Management of latent Mycobacterium tuberculosis infection: WHO guidelines for low tuberculosis burden countries

Target countries for the guidelines

National TB Programmes or their equivalents in the ministries of health of high income or upper middle income countries with an estimated TB incidence rate of less than 100 per 100 000 population per year are the primary target audience for the guidelines presented here (table 1). The guidelines are also relevant for other policy makers responsible for prison or social services, as well as immigration services (such as ministries of justice or correctional services, and ministries dealing with immigration). In addition to the guidelines described in this manuscript there are pertinent WHO guidelines on management of LTBI in people living with HIV [18] and child contacts below 5 years of age [19] which should be implemented in all countries.

Identification of at risk populations

Management of LTBI can prevent TB which is generated by progression from latent infection to disease. To assist in the identification of groups to prioritise for LTBI testing and treatment, we conducted a primary systematic review of the literature on the relative risk of progression from infection to disease in 24 pre-defined population groups. As evidence was very limited, two additional systematic reviews were conducted to measure the prevalence of LTBI, as well as incidence of active TB, relative to the general population, in those 24 groups.

The first systematic review assessed the risk of progression from LTBI to active TB and was restricted to studies published from January 1, 2003 to January 17, 2014 in English, Spanish, French, and identified in MEDLINE. In addition, expert researchers were also contacted to identify any studies that met the inclusion criteria irrespective of date of publication. Eight individual studies provided evidence of an increased risk of progression from LTBI to active TB for the following risk groups: people living with HIV, adult contacts of TB cases, patients undergoing dialysis, underweight people, individuals with fibrotic radiologic lesions and Mantoux tuberculin skin test (TST) converters within the past 2 years.

The second systematic review assessed the prevalence of Mycobacterium tuberculosis infection as determined either by TST or commercially available interferon-gamma release assays (IGRAs) and was restricted to studies published from January 1, 2003 to January 17, 2014 in English, Spanish, and French, and identified in MEDLINE. A total of 276 studies (with 299 entries) were included. Pooled relative risks were calculated by comparison of LTBI prevalence in risk groups (from individual studies) and the general population (using estimates derived from modelling) [20]. Considerable between-study heterogeneity was observed even after stratification for risk group. Nevertheless, an increased prevalence of LTBI evidenced by positive TST or IGRA, compared to the general population, was reported in at least 65% of the identified studies for each of the following risk groups: adult and child contacts of persons with TB, prisoners, homeless people, elderly people, immigrants from high TB burden countries, and illicit drug users.

The third systematic review was conducted to determine the pooled incidence rate ratio of active TB in the pre-defined risk groups compared with the general population. The search was restricted to studies published from January 1, 2004 to March 31, 2014 in English and identified through PUBMED. Evidence of increased risk of active TB was reported in the following risk groups: people living with HIV, adult and child contacts of a TB case, patients receiving dialysis, patients receiving anti-tumour necrosis factor (TNF)-alpha drugs, patients with silicosis, healthcare workers (including students), immigrants from high TB burden countries, prisoners, the homeless, persons with cancer, diabetes mellitus, or harmful alcohol use, tobacco smokers and underweight people.

Based on these findings the panel issued the following recommendations (box 1):

• Systematic testing and treatment of LTBI should be performed in people living with HIV, adult and child contacts of pulmonary TB cases, persons initiating anti-TNF-alpha treatment, receiving dialysis, preparing for organ or haematological transplantation, or with silicosis. Either IGRA or Mantoux TST should be used to test for LTBI. (Strong recommendation, low to very low quality of evidence.)

• Systematic testing and treatment of LTBI should be considered for prisoners, healthcare workers, immigrants from high TB burden countries, homeless persons and illicit drug users. Either IGRA or Mantoux TST should be used to test for LTBI. (Conditional recommendation, low to very low quality of evidence.)

• Systematic testing for LTBI is not recommended in people with diabetes, people with harmful alcohol use, tobacco smokers, and underweight people unless they are already included in the above recommendations. (Conditional recommendation, very low quality of evidence.)

The rationale for the panel to make strong recommendations despite low to very low quality of evidence was based on the increased likelihood of progression to active TB disease, and that the benefits of treatment outweighed the potential harms in those at-risk population groups. Conditional recommendations were made primarily because of reservations on implementation issues, as well as low quality of the evidence.

