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. Author manuscript; available in PMC: 2013 Nov 20.
Published in final edited form as: AIDS. 2012 Mar 13;26(5):10.1097/QAD.0b013e328350fbfb. doi: 10.1097/QAD.0b013e328350fbfb

Projecting the clinical benefits and risks of using efavirenz-containing ART regimens in women of childbearing age in Sub-Saharan Africa

Eric N Ouattara 1,2, Xavier Anglaret 1,2, Angela Y Wong 3, Jennifer Chu 3, Heather E Hsu 3, Christine Danel 1,2, Serge Eholié 1, Raoul Moh 1, Delphine Gabillard 2, Rochelle Walensky 3, Kenneth A Freedberg 3,4,5
PMCID: PMC3834615  NIHMSID: NIHMS517945  PMID: 22398569

Abstract

Objectives

Our aim was to project the outcomes of using either efavirenz or nevirapine as part of initial antiretroviral therapy (ART) in women of childbearing age in Côte d’Ivoire.

Methods

We used an HIV computer simulation model to project both the mother’s survival and the birth defects at 10 years for a cohort of women who started ART with either efavirenz or nevirapine. The primary outcome was the ratio at 10 years of the difference in the number of women alive to the difference in the cumulative number of birth defects in women who started ART with efavirenz compared to nevirapine. In the base case analysis, the birth defect rate was 2.9% on efavirenz and 2.7% on nevirapine. In sensitivity analyses we varied all inputs across confidence intervals reported in the literature.

Results

In the base case analysis, for a cohort of 100,000 women, the additional number of women alive initiating ART with efavirenz at 10 years was 15 times the additional number of birth defects (women alive: nevirapine 67,969, efavirenz 68,880, difference = 911; birth defects: nevirapine 1,128, efavirenz 1,187, difference = 59). In sensitivity analysis, the teratogenicity rate with efavirenz had to be 6.3%, or 2.3 times higher than the rate with nevirapine, for the excess number of birth defects to outweigh the additional number of women alive at 10 years.

Conclusions

In Côte d’Ivoire, initiating ART with efavirenz instead of nevirapine is likely to substantially increase the number of women alive at 10 years with a smaller potential number of birth defects.

Keywords: efavirenz, women, sub-Saharan Africa, teratogenicity, survival, pregnancy, antiretroviral therapy

INTRODUCTION

World Health Organization (WHO) guidelines for antiretroviral treatment (ART) in resource- limited countries recommend that first-line ART regimens should consist of one non-nucleoside reverse transcriptase inhibitor (NNRTI) and two nucleoside reverse transcriptase inhibitors (NRTIs) (1). The rationale for using NNRTIs in first-line ART while sparing protease inhibitors for second line is due to consideration of cost, ease of use, and resistance (23).

Two NNRTIs are available for first-line therapy: efavirenz and nevirapine. Efavirenz has two advantages over nevirapine. First, although efavirenz and nevirapine have similar risks of mucocutaneous and liver toxicities, these side-effects are much less frequent and of lower severity with efavirenz than with nevirapine (4). The most frequent side-effects from efavirenz are transient central nervous system symptoms, which rarely lead to drug discontinuation (56). Second, efavirenz can be safely routinely prescribed with rifampicine, the first-line treatment for tuberculosis, while the interaction between nevirapine and rifampicine is still unclear (7). Subsequently, since HIV-associated tuberculosis is extremely common in sub-Saharan Africa, nevirapine often needs to be discontinued (8).

However, reports of teratogenicity gave efavirenz one major disadvantage over nevirapine. Based on animal studies and human case reports (911), the United States Food and Drug Administration classifies efavirenz as a category D drug, thereby strictly recommending against efavirenz use during pregnancy (12). The 2010 revised WHO guidelines for ART allows efavirenz to be prescribed during the second and third trimesters of pregnancy, but not during the first trimester (13). As a consequence, efavirenz should not be prescribed in women of child-bearing age who are not using effective contraception. Due to limited access and ineffective use of contraception in sub-Saharan Africa (1416), many physicians prescribe nevirapine rather than efavirenz in women of child-bearing age (1).

