KIDCRU, Stellenbosch University, Tygerberg Children’s Hospital, W Cape
HIV-infected children have a high risk of acquiring tuberculosis. The World Health Organization (WHO) has released isoniazid preventive therapy (IPT) recommendations for adults and children living with HIV, based on efficacy studies, mainly in adults. Data from children appear conflicting. IPT guidelines for children were developed in response to WHO guidelines at a local meeting, followed by discussions.
IPT should be given to all HIV-infected children after exposure to a source case if treatment for active disease is not required. For children whose mothers’ HIV status was known antentally, when tuberculosis has been actively excluded in mothers and at infant follow-up, and when infants have commenced antiretroviral therapy in the first 3 months of life, IPT is not required. Otherwise, all infants and children should be given IPT for 6 months once active tuberculosis has been excluded.
HIV-infected children are at high risk of contracting tuberculosis (TB). An incidence of 24 cases per 100 HIV-infected children per year was documented in Cape Town during a period of limited access to antiretroviral therapy (ART).1
For HIV-infected adults, IPT is a cornerstone of TB management. IPT for HIV-infected adults refers to giving INH to those without active TB. IPT, together with intensified case finding and infection control, is collectively referred to as the ‘3 Is’ strategy of the World Health Organization (WHO).2 In a recent meta-analysis of 12 trials and 8 578 randomised HIV-infected subjects >13 years of age, TB preventive therapy (any anti-TB drug) versus placebo resulted in a lower incidence of active TB (relative risk (RR) 0.68, 95% confidence interval (CI) 0.54 - 0.85). This effect was more pronounced in individuals with a positive tuberculin skin test (TST) (RR 0.38, 95% CI 0.25 - 0.57). For adults with a negative TST, there was no statistically significant difference between treatment groups as the upper CI was >1 (RR 0.89, 95% CI 0.64 - 1.24). Compared with INH monotherapy, shortcourse multidrug regimens had more adverse effects. A reduction in mortality with INH monotherapy versus placebo was confined to those with a positive TST (RR 0.74, 95% CI 0.55 - 1.00).3
The meta-analysis did not address the role of ART, which also reduces the risk of acquiring TB disease, as no randomised controlled trials have been reported in patients on ART. Lawn and colleagues have argued that ART and IPT have complementary roles, IPT being important in TST-positive individuals with higher CD4 counts and better immunity, and that ART (together with active case finding) is the most important component in immunosuppressed individuals.4
A meta-analysis from 2006 showed that IPT is not associated with production of INH resistance,5 although resistance is a concern if patients have active disease before commencing IPT. It is also recognised that IPT is unlikely to prevent TB if a patient is infected with Mycobacterium tuberculosis resistant to INH.6
For children there are fewer data. The benefit of IPT after documented TB exposure or infection (TST positive) is undisputed, with the efficacy derived from studies in HIV-uninfected children.7 Findings assessing the value of universal IPT before or in the absence of documented exposure to a source case (pre-exposure IPT) seem contradictory. Zar and colleagues showed benefit in a double-blind study comparing INH with placebo in children with limited access to ART in Cape Town.1 Active TB was excluded at baseline and children already responding to TB treatment were randomised once TB treatment had been completed. Mortality was lower in the INH group (11 (8%) v. 21 (16%)) (hazard ratio (HR) 0.46, 95% CI 0.22 - 0.95, p=0.015). The incidence of TB was also lower in the INH group (5 cases, 3.8%) than in the placebo group (13 cases, 9.9%) (HR 0.28, 95% CI 0.10 - 0.78, p=0.005).1
A large multicentre trial set in Soweto, Cape Town and Durban enrolled infants between 3 and 4 months of age, after excluding all children with known TB contact.
It took place during expanding access to ART. There was no benefit from pre-exposure IPT compared with placebo, either in preventing TB or in reducing mortality in HIV-infected and HIV-exposed uninfected infants.8 , 9 The apparent contradiction with the study by Zar et al. 1 could be explained by differences in the patient populations, excellent surveillance for TB exposure, and rapid institution of open-label INH for any documented exposure to a source case. The benefit of ART in reducing TB disease is well documented in children.10 , 11
New long-term data from Cape Town on children from the original IPT study recently reported additive benefit of ART and IPT over 5 years of follow-up. All children on placebo were switched to open-label INH and accessed ART through the public programme. INH reduced the risk of TB by 0.22 (95% CI 0.09 - 0.53) compared with placebo. ART alone reduced TB risk by 0.32 (95% CI 0.07 - 1.55). INH plus ART reduced the risk of TB by 0.11 (95% CI 0.04 - 0.32). Restricting the analysis to children receiving ART revealed a TB risk reduction of 0.23 (95% CI 0.05 - 1.00) when comparing INH with no INH.12 This study suggests that IPT and ART have additive benefit in HIV-infected children.
