse rates in multivariable analysis.
This review provides evidence against continued use of regimens that utilize rifampin for the first 2 mo only, as they are significantly and substantially inferior to regimens that use rifampin for at least 6 mo. This review also has identified an important need for adequately powered clinical trials that address dosing schedules, management of isoniazid mono-resistance, and the optimal duration of treatment to prevent relapse.
Forest plots of relapse rates with different duration of rifampin. Only patients with drug-sensitive organisms in studies where drug-sensitive testing was performed are shown.
(3.53 MB TIF)
Characteristics of studies reviewed. Appendix Table 1: Rifampin duration directly compared, and regimens otherwise comparable; Appendix Table 2: Intermittent regimens, directly compared head to head within studies and with otherwise comparable regimens; Appendix Table 3: Regimens differed by rifampin duration but also by other important factors; Appendix Table 4: Regimens differed by intermittent schedule, but also by other important factors; Appendix Table 5: No internal comparison of rifampin duration, nor of intermittent schedules; Appendix Table 6: Randomized trials in which only one arm could be analyzed.
(0.40 MB DOC)
The authors would like to thank Malgorzata Grzemska, who provided assistance at every stage of the review; Woojin Lew, who identified a number of studies included in this review; the medical librarian at the Montreal Chest Institute, Ibtisam Mahmoud, for assistance in finding published studies; and Ria Choe, for secretarial assistance.
ICMJE criteria for authorship read and met: DM AB AP IM SR MP AV CL WB. Agree with the manuscript's results and conclusions: DM AB AP IM SR MP AV CL WB. Designed the experiments/the study: DM. Analyzed the data: DM AB. Collected data/did experiments for the study: AP IM WB. Wrote the first draft of the paper: DM. Contributed to the writing of the paper: DM AB AP SR MP AV CL WB. Helped develop statistical analysis plan, helped with interpretation of results: AB. Provided input on systematic review methodology: MP. Participated in critical discussion of the draft initial findings and in revision of the manuscript: AV.
- 1. Fox W, Ellard GA, Mitchison DA (1999) Studies on the treatment of tuberculosis undertaken by the British Medical Research Council tuberculosis units, 1946–1986, with relevant subsequent publications. Int J Tuberc Lung Dis 3: S231–S279.
- 2. World Health Organization (2004) Treatment of tuberculosis: guidelines for national programmes WHO/CDS/TB/2003.313 (Revised June 2004). WHO 313: 1–108.
- 3. Mitchison DA, Nunn AJ (1986) Influence of initial drug resistance on the response to short-course chemotherapy of pulmonary tuberculosis. Am Rev Respir Dis 133: 423–430.
- 4. Caminero JA (2006) Treatment of multidrug resistant tuberculosis: evidence and controversies. Int J Tuberc Lung Dis 10: 829–837.
- 5. Espinal MA, Laszlo A, Simonsen L, Boulahbal F, Kim SJ, et al. (2001) Global trends in resistance to antituberculosis drugs. World Health Organization-International Union against Tuberculosis and Lung Disease Working Group on Anti-Tuberculosis Drug Resistance Surveillance. N Engl J Med 344: 1294–1303.
- 6. World Health Organization (2008) Anti-tuberculosis drug resistance in the world (Report no. 4). WHO/HTM/TB/2008.
- 7. WHO and IUATLD (2008) Anti-tuberculosis drug resistance in the world (Report no. 4)
- 8. Han T (2006) Effectiveness of standard short-course chemotherapy for treating tuberculosis and the impact of drug resistance on its outcome. Int J Evid Based Healthc 4: 101–117.
- 9. Mwandumba HC, Squire SB (2008) Fully intermittent dosing with drugs for treating tuberculosis in adults. Cochrane Database of Systematic Reviews.
- 10. Cox HS, Morrow M, Deutschmann PW (2008) Long term efficacy of DOTS regimens for tuberculosis: systematic review. BMJ 336: 484–487.
- 11. Gelband H (1999) Regimens of less than six months for treating tuberculosis (review). Cochrane Database of Systematic Reviews 1.