The consequences of these recommendations are unclear. Neither the additional risk of teratogenicity from efavirenz compared to nevirapine nor the potential harmful long-term consequences for women of starting ART with nevirapine rather than with efavirenz have been accurately assessed. Because efavirenz is strictly not recommended in women of child-bearing age without effective contraception, clinical studies comparing the maternal survival and pregnancy outcomes with both drugs would not be ethical.

We therefore used a simulation model to assess the trade-off between potential excess birth defects and potential long-term clinical benefits for women starting ART with efavirenz, rather than with nevirapine.

METHODS

Analytic Overview

Using a previously-validated computer-based simulation model of HIV disease in resource-limited settings (1719), we projected the clinical benefits for women and the risk of birth defects for their infants in two cohorts of women of child-bearing age in Côte d’Ivoire: one started ART with an efavirenz-based regimen (EFV), and the other started ART with a nevirapine-based regimen (NVP). Inputs were derived from cohort studies and clinical trials in sub-Saharan Africa. We used a mean pre-ART CD4 count of 154/μl, allowing the prescription of NVP. In the base case analysis, we assumed EFV and NVP had similar efficacy (20), but that NVP had a higher rate of toxicity-related drug discontinuation, as well as a higher rate of fatal toxicity than EFV (8). In sensitivity analysis, we varied major inputs widely. The main outputs were the number of women alive at 10 years and the cumulative number of birth defects at 10 years for a cohort of women starting EFV compared to one starting NVP. The cumulative number of birth defects was calculated in a separated decisions tree model using time of exposure to ART, the rate of pregnancy, the rate of live birth and the rate of birth defect. Using the main outputs, we calculated the ratio of the difference between both cohorts in the absolute number of women alive at 10 years to the difference in the cumulative absolute number of birth defects. Finally, we estimated the excess in birth defect rate with efavirenz compared to nevirapine that would equalize the additional number of women alive at 10 years and the additional number of birth defects with efavirenz compared to nevirapine.

Model description

The Cost-Effectiveness of Preventing AIDS Complications (CEPAC)-International model is a state-transition, first-order Monte Carlo simulation model of HIV infection incorporating natural history, disease progression, and treatment (1819, 21). The model divides HIV infection into “health states,” which include an acute state, a chronic state, and death. Simulated patients are randomly selected from an initial distribution of age, CD4 count, and HIV RNA level, and transition monthly to different health states. The probability of transition from one state to another depends on the CD4 stratum and the associated risk of opportunistic infections (OIs) or death (22) as well as ART. HIV RNA levels determine the rate of CD4 count decline in the absence of ART (23). Successful ART decreases HIV RNA and increases CD4 count. The model also takes into account ART toxicity, ART switching criteria, resistance, and number of ART lines available. Using the model, we simulated outcomes for two cohorts of 100,000 women, one starting ART with efavirenz and one with nevirapine.

Base case inputs

Baseline cohort characteristics, morbidity, and mortality data were derived from four studies in Côte d’Ivoire (2426) (Table 1 All women started ART upon entry into the model. Two lines of ART were available; the first consisted of two NRTIs (tenofovir and emtricitabine) and either efavirenz or nevirapine, and the second-line consisted of two NRTIs (didanosine and abacavir) and lopinavir/ritonavir (1). Patients had a CD4 count assessed every six months. HIV RNA testing was not routinely available. Switching from first-line to second-line was dictated by immunological criteria, as recommended by the WHO in the absence of HIV RNA monitoring (1).

Table 1.