The WHO has recently published guidance on IPT for both children and adults, mainly based on adult data.13
The recommendations for children are as follows:
1.2
1.3
1.4
1.5
The place of IPT for HIV-infected children in Southern Africa was debated at a small meeting held in Cape Town
on 14 October 2010, sponsored by the HIV Clinicians Society of South Africa. Paediatricians from South Africa
and Botswana and adult infectious diseases specialists with expertise in IPT attended. (During a review process,
additional colleagues with expertise in childhood HIV and TB gave invaluable input.) The consensus was that
IPT should be supported. There is a need to define the extent to which it should be included. There is a role for
operational research on IPT. Integration of maternal and child health with TB and HIV programmes to accompany
IPT (Infection control and Intensified case finding) is a key component for elimination of TB in children.
The following should be addressed:
At each health care visit, every HIV-infected child must be reviewed for possible TB exposure and/or active
disease and managed appropriately.
Always check the following:
IPT should be provided after EACH documented TB exposure, unless the child is CURRENTLY receiving
INH or TB treatment (Fig. 1).
• Completely asymptomatic children (no current cough, no failure to thrive, no signs of extrathoracic TB, active and playful) require no further investigation prior to IPT initiation. (All children receiving IPT and/or TB treatment should be followed up clinically while on therapy to evaluate for new symptoms or signs of disease.)
• Any symptomatic child should be carefully assessed (always plot weight and assess RTHC for failure to thrive). In the absence of a convincing clinical picture of TB or lethargy, and without easy access to chest radiography, first treat the most likely alternative diagnosis and re-assess the child after 2 weeks.
• Persistently symptomatic children must be assessed with at least a chest radiograph (antero-posterior
or postero-anterior AND lateral). Respiratory specimens (gastric aspirates and/or induced sputa)
for M. tuberculosis culture must be collected in all children with signs suggestive of TB on chest
radiograph (prior to initiation of TB treatment).
NOTE: Evaluate for TB using the best resources available.
Primary (pre-exposure) IPT should be given for 6 months (Fig. 2).
5.1 Give under the following circumstances:
5.2. Do NOT give if ALL of the following criteria are fulfilled:
At the time of implementation of the IPT guidelines (June 2011), there will be 50 000 children on ART. Data support
IPT in children.12
For children already well established on highly active antiretroviral therapy (HAART) (i.e. >3
months) and without active TB, there are two options:
7.1 INH 10 - 15 mg/kg/d.
8.1 In the absence of obvious TB disease, initiation of HAART takes precedence over IPT.
1. Zar HJ, Cotton MF, Strauss S, et al. Effect of isoniazid prophylaxis on mortality and incidence of tuberculosis in children with HIV: randomised controlled trial. BMJ 2007;334:136.
2. World Health Organization. WHO Three I’s Meeting (2 - 4 April 2008). Geneva: WHO, 2008.
3. Akolo C, Adetifa I, Shepperd S, Volmink J. Treatment of latent tuberculosis infection in HIV infected persons (Review). Cochrane Collection 2010. www.thecochranelibrary. com (accessed 18 January 2011).
4. Lawn SD, Wood R, De Cock KM, Kranzer K, Lewis JJ, Churchyard GJ. Antiretrovirals and isoniazid preventive therapy in the prevention of HIV-associated tuberculosis in settings with limited health-care resources. Lancet Infect Dis 2010;10:489-498.
5. Balcells ME, Thomas SL, Godfrey-Faussett P, Grant AD. Isoniazid preventive therapy and risk for resistant tuberculosis. Emerg Infect Dis 2006;12:744-751.
6. Sneag DB, Schaaf HS, Cotton MF, Zar HJ. Failure of chemoprophylaxis with standard antituberculosis agents in child contacts of multidrug-resistant tuberculosis cases. Pediatr Infect Dis J 2007;26:1142-1146.