- 12. Fox W, Ellard GA, Mitchison DA (1999) Studies on the treatment of tuberculosis undertaken by the British Medical Research Council tuberculosis units, 1946–1986, with relevant subsequent publications. Int J Tuberc Lung Dis 3: S231–S279.
- 13. American Thoracic Society, Infectious Diseases Society of America, Centres for Disease Control (2003) Treatment of tuberculosis. Am J Respir Crit Care Med 167: 603–662.
- 14. Public Health Agency of Canada and Canadian Lung Association/Canadian Thoracic Society (2007) Canadian tuberculosis standards. Toronto: Canadian Lung Association, Public Health Agency of Canada, Tuberculosis Prevention and Control.
- 15. Page KR, Chaisson RE (2006) Tuberculosis - HIV coinfection: epidemiology, clinical aspects, and interventions. In: Raviglione MC, editor. Reichman and Hershfield's tuberculosis a comprehensive, international approach. New York: Informa HealthCare. pp. 371–416.
- 16. Rieder HL (2002) Interventions for tuberculosis control and elimination. Paris: International Union against Tuberculosis and Lung Disease.
- 17. World Health Organization, International Union against Tuberculosis and Lung Disease (IUATLD), Royal Netherlands Tuberculosis Association (2001) Revised international definitions in tuberculosis control. Int J Tuber Lung Dis 5: 213–215.
- 18. Bradburn MJ, Deeks JJ, Berlin JA, Localio AR (2007) Much ado about nothing: a comparison of the performance of meta-analytical methods with rare events. Statist Med 26: 53–77.
- 19. Higgin JPT, Thompson SG (2004) Controlling the risk of spurious findings from meta-regression. Stat Med 23: 1663–1682.
- 20. Hamza TH, Houwelingen HC, Stijnen T (2008) The binomial distribution of meta-analysis was preferred to model within-study variability. J Clin Epidemiol 61: 41–51.
- 21. Glasziou PP, Sanders SL (2002) Investigating causes of heterogeneity in systematic reviews. Stat Med 21: 1503–1511.
- 22. Thompson SG, Sharp SJ (1999) Explaining heterogeneity in meta-analysis: a comparison of methods. Stat Med 18: 2693–2708.
- 23. Singapore Tuberculosis Service, British Medical Research Council (1975) Controlled trial of intermittent regimens of rifampicin plus isoniazid for pulmonary tuberculosis in Singapore. Lancet 306: 1105–1109.
- 24. East African-British Medical Research Council Study (1972) Controlled clinical trial of short-course (6 month) regimens of chemotherapy for treatment of pulmonary tuberculosis. Lancet 299: 1079–1085.
- 25. Tuberculosis Research Centre (1983) Study of chemotherapy regimens of 5 and 7 months' duration and the role of corticosteroids in the treatment of sputum-positive patients with pulmonary tuberculosis in South India. Tuberc 64: 73–91.
- 26. Jindani A, Nunn AJ, Enarson DA (2004) Two 8-month regimens of chemotherapy for treatment of newly diagnosed pulmonary tuberculosis: international multicentre randomised trial. Lancet 364: 1244–1251.
- 27. Singapore Tuberculosis Service-British Medical Research Council (1977) Controlled trial of intermittent regimens of rifampin plus isoniazid for pulmonary tuberculosis in Singapore. the results up to 30 months. Am Rev Respir Dis 116: 807–820.
- 28. Hong Kong Chest-British Medical Research Council (1981) Controlled trial of four twice-weekly regimens and a daily regimen all given for 6 months for pulmonary tuberculosis. Lancet 317: 171–174.
- 29. Balasubramanian R, Sivasubramanian S, Vijayan VK, Ramachandran R, Jawahar MS, et al. (1990) Five year results of a 3-month and two 5-month regimens for the treatment of sputum-positive pulmonary tuberculosis in south India. Tuberc 71: 253–258.
- 30. East African-British Medical Research Council (1973) Controlled clinical trial of four short-course (6-month) regimens of chemotherapy for treatment of pulmonary tuberculosis. second report. Lancet 1: 1331–1338.