Main model input parameters

Base case value Sensitivity analyses (4)
References
Range Type
Baseline characteristics
 Mean age, years (SD) 33.6 (7.7) [26 – 41] CI (24)
 Mean CD4, cells/μl (SD) 154 (102) [52 – 256] CI (20)
 Sex, female, % 100
 Plasma HIV-1 RNA, copies/ml, %
  >100,000 52.6 (24)
  30,001–10,0000 21.8 (24)
  10,001–30,000 13.1 (24)
  3,001–10,000 5.5 (24)
  501–3,000 3.1 (24)
  ≤ 500 3.9 (24)
Monitoring
 Interval between clinic visits, months 3 1; 6 months Extr. values ASMPT
 Interval between CD4 tests, months 6 3; 12 months Extr. values ASMPT
First-line ART efficacy and toxicity
 HIV-1 RNA suppression at 24 weeks, % (1) 80.2 [65 – 85] Extr. Values (2, 20)
 CD4 cell/μl increase at 24 weeks (1) 152 (20)*
 Toxicity, %
  EFV:
   Drug discontinuation 0.1 [0 – 6.3] Extr. values (8)
   Fatal toxicity (2) 0.1 [0 – 1.0] Extr. values (27)
  NVP:
   Drug discontinuation 6.3 [4.3 – 8.3] CI (8)
   Fatal toxicity (2) 1.0 [0 – 3.0] Extr. values (28)
Pregnancy
 Pregnancy rate, per 100 woman-years (3) 7.9 [5.0 – 15.0] Extr. values (9)
 Outcomes, %
  Abortion 11.7 (29)
  Miscarriage 5.2 (29)
  Stillborn 6.7 (29)
  Live births (3) 76.4 [60.0 – 85.0] Extr. values (29) (9, 34)
   Birth defects, %
    EFV 2.9 (30)
    NVP 2.7 (30)
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EFV: ART regimen including efavirenz and 2 nucleoside reverse transcriptase inhibitors (tenofovir + emtricitabine); NVP: ART regimen including nevirapine and 2 nucleoside reverse transcriptase inhibitors (tenofovir + emtricitabine);

(1)

In the base case analysis we assumed that EFV and NVP had the same immunological and virological efficacy;

(2)

In the base case analysis we assumed that 0.1% of the 0.1% patients who had major toxicity on EFV died (0.001 × 0.001 = 0.00001), and 1% of the 6.3% patients who had major toxicity on NVP died (0.063 × 0.01 = 0.00063);

(3)

In the base case analysis we assumed that women on EFV or NVP had the same rate of pregnancy and live birth;

(4)

In one-way sensitivity analysis, we varied each parameter within the range of confidence interval (CI) or of highest or lowest values (Extreme values - Extr.values) as found in the literature. The column ‘references’ refers to the papers where CI and extreme values were found (ASMPT: assumption).

In the base case analysis, we used three assumptions, all of which were tested in sensitivity analyses. First, we assumed that EFV and NVP had similar virologic and immunologic efficacy (20, 26), and NVP had a higher rate of toxicity leading to drug discontinuation than EFV (8, 2728). Second, we assumed that the rate of pregnancy was constant over time and disease stage, and did not vary from age 25 to 45 or according to ART regimen (9, 29). Finally, we assumed that the rate of birth defect was 0.2% higher with EFV than NVP, based on data from the US Antiretroviral Pregnancy Registry that had reported a birth defect rate of 2.7% for women on NVP and 2.9% for women on EFV (30). We used the same birth defect rate as NVP for the other ART regimens.

Model Outputs

The main model output was the number of women alive. Secondary outputs included time of exposure to each first-line and second-line ART regimen. We then incorporated the latter time of exposure into a decision tree, which included rates of pregnancy, live births, birth defects, abortions, miscarriages, and stillborns, to calculate the cumulative number of babies born with birth defects at 10 years using the following formula:

10-yearnumberofbirthdefects=i[Time_expoiPregnancyrateLivebirthrate]Rate_Bdefi

Where:

  • Time_expoi = total time of exposure to ART regimen i at 10 years;

  • Rate_Bdefi = the birth defect rate due to ART regimen i

  • i =1, 2, 3…n = the different lines of ART regimen

Study main outcomes

This study had two outcomes. The primary outcome was the difference in number of women alive per additional birth defect (“Δ NWA per additional birth defect”), defined as the ratio of the difference in the absolute number of women alive at 10 years to the difference between both populations in the cumulative absolute number of birth defects at 10 years. This outcome was calculated using the following formula:

ΔNWAperadditionalbirthdefect=(NWA_EFV-NWA_NVP)/(NBD_EFV-NBD_NVP);

Where:

  • NWA = number of women alive at 10 years

  • NBD = number of birth defects over 10 years

The secondary outcome was the “equivalence birth defect rate difference,” defined as the difference in birth defect rate per 100 live births that would be necessary to equalize the additional number of women alive at 10 years and the additional number of birth defects with EFV.