There was a paucity of data on the benefits and harms of systematic LTBI testing and treatment as well as doubts about its operational feasibility in diabetic patients, people with harmful alcohol use, tobacco smokers and underweight people.

Excluding active TB and testing for LTBI

Exclusion of active TB disease is an important initial step in the process of LTBI management. The fourth systematic review had been conducted in 2012 to determine the accuracy of symptoms and chest radiography screening for active pulmonary TB in HIV-negative persons and persons with unknown HIV status [21] as a screening rule for people living with HIV already exists [22]. The databases MEDLINE, EMBASE, LILIACS and Health Technology Assessment were searched from 1992 to 2012, supplemented by a search of reference lists of relevant reviews and studies, websites of the WHO, and expert consultation for relevant studies and unpublished reports.

The review identified 11 studies from general population surveys that provided data on screening with either symptoms or chest radiography or both [21]. Based on the review, a model was constructed to compare seven screening strategies to rule out active TB (table 2). The presence of any symptom suggestive of TB (i.e. any one of cough, haemoptysis, fever, night sweats, weight loss, chest pain, shortness of breath and fatigue) plus any abnormality on chest radiography offered the highest sensitivity and negative predictive value to rule out active TB.

The fifth systematic review explored tests and clinical proxies that can best identify individuals most at risk of progression to incident TB disease. While the systematic review did not identify any clinical parameter that would assist in the prediction of progression to active TB disease, 29 studies that provided information on the utility of IGRAs and TST in predicting the risk of TB were assessed. The main effect measure of interest was the risk ratio, comparing TB cumulative incidence following a positive test result versus a negative test result in individuals not receiving preventive therapy, or the incidence rate ratio in the few studies that reported the person-years of follow-up amongst persons with positive and negative tests.

The main analysis was restricted to the eight studies that compared TST and IGRA to each other in the same study population (head-to-head comparison). The overall pooled risk ratio for test positives compared to test negatives for TST was 2.58 (95% CI 1.72–3.88) and for IGRA 4.94 (95% CI 1.79–13.65). Similarly, the pooled incidence rate ratio in the three head-to-head studies with person-time data was 2.07 (95% CI 1.38–3.11) for TST and 2.40 (95% CI 1.26–4.60) for IGRA. In both analyses, the confidence intervals around the effect measures for the TST and IGRA were imprecise and largely overlapped. There was insufficient data to provide evidence on predictive utility of the tests among specific high risk groups. The added value of the tests over and above other clinical indicators of risk as well as their additive value when combining TST and IGRAs for diagnosis of LTBI could not be evaluated.

Based on these findings the panel issued the following recommendations:

• Individuals should be asked about symptoms of TB before being tested for LTBI. Chest radiography can be performed if efforts are intended also for active TB case finding. Individuals with TB symptoms or any radiological abnormality should be investigated further for active TB and other conditions. (Strong recommendation, very low quality of evidence.)

• Either TST or IGRA can be used to test for LTBI in high income and upper middle income countries with an estimated TB incidence of less than 100 per 100 000. (Strong recommendation, very low quality of evidence.)

Furthermore, the panel maintained the existing WHO recommendation that IGRA should not replace TST in low income and other middle income countries (strong recommendation, very low quality of evidence) [23].

Treatment options for LTBI

The sixth systematic review was conducted to evaluate the efficacy and safety of treatment for LTBI [24]. 53 studies, all of which were randomised controlled trials and recorded at least one of the two pre-specified end-points (preventing active TB, hepatotoxicity of grade III or above), were included. Data was available for 15 treatment regimens, although relatively few direct comparisons were reported. In addition to standard meta-analysis, mixed treatment comparisons were also performed to allow the inference of indirect evidence (regimen comparisons without randomised controlled trials) and thus a network of evidence [24].

The efficacy of several regimens was established in trials against placebo or no treatment, including 6 month and 12 month isoniazid, 4 month rifampicin, and 3 month rifampicin and isoniazid. No trial determined the efficacy and safety of a 3 month regimen of weekly rifapentine plus isoniazid compared to placebo or no treatment, because this regimen was introduced at a time when conducting placebo controlled trials for LTBI was not considered ethically acceptable.