- 31. East African-British Medical Research Council (1974) Controlled clinical trial of four short-course (6-month) regimens of chemotherapy for treatment of pulmonary tuberculosis. third report. Lancet 2: 237–240.
- 32. East African-British Medical Research Council (1976) Controlled clinical trial of four (6-month) 3 regimens of chemotherapy for pulmonary tuberculosis. second report. Am Rev Respir Dis 114: 471–475.
- 33. Third East African-British Medical Research Council (1978) Controlled clinical trial of four short-course regimens of chemotherapy for two durations in the treatment of pulmonary tuberculosis: first report. Am Rev Respir Dis 118: 39–48.
- 34. Third East African-British Medical Research Council (1980) Controlled clinical trial of four short-course regimens of chemotherapy for two durations in the treatment of pulmonary tuberculosis. second report. Tuberc 61: 59–69.
- 35. Hong Kong Chest Service and British Medical Research Council (1978) Controlled trial of 6-month and 8-month regimens in the treatment of pulmonary tuberculosis. first report. Am Rev Respir Dis 118: 219–228.
- 36. Hong Kong Chest Service and British Medical Research Council (1979) Controlled trial of 6-month and 8-month regimens in the treatment of pulmonary tuberculosis: the results up to 24 months. Tuberc 60: 201–210.
- 37. Singapore Tuberculosis Service-British Medical Research Council (1979) Clinical trial of six-month and four-month regimens of chemotherapy in the treatment of pulmonary tuberculosis. Am Rev Respir Dis 119: 579–585.
- 38. Singapore Tuberculosis Service-British Medical Research Council (1981) Clinical trial of six-month and four-month regimens of chemotherapy in the treatment of pulmonary tuberculosis: the results up to 30 months. Tuberc 62: 95–102.
- 39. Singapore Tuberculosis Service-British Medical Research Council (1986) Long-term follow-up of a clinical trial of six-month and four-month regimens of chemotherapy in the treatment of pulmonary tuberculosis. Am Rev Respir Dis 133: 779–783.
- 40. Hong Kong Chest Service-British Medical Research Council (1982) Controlled trial of 4 three-times-weekly regimens and a daily regimen all given for 6 months for pulmonary tuberculosis. second report: the results up to 24 months. Tuberc 63: 89–98.
- 41. Hong Kong Chest Service-British Medical Research Council (1987) Five-year follow-up of a controlled trial of five 6-month regimens of chemotherapy for pulmonary tuberculosis. Am Rev Respir Dis 136: 1339–1342.
- 42. Algerian Working Group-British Medical Research Council (1984) Controlled clinical trial comparing a 6-month and a 12-month regimen in the treatment of pulmonary tuberculosis in the Algerian Sahara. Am Rev Respir Dis 129: 921–928.
- 43. East and Central African-British Medical Research Council (1983) Controlled clinical trial of 4 short-course regimens of chemotherapy (three 6-month and one 8-month) for pulmonary tuberculosis. Tuberc 64: 153–166.
- 44. East and Central African-British Medical Research Council Fifth Collaborative (1986) Controlled clinical trial of 4 short-course regimens of chemotherapy (three 6-month and one 8-month) for pulmonary tuberculosis: final report. Tuberc 67: 5–15.
- 45. Tanzania-British Medical Research Council (1985) Controlled clinical trial of two 6-month regimens of chemotherapy in the treatment of pulmonary tuberculosis. Am Rev Respir Dis 131: 727–731.
- 46. Singapore Tuberculosis Service-British Medical Research Council (1985) Clinical trial of three 6-month regimens of chemotherapy given intermittently in the continuation phase in the treatment of pulmonary tuberculosis. Am Rev Respir Dis 132: 374–378.
- 47. Singapore Tuberculosis Service-British Medical Research Council (1988) Five-year follow-up of a clinical trial of three 6-month regimens of chemotherapy given intermittently in the continuation phase in the treatment of pulmonary tuberculosis. Am Rev Respir Dis 137: 1147–1150.
- 48. Hong Kong Chest Service-Tuberculosis Research Centre MBMRC (1991) A controlled clinical comparison of 6 and 8 months of antituberculosis chemotherapy in the treatment of patients with silicotuberculosis in Hong Kong. Am Rev Respir Dis 143: 262–267.