Sensitivity Analysis

Sensitivity analyses were done in three steps.

First, in one-way sensitivity analysis, we varied all major parameters in the model. These included patient and regimen characteristics (age, pre-ART CD4 count, virological efficacy of EFV and NVP-based regimens, pregnancy rate (3132), birth defect rate, drug discontinuation and fatal toxicity rates of EFV and NVP-based regimens), as well as program characteristics (interval between clinic visits, interval between CD4 counts, third-line ART availability for patients failing second-line ART, rate of lost-to-follow-up, and availability of contraception). The latter included a mixed-scenario in which the women on effective contraception received EFV while the others received NVP. One-way sensitivity analyses were either confidence interval or extreme case range analyses, according to the confidence intervals or extreme values found in the literature.

Second, we classified the parameters into three groups according their impact on the outcomes. If the sensitivity analysis on a variable produced a variation in Δ number of women alive greater than ±10 per additional birth defect or a variation in equivalence birth defect rate difference greater than ±3%, that variable was classified as ‘highly-sensitive’. If the variation in Δ number of women alive per additional birth defect was between ±5 and ±10 or the variation in equivalence birth defect rate difference was between ±1.5% and ±3%, the variable was classified as ‘moderately sensitive’. Finally, if the variation was less than ±5 for the Δ number of women alive per additional birth defect and less than ±1.5% for the equivalence birth defect rate difference, the variable was classified as ‘minimally-sensitive’.

Third, we included all highly-sensitive variables in a multi-way sensitive analysis.

RESULTS

Base case analysis

During the first 10 years of ART, 92 of the 100,000 women who started ART with EFV experienced severe acute toxicity (of whom none died and all 92 switched to LPV/r), compared to 6,000 of the 100,000 women who started ART with NVP (of whom 62 died and 5937 switched to LPV/r). In women who started ART with EFV, the mean time per woman spent on EFV and on LPV/r was 7.03 years and 8.61 years. In women who started with NVP, the mean time spent on NVP and on LPV/r was 6.61 and 8.63 years. As shown in Table 2, 68,880 of the 100,000 women who started ART with EFV were alive at 10 years, compared to 67,969 women who started ART with NVP. The cumulative number of birth defects that occurred over the 10 years was 1,187 in women who started with EFV and 1,128 in women who started with NVP. Thus, the difference in absolute number of women alive at 10 years was 911, and the difference in absolute number of birth defects on EFV compared to NVP was 59. The “difference in number of women alive per additional birth defect,” was 15, and the “equivalence birth defect rate difference” was 3.4 per 100 live births. As the birth defect rate with EFV was 2.9 per 100, this means that the absolute birth defect rate with EFV had to be greater than 6.3 per 100 live births, and the birth defect rate with EFV had to be more than 2.3 times as higher as the birth defect rate with NVP for the additional number of birth defects to exceed the additional number of women alive at 10 years in women starting ART with EFV (Table 2).

Table 2.

10-year outcomes for a cohort of 100,000 women of child-bearing age starting on EFV or NVP-based ART regimens in Côte d’Ivoire: base case analysis

EFV NVP Δ (EFV-NVP)
Women
 At 10 years, number of women:
  Alive 68,880 67,969 911
  Still on first-line regimen 24,585 23,121 1,464
  With undetectable plasma HIV-1 RNA 65,144 64,613 531
 Overall time on ART during child-bearing years, person-years 694,341 692,413 1,928
  Including time on first-line ART (EFV or NVP) 456,153 430,748 25,405
Pregnancies and newborns
 Pregnancies at 10 years, number 54,853 54,701 152
  Abortions, miscarriages and stillbirths 12,945 12,909 36
  Live births 41,908 41,791 117
   Birth defects 1,187 1,128 59
Combined outcomes
 Δ NWA per additional birth defect (1) 15
 Equivalence birth defect rate difference (2) 3.4%
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EFV: ART regimen including efavirenz and 2 nucleoside reverse transcriptase inhibitors (tenofovir + emtricitabine); NVP: ART regimen including nevirapine and 2 nucleoside reverse transcriptase inhibitors (tenofovir + emtricitabine);