The main analysis considered studies that compared the above regimens against 6 month isoniazid (taken as reference) for efficacy and heptotoxicity (table 3). In general, these comparisons did not show superiority of efficacy of one regimen over any other. However, in terms of safety, a 3–4 month rifampicin regimen and a 3 month weekly rifapentine plus isoniazid regimen had fewer hepatotoxicity events compared to the 6 month and 9 month isoniazid regimen, respectively. In the absence of any direct comparison of efficacy of 6 and 9 month isoniazid, the equivalence of these two regimens was based on re-analysis of the US Public Health Service (USPHS) trials conducted in the 1950s and 1960s that concluded that optimal protection from isoniazid appears to be obtained by 9 months [25]. Pyrazinamide-containing regimens were evaluated in the analysis, but were not considered for recommendation because of high documented toxicity [3, 26].

Based on these findings the following treatment options were recommended for the treatment of LTBI: 6 month isoniazid, or 9 month isoniazid, or 3 month regimen of weekly rifapentine plus isoniazid, or 3–4 months isoniazid plus rifampicin, or 3–4 months rifampicin alone (strong recommendation, moderate to high quality of evidence).

Preventive treatment for contacts of multidrug resistant-TB cases

The seventh systematic review was conducted to define the effectiveness of anti-TB drugs in preventing active TB in contacts of multidrug-resistant (MDR)-TB patients. Four studies were included for the analysis; all were cohort studies of which one [27] was a prospective study exclusively involving children below 5 years of age while the others were retrospective studies involving both adults and children [28–30]. For the final analysis, one study was excluded for its small sample size [29] while two other studies were excluded because all or the majority of MDR-TB contacts received preventive treatment with isoniazid [28, 30]. Therefore, the quality of evidence was determined using only one comparison study which used a tailored treatment regimen taking into account the resistance pattern of the index case among childhood contacts [27]. In this single study two of 41 children receiving tailored preventive therapy developed TB (confirmed and probable TB) compared to 13 of 64 children not receiving preventive treatment (OR 0.2, 95% CI 0.04–0.94).

There is thus sparse evidence on the effectiveness and safety of using anti-TB drugs to prevent active TB among adult and childhood contacts of MDR-TB cases. Furthermore, determination of the drug susceptibility profile for drugs to be used as preventive treatment for MDR contacts poses both technical and logistic challenges and may lead to drug-related harms, which would necessitate additional cost for close monitoring which has resource implications [31]. The panel noted the serious limitations of evidence to draw any recommendations on MDR-TB preventive therapy as a public health measure and concluded that the management of contacts of MDR-TB patients needs to be guided by a comprehensive clinical risk assessment considering the balance between risk and benefits for the individual. Based on the available evidence and the probability of increased likelihood to develop active TB disease following recent infection, strict clinical observation and close monitoring for the development of active TB disease for at least 2 years is preferred over the provision of preventive treatment for contacts of MDR-TB cases.

Adverse event monitoring

Drug-specific adverse reactions can occur with individuals who receive treatment for LTBI who are usually in good condition and not sick, making it more important to minimise risks of drug-induced harms during treatment. Adverse drug reactions in persons who take isoniazid include asymptomatic elevation of serum liver enzyme concentrations, peripheral neuropathy and hepatotoxicity. Rifampicin- and rifapentine-related adverse reactions include cutaneous reactions, hypersensitivity or flu-like reactions, gastrointestinal intolerance and hepatotoxicity. While most adverse drug reactions are minor and occur rarely, particular attention should be paid to prevent drug-induced hepatotoxicity.

The eighth systematic review was conducted to assess the best way to monitor and manage hepatotoxicity and other adverse drug reactions and no studies were identified [32]. A review of national guidelines [33–37] instead showed consistent recommendations based on expert opinion, which were useful to inform the judgment of the panel.

Based on these observations, the panel underlined the importance of routine regular clinical monitoring of individuals receiving treatment for LTBI through a monthly visit to healthcare providers. The prescribing healthcare provider should explain the disease process and the rationale of treatment and emphasise the importance of completing it. Those receiving treatment should be educated to contact their healthcare providers should they develop symptoms such as anorexia, paraesthesiae, nausea, vomiting, abdominal discomfort, persistent fatigue or weakness, dark-coloured urine, pale stools or jaundice. Whenever a healthcare provider cannot be consulted at the onset of these symptoms, treatment should be stopped immediately.

The panel noted that there was insufficient evidence to support baseline laboratory testing for measurements of serum aspartate aminotransferase, alanine aminotransferase and bilirubin. However, the panel strongly encouraged baseline laboratory testing for individuals with any of the following risk factors: history of liver disease; regular use of alcohol; chronic liver disease; HIV infection; age more than 35 years; and pregnancy or the immediate postpartum period (i.e., within 3 months of delivery). For individuals with abnormal baseline test results, routine periodic laboratory testing should be carried out.