- 49. Hong Kong Chest Service-British Medical Research Council (1991) Controlled trial of 2, 4, and 6 months of pyrazinamide in 6-month, three-times-weekly regimens for smear-positive pulmonary tuberculosis, including an assessment of a combined preparation of isoniazid, rifampin, and pyrazinamide. results at 30 months. Am Rev Respir Dis 143: 700–706.
- 50. Singapore Tuberculosis Service-British Medical Research Council (1991) Assessment of a daily combined preparation of isoniazid, rifampin, and pyrazinamide in a controlled trial of three 6-month regimens for smear-positive pulmonary tuberculosis. Am Rev Respir Dis 143: 707–712.
- 51. Kenyan-Zambian-British Medical Research Council (1989) Controlled clinical trial of levamisole in short-course chemotherapy for pulmonary tuberculosis. Am Rev Respir Dis 140: 990–995.
- 52. Tuberculosis Research Centre Madras (1986) A controlled clinical trial of 3- and 5-month regimens in the treatment of sputum-positive pulmonary tuberculosis in South India. Am Rev Respir Dis 134: 27–33.
- 53. British Medical Research Council (1973) Co-operative controlled trial of a standard regimen of streptomycin, PAS and isoniazid and three alternative regimens of chemotherapy in Britain. Tuberc 54: 99–129.
- 54. British Thoracic and Tuberculosis Association (1975) Short-course chemotherapy in pulmonary tuberculosis. Lancet 305: 119–124.
- 55. British Thoracic and Tuberculosis Association, Angel H (1976) Short-course chemotherapy in pulmonary tuberculosis. a controlled trial by the British Thoracic and Tuberculosis Association. Lancet 2: 1102–1104.
- 56. British Thoracic Association (1981) A controlled trial of six months chemotherapy in pulmonary tuberculosis. first report: results during chemotherapy. Br J Dis Chest 75: 141–153.
- 57. Zierski M, Bek E, Long MW, Snider DE, Jr. (1981) Short-course (6-month) cooperative tuberculosis study in Poland: results 30 months after completion of treatment. Am Rev Respir Dis 124: 249–251.
- 58. British Thoracic Association (1982) A controlled trial of six months chemotherapy in pulmonary tuberculosis. second report: results during the 24 months after the end of chemotherapy. Am Rev Respir Dis 126: 460–462.
- 59. Macnab MF, Bohmer PD, Seager JR (1994) Evaluation of the 3-drug combination, Rifater, versus 4-drug therapy in the ambulatory treatment of tuberculosis in Cape Town. S Afr Med J 84: 325–327.
- 60. Felten MK (1989) Importance of rifampicin in combined daily/intermittent chemotherapy for tuberculosis. S Afr Med J 75: 524–526.
- 61. Kohno S, Koga H, Kaku M, Maesaki S, Hara K (1992) Prospective comparative study of ofloxacin or ethambutol for the treatment of pulmonary tuberculosis. Chest 102: 1815–1818.
- 62. Gonzalez-Montaner LJ, Natal S, Yongchaiyud P, Olliaro P, the Rifabutin Study Group (1994) Rifabutin for the treatment of newly-diagnosed pulmonary tuberculosis: a multinational, randomized, comparative study versus rifampicin. Tuberc Lung Dis 75: 341–347.
- 63. Algerian Working Group British Medical Research Council Cooperative Study (1991) Short-course chemotherapy for pulmonary tuberculosis under routine programme conditions: a comparison of regimens of 28 and 36 weeks duration in Algeria. Tuberc 72: 88–100.
- 64. Tripathy SP (1983) Controlled clinical trial of a 3-month and two 5-month regimens in pulmonary tuberculosis. Second Madras short course study. Bull Int Union Tuberc 58: 97–100.
- 65. Su W-J, Perng R-P (2002) Fixed-dose combination chemotherapy (Rifater/Rifinah) for active pulmonary tuberculosis in Taiwan: a two-year follow-up. Int J Tuberc Lung Dis 6: 1029–1032.