(1)
Δ NWA per additional birth defect = The ratio of number of women alive at ten years on EFV compared to NVP to the additional number of birth defects on EFV compared to NVP
=(NWA_EFV-NWA_NVP)/(NBD_EFV-NBD_NVP)

Where:

  • NWA = number of women alive at 10 years
  • NBD = number of birth defects over 10 years
(2)

Equivalence birth defect rate difference: difference in birth defect rate per 100 live births between EFV and NVP that would be necessary to make the NWA at 10 years equivalent to the number of birth defects

Sensitivity analysis

In one-way confidence interval and extreme case sensitivity analysis, both the Δ NWA per additional birth defect and/or the equivalence birth defect rate difference were highly sensitive to the pregnancy rate, the difference in virologic efficacy between EFV and NVP and EFV toxicity-induced drug discontinuation (Table 3).

Table 3.

10-year outcomes for a cohort of 100,000 women on EFV or NVP-based ART regimens in Côte d’Ivoire: One-way sensitivity analysis (patients and treatment characteristics)

Δ Women alive, at 10 years (1) Δ Birth defects, at 10 years (1) Δ NWA per additional birth defect (2) Equivalence birth defect rate difference (3)
Base case 911 59 15 3.4%
Mean Age, years
  26 913 68 13 3.0%
  41 836 38 22 4.8%
Mean CD4, cells/μl
  52 795 49 16 3.7%
  256 949 66 14 3.2%
HIV-1 RNA suppression at 6 months, %
Varying both regimens, with EFV=NVP
  EFV : 65 ; NVP : 65 922 53 17 4.0%
  EFV: 85 ; NVP: 85 1023 61 17 3.7%
Varying EFV only
  EFV : 78 ; NVP : 80.2 323 53 6 1.3%
  EFV: 82 ; NVP: 80.2 1474 63 23 5.4%
EFV-based regimen toxicity, %
 Drug discontinuation
  0 (EFV < NVP: −6.3%) 961 58 17 3.6%
  6.3 (EFV = NVP) 190 54 4 0.9%
 Fatal toxicity (2)
  0 (EFV < NVP: −1%) 1040 59 18 3.9%
  1.0 (EFV = NVP) 915 59 16 3.5%
NVP-based regimen toxicity, %
 Drug discontinuation
  4.3 (NVP > EFV: +4.2) 937 59 16 3.5%
  8.3 (NVP > EFV: +8.2) 930 60 16 3.5%
 Fatal toxicity
  0.1 (NVP = EFV) 973 58 17 3.7%
  3.0 (NVP > EFV: +2.9) 979 59 17 3.7%
Pregnancy rate/100 person-years
  5.0 911 35 26 5.3%
  15.0 911 105 9 1.8%
Live births, %
  60.0 911 43 21 4.3%
  85.0 911 61 15 3.0%
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EFV: ART regimen including efavirenz and 2 nucleoside reverse transcriptase inhibitors (tenofovir + emtricitabine); NVP: ART regimen including nevirapine and 2 nucleoside reverse transcriptase inhibitors (tenofovir + emtricitabine);

(1)

Δ: Difference between EFV and NVP

(2)
Δ NWA per additional birth defect = The ratio of number of women alive at ten years on EFV compared to NVP to the additional number of birth defects on EFV compared to NVP
=(NWA_EFV-NWA_NVP)/(NBD_EFV-NBD_NVP)

Where:

  • NWA = number of women alive at 10 years
  • NBD = number of birth defects over 10 years
(3)

Equivalence birth defect rate difference: difference in birth defect rate per 100 live births between EFV and NVP that would be necessary to make the number of women alive at 10 years equivalent to the number of birth defects

Decreasing the pregnancy rate increased the ratio of the benefits for women to the risks for children on EFV. When the pregnancy rate decreased from 15 per 100 woman-years (32) to 5 per 100 woman-years (31), the “Δ NWA per additional birth defect” increased from 9 to 26 and the “equivalence birth defect rate difference” increased from 1.8 per 100 live births (i.e. absolute birth defect rate with EFV was 4.7 per 100 live births, 1.7 times as high as the birth defect rate with NVP) to 5.3 per 100 live births (i.e. absolute birth defect rate with EFV was 8.2 per 100 live births, 3 times as high as the birth defect rate with NVP) (Table 3). To make the “Δ NWA per additional birth defect” lower than 1.0, the pregnancy rate had to be over 50 per 100 woman-years.