7. United States Public Health Service Tuberculosis Prophylaxis Trial Collaborators. Prophylactic effects of isoniazid on primary tuberculosis in children. Am Rev Tuberc 1957;76:942-963.
8. Madhi SA, McSherry G, Violari A, et al. Lack of efficacy of primary isoniazid (INH) prophylaxis in reducing tuberculosis (TB) free survival in HIV-infected (HIV+) African children. Presented at the Interscience Conference on Antimicrobial Agents and Chemotherapy, 25 - 28th October 2008. Washington DC: IDSA/ASM. http:// clinicaloptions.com/hiv/washington2008 (accessed 11 May 2011).
9. Mitchell C, McSherry G, Violari A, et al. Primary isoniazid prophylaxis did not protect against TB or latent TB infection in HIV-exposed, uninfected infants in South Africa. Presented at the 16th Conference on Retrovirology and Opportunistic Infections, 8 - 11 February 2009, Montreal, Canada. http://www.retroconference.org/ (accessed 11 May 2011).
10. Violari A, Cotton MF, Gibb DM, et al. Early antiretroviral therapy and mortality among HIV-infected infants. N Engl J Med 2008;359:2233-2244.
11. Walters E, Cotton MF, Rabie H, Schaaf HS, Walters LO, Marais BJ. Clinical presentation and outcome of tuberculosis in human immunodeficiency virus infected children on anti-retroviral therapy. BMC Pediatr 2008;8:1.
12. Frigati LJ, Kranzer K, Cotton MF, Schaaf HS, Lombard CJ, Zar HJ. The impact of isoniazid preventive therapy and antiretroviral therapy on tuberculosis in children infected with HIV in a high tuberculosis incidence setting. Thorax 2011 (in press, e-pub date 2 April).
13. World Health Organization. Guidelines for Intensified Ttuberculosis Case-finding and Isoniazid Preventive Therapy for People Living with HIV in Resource-constrained Settings. Geneva: WHO, 2011.
14. Hesseling AC, Cotton MF, Jennings T, et al. High incidence of tuberculosis among HIV-infected infants: Evidence from a South African population-based study highlights the need for improved tuberculosis control strategies. Clin Infect Dis 2009;48:108-114.
15. Fitzgerald DW, Desvarieux M, Severe P, Joseph P, Johnson WD Jr, Pape JW. Effect of post-treatment isoniazid on prevention of recurrent tuberculosis in HIV-1-infected individuals: a randomised trial. Lancet 2000;356:1470-1474.
16. World Health Organization, International Union Against Tuberculosis and Lung Disease. Guidance for national tuberculosis and HIV programmes on the management of tuberculosis in HIV-infected children: Recommendations for a public health approach. 2010. www.idoc-africa.org/documents/download/id/206 (accessed15 April 2011).
17. Al-Dabbagh M, Lapphra K, McGloin R, et al. Drug-resistant tuberculosis. Pediatr Infect Dis J 2011 (in press, e-pub date 3 February).
Contributors to guideline development:
Mohandran
Archary (scribe), Tonya Arscott-Mills, Theunis Avenant, Vivienne Black, Raziya Bobat (Co-chair),
Ashraf Coovadia (Chair), Mark Cotton (convener), Peter Donald, Angela Dramowski, Ute Feucht,
Anneke Hesseling, Prakash Jeena, Leon Levin, Anna Mandalakas, Ben J Marais, Graeme Meintjies,
Tammy Meyers, Kimesh Naidoo, Helena Rabie, Gary Reubenson, Paul Roux, H Simon Schaaf, Andrew
Steenhof, Helecine Zeeman, Heather Zar.
Acknowledgements
We thank Natalie Martyn for
arranging the meeting and the SA HIV Clinicians Society for sponsoring it.
DOSAGE RECOMMENDATIONS FOR IPT (PRIMARY AND POST-EXPOSURE)
Weight range (kg) |
100 mg tablets per dose |
Dose given (mg) |
<5 |
0.5 |
50 |
5.1 - 9.9 |
1 |
100 |
10 - 13.9 |
1.5 |
150 |
14 - 19.9 |
2 |
200 |
20 - 24.9 |
2.5 |
250 |
>25 |
3 |
300 |
Resources for drug-resistant TB: references 16 and 17. |