- 66. Zhang LX, Kan GQ, Tu DH, Wan LY, Faruqi AR (1996) Fixed-dose combination chemotherapy versus multiple, single-drug chemotherapy for tuberculosis. Curr Ther Res 57: 849–856.
- 67. Corpe R (1972) Rifampin in original treatment of pulmonary tuberculosis: a United States public health service cooperative therapy trial. Bull Int Union Tuberc 47: 41–47.
- 68. Howell F, O'Laoide R, Kelly P, Power J, Clancy L (1989) Short course chemotherapy for pulmonary tuberculosis: a randomised controlled trial of a six month versus a nine month oral regimen. Ir Med J 82: 11–13.
- 69. Snider DE, Gracyk J, Bek E, Rogowski J (1984) Supervised six-months treatment of newly diagnosed pulmonary tuberculosis using isoniazid, rifampin, and pyrazinamide with and without streptomycin. Am Rev Respir Dis 130: 1091–1094.
- 70. Santha T, Nazareth O, Krishnamurthy MS, Balasubramanian R, Vijayan VK, et al. (1989) Treatment of pulmonary tuberculosis with short course chemotherapy in south India-5 year follow up. Tuberc 70: 229–234.
- 71. Shenna DH (1984) Comparison of a conventional and an initial 2-month intensive drug regimen for treating pulmonary tuberculosis in Swaziland. Tuberc 65: 101–104.
- 72. Perriens JH, St. Louis M, Mukadi YB, Brown C, Prignot J, et al. (1995) Pulmonary tuberculosis in HIV-infected patients in Zaire. N Engl J Med 332: 779–784.
- 73. Tam CM, Chan SL, Lam CW, Leung CC, Kam KM, et al. (1998) Rifapentine and isoniazid in the continuation phase of treating pulmonary tuberculosis. Am J Respir Crit Care Med 157: 1726–1733.
- 74. Combs D, O'Brien R, Geiter LJ (1990) USPHS tuberculosis short-course chemotherapy trial 21: effectiveness, toxicity, and acceptability. Ann Intern Med 112: 397–406.
- 75. Pedral-Sampaio DB, Netto EM, Brites C, Bandeira AC, Guerra C, et al. (2003) Use of Rhu-GM-CFS in pulmonary tuberculosis patients: results of a randomized clinical trial. Braz J Infect Dis 7: 245–252.
- 76. Hong Kong Chest Service, Tuberculosis Research Centre M, British Medical Research Council (1984) A controlled trial of 2-month, 3-month, and 12-month regimens of chemotherapy for sputum-smear-negative pulmonary tuberculosis. Am Rev Respir Dis 130: 23–28.
- 77. Snider DE Jr., Long MW, Cross FS, Farer LS (1984) Six-months isoniazid-rifampin therapy for pulmonary tuberculosis. Am Rev Respir Dis 129: 573–579.
- 78. Long MW, Snider D Jr., Farer LS (1979) U.S. public health service cooperative trial of three rifampin-isoniazid regimens in treatment of pulmonary tuberculosis. Am Rev Resp Dis 119: 879–894.
- 79. Tripathy SP (1979) Madras study of short-course chemotherapy in pulmonary tuberculosis. Bull Int Union Tuberc 54: 28–30.
- 80. Murray J, Sonnenberg P, Shearer S, Godfrey-Faussett P (2000) Drug-resistant pulmonary tuberculosis in a cohort of southern African goldminers with a high prevalence of HIV infection. S Afr Med J 90: 381–386.
- 81. East African British Medical Research Councils (1981) Controlled clinical trial of five short-course (4 month) chemotherapy regimens in pulmonary tuberculosis. Am Rev Respir Dis 123: 165–170.
- 82. Agounitestane D, Chiheb M, Khaled S, Khaled NA, Boulahbal F, et al. (1990) Essai thérapeutique d'une combinaison de trois médicaments essentiels dans la chimiothérapie courte de la tuberculose. Rev Mal Resp 7: 209–213.