When assuming that EFV efficacy at 6 months was 2% higher than that of NVP, the “Δ NWA per additional birth defect” increased to 23, and the “equivalence birth defect rate difference” increased to 5.4 per 100 live births (i.e. absolute birth defect rate with EFV was 8.3 per 100 live births, 3 times as high as the birth defect rate with NVP). To make the “ Δ NWA per additional birth defect” lower than 1.0, the efficacy of EFV at 6 months had to be 3% lower than the efficacy of NVP.

When assuming that EFV had the same rate of severe toxicity leading to drug discontinuation as NVP, the “Δ NWA per additional birth defect” was 4.0 and the “equivalence birth defect rate difference” was 0.9 per 100 live births (i.e. absolute birth defect rate with EFV was 3.8 per 100 live births, or 1.4 times as high as the birth defect rate with NVP) (Table 3). To make the “Δ NWA per additional birth defect” lower than 1.0, the absolute rate of EFV severe toxicity leading to drug discontinuation had to be 7.0%, i.e. 0.7% higher than NVP’s base case rate of severe toxicity.

If a third-line ART regimen was available in the country, the “Δ NWA per additional birth defect” ranged from 5 to 12, and the “equivalence birth defect rate difference” ranged from 1.2 to 2.5 per 100 live births, depending on third-line efficacy (Table 4). When assuming a scenario under which EFV is given only to women who take contraception while other women receive NVP, both the “Δ NWA per additional birth defect” and the “equivalence birth defect rate difference” were at least as high as in the base case analysis, and tended to be even higher with decreasing rates of pregnancy in women receiving contraception. If loss-to-follow-up rates were considered, the women in both strategies did worse in terms of survival, and there were fewer birth defects (Table 4). As a result, there was no substantial change in the main results

Table 4.

10-year outcomes for a cohort of 100,000 women on EFV or NVP-based ART regimens in Côte d’Ivoire: One-way sensitivity analysis (program characteristics)

Δ Women alive, at 10 years (1) Δ Birth defects, at 10 years (1) Δ NWA per additional birth defect (2) Equivalence birth defect rate difference (3)
Interval between scheduled visits
 Every months 1031 59 17 3.9%
 Every 6 months 994 59 17 3.8%
Routine CD4 tests
 Every 3 months 1025 58 18 4.0%
 Every 12 months 863 62 14 3.1%
EFV only for women on contraception (4)
 Pregnancy rate = 90% × base case 546 31 17 3.8%
 Pregnancy rate = 50% × base case 546 17 31 6.8%
 Pregnancy rate = 30% × base case 546 10 52 >10.0%
Third-line ART available
 6-month HIV-1 RNA suppression: 30 % 304 58 5 1.2%
 6-month HIV-1 RNA suppression: 50 % 401 57 7 1.6%
 6-month HIV-1 RNA suppression: 80 % 658 56 12 2.5%
Lost to follow-up (LTFU) on ART
 12-month LTFU percentage: 8 % 696 43 16 3.5%
 12-month LTFU percentage: 16% 482 41 12 2.6%
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EFV: ART regimen including efavirenz and 2 nucleoside reverse transcriptase inhibitors (tenofovir + emtricitabine); NVP: ART regimen including nevirapine and 2 nucleoside reverse transcriptase inhibitors (tenofovir + emtricitabine);

(1)

Δ : Difference between EFV and NVP

(2)
Δ NWA per additional birth defect = The ratio of number of women alive at ten years on EFV compared to NVP to the additional number of birth defects on EFV compared to NVP
=(NWA_EFV-NWA_NVP)/(NBD_EFV-NBD_NVP)