Risk of drug resistance following LTBI treatment

The ninth systematic review was conducted to determine whether LTBI treatment leads to significant development of resistance. The systematic review considered the following treatment regimens.

Adherence and completion of preventive treatment

Adherence to the full course and completion of LTBI treatment are important determinants of clinical benefit to the individual as well as to the success of the programme.

Four systematic reviews (10–13th) were conducted to describe initiation and completion rates of LTBI treatment; to define determinants of initiation, adherence and completion rates of LTBI treatment; to assess interventions that are effective to improve those rates; and to assess if the duration of LTBI treatment will be a barrier to implementation of LTBI treatment. All four reviews focused on prospective studies.

Completion rates were shown to vary greatly across risk groups ranging from 6% to 94%. In general, completion rates were lower among prisoners and immigrants compared with people living with HIV and contacts, and were inversely proportional related to the duration of treatment.

Determinants of treatment initiation, adherence and completion identified in the systematic review were: 1) adverse drug reactions, 2) longer duration of treatment, 3) legal status among immigrants, 4) long distance from health facility, 5) history of incarceration, 6) absence of perception of risk, 7) presence of stigma, 8) alcohol and drug use, 9) unemployment, and 10) time lag between diagnosis and treatment.

Evidence on the efficacy of interventions to improve treatment adherence and completion showed that shorter treatment duration was significantly associated with increased adherence [39–41]. There is contradictory evidence on the role of monetary incentives to improve treatment completion rates, with randomised trials showing benefit of incentives (either monetary or methadone) on treatment completion rates among illicit drug users [42, 43], and other randomised trials among the homeless [44] and prisoners [45] not showing any significant impact. Significant increases in completion rates were demonstrated with peer support and coaching among adolescents and adults [46–48]; nurse case management among the homeless [49]; cultural case management among immigrants [50]; and educational interventions among inmates [45]. No studies were found on the question whether the duration of protection from LTBI treatment will be a barrier to implementation of LTBI treatment.

It was noted that the available evidence is heterogeneous and inconclusive to be able to recommend the best interventions to improve treatment adherence and completion. However, the panel underlined the importance of designing flexible interventions that are tailored to respond to the local context and needs of the population to ensure acceptable initiation of, adherence to and completion of LTBI treatment as part of the public health approach.

Cost-effectiveness

The 14th systematic review was conducted to critically appraise and summarise current evidence on the cost-benefit and cost-effectiveness associated with screening for and treatment of LTBI. Studies that evaluated costs and outcomes of any screening strategy and any drug regimen for LTBI compared to no intervention in any setting and population group were selected. The outcomes considered were incremental cost per quality-adjusted life year or life year gained, and incremental cost per TB case averted. 39 articles were included and the majority of articles (82%) reported on analyses conducted in upper middle-income countries with TB incidence less than 100 per 100 000 population.

Cost inputs (adjusted for currency and inflation to US$ value as of 2012), varied widely among studies. For example, the cost of testing for LTBI using TST varied from US$ 10.9 in a study from Italy [51] to an average of US$ 31.5 in studies from the UK [52]; similarly, detecting LTBI using an IGRA test varied from US$ 22.5 in a study from Mexico [53] to an average of US$ 97.1 in studies from the UK [52, 54]. Wide variations were also observed for the cost of screening eligible candidates for latent TB treatment and the overall cost. For example, the costs of monitoring adverse drug reactions (including liver function tests and clinical monitoring) ranged from US$ 8.3 [55] to US$ 687.3 [56]. The average cost of treating LTBI (including cost of drugs and monitoring) ranged from US$ 381.9 in Italy [51] to US$ 1 129.9 in the UK [52].

Studies showed that LTBI testing and treating of immigrants from high (between 120 and 150 per 100 000 population) to low TB incidence countries may result in savings for the healthcare system or have a favourable incremental cost-effectiveness ratio [52, 54, 57–61]. Similar results were found in studies among people living with HIV [51, 55, 60, 62] and contacts of patients with active TB [52, 61, 63–66]. However, a marked variability across studies in the economic inputs, in epidemiological and TB natural history parameters, as well as in assumptions on the effectiveness of preventive treatment made the extrapolation of the results from one setting to another problematic.