- 83. Mazouni L, Tazir M, Boulahbal F, Chaulet P (1985) Enquête contrôlée comparant trois règimes de chiniothérapie quotidienne de six mois dans la tuberculose pulmonaire, en pratique de routine à Alger. Rev Mal Resp 2: 209–214.
- 84. East African and British Medical Research Councils (1978) Controlled clinical trial of five short-course (4-month) chemotherapy regimens in pulmonary tuberculosis. Lancet 2: 334.
- 85. El-Sadr WM, Perlman DC, Matts JP, Nelson ET, Cohn DL, et al. (1998) Evaluation of an intensive intermittent-induction regimen and duration of short-course treatment for human immunodeficiency virus-related pulmonary tuberculosis. Clin Infect Dis 26: 1148–1158.
- 86. British Thoracic and Tuberculosis Association (1976) Short-course chemotherapy in pulmonary tuberculosis. Lancet ii: 1102.
- 87. Teo SK, Tan KK, Khoo TK (2002) Four-month chemotherapy in the treatment of smear-negative pulmonary tuberculosis: results at 30 to 60 months. Ann Acad Med Singapore 31: 175–181.
- 88. Chaulet P, Boulahbal F (1995) Essai clinique d'une combinaison en proportions fixes de trois medicaments dans le traitement de la tuberculose. Tuberc Lung Dis 76: 407–412.
- 89. Engbaek HC, Heckscher T, Hojgaard C, Larsen SO, Rasmussen KN, et al. (1981) Tuberculosis treated with rifampicin, ethambutol and isoniazid: Danish tuberculosis trial 1972–1974. Eur J Respir Dis 63: 84–93.
- 90. Sharifi-Mood B, Metanat M, Alavi-Naini R, Kouhpayeh HR, Salehi M, et al. (2006) The comparison of six-month and four-month regimens of chemotherapy in the treatment of smear positive pulmonary tuberculosis. J Med Sci 6: 108–111.
- 91. A Singapore-British Medical Research Council study (1978) Controlled trial of 4-month and 6-month regimens of chemotherapy in the treatment of pulmonary tuberculosis. Ann Acad Med 5: 242–243.
- 92. Maureen M, McGregor M, Olliaro P, Wolmarans L, Mabuza B, et al. (1996) Efficacy and safety of rifabutin in the treatment of patients with newly diagnosed pulmonary tuberculosis. Am J Respir Crit Care Med 154: 1462–1467.
- 93. Hong Kong Chest Service, Tuberculosis Research Centre M, British Medical Research Council (1981) A controlled trial of 2-month, 3-month, and 12-month regimens of chemotherapy for sputum smear-negative pulmonary tuberculosis: the results at 30 months. Am Rev Respir Dis 124: 138–142.
- 94. Mohanty KC, Dhamgaye TM (1993) Controlled of ciprofloxacin in short-term chemotherapy for pulmonary tuberculosis. Chest 104: 1194–1198.
- 95. Kohno S, Koga H, Kaku M, Maesaki S, Hara K (1992) Prospective comparative study of ofloxacin or ethambutol for the treatment of pulmonary tuberculosis. Chest 102: 1815–1818.
- 96. Mak A, Thomas A, Granado M, Zaleskis R, Mouzafarova N, et al. (2008) Influence of multidrug resistance on tuberculosis treatment outcomes with standardized regimens. Am J Respir Crit Care Med 178: 306–312.
- 97. World Health Organization (2009) Treatment of tuberculosis: Guidelines. 4th Edition. Geneva: WHO. WHO/HTM/TB/2009.420.
- 98. Benator D, Bhattacharya M, Bozeman L, Burman W, Cantazaro A, et al. (2002) Rifapentine and isoniazid once a week versus rifampicin and isoniazid twice a week for treatment of drug-susceptible pulmonary tuberculosis in HIV-negative patients: a randomised clinical trial. Lancet 360: 528–534.
- 99. Chang KC, Leung CC, Yew WW, Chan SL, Tam CM (2006) Dosing schedules of 6-month regimens and relapse for pulmonary tuberculosis. Am J Respir Crit Care Med 174: 1153–1158.