Where:

  • NWA = number of women alive at 10 years
  • NBD = number of birth defects over 10 years
(3)

Equivalence birth defect rate difference: difference in birth defect rate per 100 live births between EFV and NVP that would be necessary to make the number of women alive at 10 years equivalent to the number of birth defects

(4)

In this analysis, we assumed that 60% of HIV-infected women actually take effective contraception, and we compared two strategies: (i) all women start ART with NVP, irrespective of whether they are on contraception or not; (ii) women on contraception start ART with EFV, and other women start ART with NVP.

Finally, we varied EFV efficacy compared to NVP and EFV toxicity-induced drug discontinuation in different scenarios of pregnancy rates, to estimate the impact of three-way variations on the “equivalence birth defect rate difference” (Figure 1). In settings with medium rates of pregnancy (Figure 1a), an equivalence birth defect rate difference lower than 1% was found in two situations : First, when the rate of EFV toxicity-inducing drug discontinuation was higher than 1% and the EFV 6-month virological suppression was 2% lower than the NVP 6-month virological suppression; second, when the rate of EFV toxicity-inducing drug discontinuation was higher than 2% and the EFV 6-month virological suppression was 1% lower than the NVP 6-month virological suppression.

Figure 1. Multi-way sensitivity analysis.

Figure 1

Figure 1

Figure 1

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These figures show the variation of the equivalence birth defect rate difference in different scenarios of pregnancy rate, according to different rates of drug discontinuation in women on EFV (X-axis) and to different rates of 6-month HIV-1 RNA suppression on EFV (Z-axis).

Figure 1a: Base case scenario: pregnancy rate = 7.9 per 100 person-years

Figure 1b: Low pregnancy rate scenario: pregnancy rate = 5.0 per 100 person-years

Figure 1c: High pregnancy rate scenario: pregnancy rate = 15.0 per 100 person-years

DISCUSSION

While EFV is better tolerated than NVP, many women start ART with NVP in sub-Saharan Africa. This is mainly due to the fear of efavirenz teratogenicity, which may be higher than that of nevirapine. This is a particular concern in countries where pregnancy rates are high and where contraception is not widely available.

Many physicians, however, are concerned with guidelines that recommend the more toxic NVP for women on the basis of a suspected, but not clearly known, higher rate of teratogenicity with EFV. Starting ART with a more toxic drug may lead to a switch in ART regimen earlier, thus shortening the time on effective ART for women in countries where the number of available ART lines is limited. This, in turn, may decrease long-term survival. Because EFV is strictly contraindicated in women without effective contraception, randomized trials could not be conducted to measure the rate of teratogenicity in women starting ART with EFV, and compare it to women starting ART with NVP. Furthermore, even if such trials were feasible, they would be unable to estimate outcomes over a 10-year period.

Models can explore long-term clinical outcomes in situations where trials are not feasible or ethical. In this study we used a simulation model of HIV infection to compare survival in women and pregnancy outcomes at 10 years in cohorts of women starting ART with EFV or with NVP in Côte d’Ivoire. Using a conservative approach, we first assumed that the two drugs had similar virological efficacy, and that the only differences between drugs were a higher rate of acute toxicity in women with NVP and a higher rate of birth defects in infants with EFV. We used published data for the difference in toxicity, for which there is extensive evidence (6, 8, 33). For birth defect rates, we first assumed that the difference between drugs was reasonably small (2930, 34). We then did extensive sensitivity analyses on all of these parameters.

We found that starting ART with the drug that leads to the lowest rate of switching due to acute toxicity provides a benefit in survival at 10 years, even when assuming that both drugs have the same efficacy. In a cohort of 100,000 women, there were 911 more women alive at 10 years with EFV compared to NVP, approximately a 0.9% benefit. Albeit small, the additional number of women alive was higher than the additional number of birth defects occurring with EFV compared to NVP over 10 years (59 birth defects). Consequently, the ratio of additional number of women alive per additional number of birth defect was very high (15 NWA per addition birth defects). To make the additional number of women alive equivalent to the additional number of birth defects, the rate of birth defects with EFV needed to be at least 2.3 times the rate with NVP, a very unlikely figure. These outcomes were found under conservative assumptions regarding differences in toxicity and efficacy between EFV and NVP. When assuming that EFV may have a slightly higher rate of virologic efficacy than NVP (33, 3539), or that NVP may have a higher rate of fatal toxicity than that we used in the base case (28, 33), we found results even more favourable to EFV.

