Treatment and pregnancy outcomes of pregnant women exposed to second-line anti-tuberculosis drugs in South Africa

Multi-drug resistant and rifampicin-resistant tuberculosis (MDR/RR-TB) remains a significant threat to the global control of tuberculosis (TB). An estimated 465,000 new cases and 182,000 deaths from MDR/RR-TB were reported globally in 2018, with only 56% of cases successfully treated [1, 2]. South Africa ranks among the top ten countries in the world in terms of the number of patients with MDR/RR-TB, which is driven by a high HIV burden [1, 3]. In 2018, South Africa had 13,199 MDR/RR-TB cases detected; 72.4% of these started on treatment and treatment success was similar to the global rate, and mortality was above 20% [1].

An estimated 80% of women initiating second-line anti-TB treatment for MDR/RR-TB in South Africa are of reproductive age (defined as aged 15–44), and 68.0% are also HIV-positive [4]. TB and HIV co-infection in pregnancy are major risk factors for maternal mortality and poor neonatal outcomes [4]. Multiple drugs used in MDR/RR-TB regimens are known to be potentially teratogenic to the foetus, including aminoglycosides and ethionamide [5]. Also, there is limited data from animal studies that linezolid, fluoroquinolones, clofazimine, terizidone and delamanid could be potentially unsafe in pregnancy. However, there is minimal human data as pregnant/breastfeeding women are routinely excluded from clinical trials [6, 7]. However, the potential risk associated with MDR/RR-TB treatment to the foetus must be weighed against delayed treatment which risks obstetric and neonatal complications, on-going transmission, treatment failure and amplification of resistance from sub-optimal regimens [6‐8]. Current South African and World Health Organization (WHO) guidelines for the treatment of MDR/RR-TB recommend initiating standard short and long-course regimens for MDR/RR-TB in pregnant and breastfeeding women with the exclusion of aminoglycosides and ethionamide [9, 10].

During the study period (2010–2016), the standard of care for MDR/RR-TB treatment in South Africa was a regimen of five drugs (kanamycin, moxifloxacin, ethionamide, terizidone, and pyrazinamide) for six months (intensive phase) followed by 18 months (continuation phase) of four drugs (oral moxifloxacin, ethionamide, terizidone, and pyrazinamide). For patients with documented resistance or intolerance to the drugs in the standard regimen (e.g. pre-extensively drug-resistant TB (preXDR) or extensively drug-resistant TB (XDR-TB)), an individualized regimen containing linezolid, para-aminosalicylic acid, clofazimine, and/or capreomycin was used [11, 12]. In September 2018, the South Africa National TB program eliminated injectables and recommended the use of all-oral regimens, including for pregnant women [13, 14]. However, it will be some time before TB treatment, and pregnancy outcomes for women treated with these new regimens are available given the relatively low incidence of pregnancy during MDR/RR-TB treatment. Meanwhile, data on TB treatment and pregnancy outcomes for women on older long course MDR/RR-TB regimens are still extremely valuable for patients and clinicians as both weigh the safety of second-line TB medications during pregnancy.

The aim of the study is to describe TB treatment and pregnancy outcomes among pregnant women receiving second-line anti-tuberculosis treatment for MDR/RR-TB in Johannesburg, South Africa.

In this cohort of 35 pregnant women receiving second-line anti-TB treatment for MDR/RR-TB in Johannesburg, South Africa, fifty-seven percent had known pregnancy outcomes. Of these, almost two-thirds experienced adverse pregnancy outcomes, which, excluding three elective pregnancy terminations, included preterm birth (55%), neonatal death (5%) and miscarriage (5%). The reported preterm births in our cohort were higher than was previously reported in a cohort of 108 pregnant women managed for MDR/RR-TB in KwaZulu-Natal in South Africa between 2013 and 2017 (28%), and a cohort of 38 pregnant women treated for MDR/RR-TB in Lima, Peru between 1996 and 2005 (2.7%) [13, 22]. Most concerning is that the preterm births in our cohort were also higher than in HIV and general populations in South Africa which range from 8% to over 30% [23‐26]. Multiple factors may explain the observed differences in pregnancy outcomes compared to previous cohorts. Firstly, there is an increased risk poor maternal and birth outcomes pregnant women with HIV and TB co-infection as compared to women with HIV who do not have TB [27, 28]. Almost all of the adverse birth outcomes, including preterm births, were among HIV-positive women in our cohort. This is not unexpected considering that two-thirds of the women living with HIV. Secondly, although not definitive, ART use during pregnancy has been shown in some studies to be associated with increased risk of preterm birth compared to preterm birth rates among HIV negative women [24, 29]. Although a higher proportion of the KwaZulu-Natal cohort were HIV infected (81%), our cohort had more severe immunosuppression, presenting with a median baseline CD4 counts of 145cells/mm³, compared to the baseline CD4 count of 343 cells/mm³ among the KwaZulu-Natal cohort. The Peru cohort only had 8% of women co-infected with HIV which may explain the higher proportion of favourable pregnancy outcomes compared to both the KwaZulu-Natal cohort and the current study. These findings suggest that RR/MDR-TB and HIV co-infection during pregnancy are a cause of poor birth outcomes highlighting the need for intensified TB prevention strategies, and adequate TB treatment in antenatal care and HIV programs.

Overall, 60.1% of the women in our study successfully completed MDR/RR-TB treatment, with 11.4% cured. These outcomes are comparable to the national drug-resistant TB success of 54% for South Africa in 2016 and similar to the treatment success rate in previous studies of pregnant women with RR/MDR-TB. The KwaZulu-Natal cohort had slightly better TB outcomes of 67% treatment success rate [22, 30]. However, half of this cohort received bedaquiline as part of their TB treatment regimen, which has shown improved treatment success rates among MDR/ RR-TB patients [13].

The majority of the women in our study were pregnant at the time of MDR/RR-TB diagnosis. Those that became pregnant after TB treatment initiation became pregnant during the continuation phase of treatment when most patients start to feel better and start resuming normal life activities. The lack of contraceptive use in these patients is a cause for concern as it is specified as part of the management of MDR/RR-TB in women of childbearing age [9]. Because of the lack of safety data in pregnancy for many second-line TB drugs, and the potential for poor TB and maternal outcomes, the South African National department of health guidelines recommend that all women of child-bearing potential with MDR/RR-TB should be offered reproductive counselling and access to family planning [9].

The strength of our study is that it is the first to describe the occurrence of specific drug-related adverse events among women treated with second-line TB drugs while pregnant. Almost 48.5% of the women experienced at least one adverse event, which is lower than 83% that was reported previously in a systematic review to estimate the prevalence of adverse events during DR-TB treatment among non-pregnant patients [31]. Higher rates of adverse events occurred among HIV-positive mothers, likely due to the concurrent use of ART [31]. Hepatotoxicity and nephrotoxicity were most prevalent; they have been linked to pyrazinamide, ethionamide, kanamycin and fluoroquinolones [32, 33] which were the most commonly used drugs to treat our study cohort. Aminoglycosides and ethionamide have since been removed from the new all-oral short and long course MDR/RR regimens in South Africa, but given the increasing availability of new drugs such as bedaquiline and linezolid their use among pregnant women should be reconsidered for countries still using the long course regimens for MDR/RR-TB [2].

Pregnant women with MDR-TB/RR-TB suffer from high rates of adverse pregnancy outcomes. Results from our study highlight the need for close monitoring and coordinated obstetric, HIV and TB care for these vulnerable patients.