- 100. Li J, Munsiff SS, Driver CR, Sackoff J (2005) Relapse and acquired rifampin resistance in HIV-infected patients with tuberculosis treated with rifampin- or rifabutin-based regimens in New York City, 1997-2000. Clin Infect Dis 41: 83–91.
- 101. Caldwell DM, Ades AE, Higgins JPT (2005) Simultaneous comparison of multiple treatments: combining direct and indirect evidence. BMJ 331: 897.
- 102. Song F, Loke YK, Walsh T, Glenny AM, Eastwood AJ, et al. (2009) Methodological problems in the use of indirect comparisons for evaluating healthcare interventions: survey of published systematic reviews. BMJ 338: b1147.
- 103. Greenaway C, Menzies D, Fanning A, Grewal R, Yuan L, et al. (2002) Delay in diagnosis among hospitalized patients with active tuberculosis—predictors and outcomes. Am J Respir Crit Care Med 165: 927–933.
- 104. Humphries MJ, Byfield SP, Darbyshire JH, Davies PDO, Nunn AJ, et al. (1984) Deaths occurring in newly notified patients with pulmonary tuberculosis in England and Wales. Br J Dis Chest 78: 149.
- 105. Allan WGL, Snell NJC, Hill LE, Fayers PM, Scadding JG, et al. (1981) A survey of deaths in Hong Kong attributed to tuberculosis. Tuberc 62: 1–11.
- 106. Davis MCE, McAllister K, Matthews CJ, Ognibene AJ (1985) Tuberculosis; cause of death in antibiotic era. Chest 88: 726.
- 107. Ramos JM, Padilla S, Masia M, Gutierrez F (2008) A bibliometric analysis of tuberculosis research indexed in PubMed, 1997–2006. In J Tuberc Lung Dis 12: 1461–1467.
- 108. Kieling C, Herrman H, Patel V, Mari JJ (2009) Indexation of psychiatric journals from low- and middle-income countries: a survey and a case study. World Psychiatry 8: 40–44.
- 109. Sonnenberg P, Murray J, Glynn JR, Shearer S, Kambashi B, et al. (2001) HIV-1 and recurrence, relapse, and reinfection of tuberculosis after cure: a cohort study in South African mineworkers. Lancet 358: 1687–1693.
- 110. Hong Kong Chest Service, Tuberculosis Research Centre M-BMRC (1992) A double-blind placebo-controlled clinical trial of three antituberculosis chemoprophylaxis regimens in patients with silicosis in Hong Kong. Am Rev Respir Dis 145: 36–41.
- 111. East and Central African-British Medical Research Council Fifth Collaborative (1986) Controlled clinical trial of 4 short-course regimens of chemotherapy (three 6-month and one 8-month) for pulmonary tuberculosis: final report. Tuberc 67: 5–15.
- 112. Felten MK (1989) Importance of rifampicin in combined daily/intermittent chemotherapy for tuberculosis. S Afr Med J 75: 524–526.
- 113. East and Central African-British Medical Research Council Fifth Collaborative (1986) Controlled clinical trial of 4 short-course regimens of chemotherapy (three 6-month and one 8-month) for pulmonary tuberculosis: final report. Tuberc 67: 5–15.
- 114. East and Central African-British Medical Research Council Fifth Collaborative (1986) Controlled clinical trial of 4 short-course regimens of chemotherapy (three 6-month and one 8-month) for pulmonary tuberculosis: final report. Tuberc 67: 5–15.
- 115. Zierski M, Bek E, Long MW, Snider DE, Jr. (1981) Short-course (6-month) cooperative tuberculosis study in Poland: results 30 months after completion of treatment. Am Rev Respir Dis 124: 249–251.
- 116. Zierski M, Bek E, Long MW, Snider DE, Jr. (1980) Short-course (6 month) cooperative tuberculosis study in Poland: results 18 months after completion of treatment. Am Rev Respir Dis 122: 879–889.
- 117. Macnab MF, Bohmer PD, Seager JR (1994) Evaluation of the 3-drug combination, Rifater, versus 4-drug therapy in the ambulatory treatment of tuberculosis in Cape Town. S Afr Med J 84: 325–327.