There are several limitations to this study. First, we used birth defect rates from the Antiretroviral Pregnancy Report (APR), which pools data from different sources (30). Other studies reported different birth defect rates (9, 29, 34). Furthermore, other model inputs were also from different African countries. However, we varied birth defect rates and other inputs widely in sensitivity analysis, and found that the outcomes were robust. Second, our primary outcome is an atypical one, as it posed survival in women against birth defects in children. One may argue that birth defects and women’s deaths are altogether different. Birth defects lead to a higher risk of death in children (4041), but also to consequences in terms of quality of life (4243) that we did not take into account in this study. Finally, both birth defects and women’s death may also affect other family members both in terms of mortality and of quality of life (4445) that we also did not take into account. For a direct comparison of outcomes in women and in infants related to the use of NVP or EFV, or for a cost-effectiveness analysis, QALYs and DALYs would be more appropriate outcomes than the ones we used. However, our aim was not to compare adult deaths to birth defect, but to evaluate in parallel the severe clinical outcomes related to the use of NVP or EFV in both he infants and their mothers. For the infants, the most severe outcome associated with EFV is birth defect. For the mothers, the most severe outcome associated with starting ART either with EFV or with NVP is death. The first outcome can be measured early. The second one requires a long-term analysis, because it’s most important determinant is not virological efficacy but the rate of toxicity-induced drug discontinuation. Showing these two outcomes in parallel could allow people to take the long-term survival of mothers into consideration when debating the merits of EFV versus NVP. Currently birth defects are considered the most important part of this debate, and survival in mothers is rarely taken into consideration.

Our aim was not to suggest that birth defects are preferable to women’s deaths. Our aim was to estimate the extent to which recommending NVP over EFV might affect women’s long-term survival. Our analysis suggests that women’s survival could be substantially improved if EFV was recommended first in all women of childbearing age, and that the additional number of birth defects would be likely to be lower than the additional number of women alive over a 10-year period. This trade off should be carefully considered when recommending first-line ART regimens in resource-limited countries.

Acknowledgments

This research was supported by:

The Agence Nationale de recherche sur le Sida et les hépatites virales (ANRS 12212), France The National Institute of Allergy and Infectious Diseases (R01 085276), USA

We extend our gratitude to the entire CEPAC-International team and investigators including: Xavier Anglaret, Ingrid Bassett, Linda-Gail Bekker, Andrea Ciaranello, Christine Danel, Timothy Flanigan, Kenneth A. Freedberg, Sue J. Goldie, Nagalingeswaran Kumarasamy, Marc Lipsitch, Elena Losina, Neil A. Martinson, Kenneth Mayer, Eugene Messou, Eric Ouattara, A. David Paltiel, Stephen Resch, George R. Seage III, Soumya Swaminathan, Rochelle P. Walensky, Milton C. Weinstein, Robin Wood, Yazdan Yazdanpana.

Author’s contribution

Eric N. Ouattara, MD, MPH Conception and design
Doing runs and calculations
Drafting and writing of the manuscript
Tables and figures
Xavier Anglaret, MD, PhD Conception and design
Clinical expertise
Modeling expertise
Critical revision of the manuscript
Angela Y. Wong, BS Modeling expertise
Doing runs and calculations
Critical revision of the manuscript
Jennifer Chu, BS Modeling expertise
Revision of the manuscript
Heather E. Hsu, MPH Modeling expertise
Revision of the manuscript
Christine Danel, MD, PhD Clinical expertise
Revision of the manuscript
Serge Eholié, MD, MSc Clinical expertise
Revision of the manuscript
Raoul Moh, MD, MPH Clinical expertise
Revision of the manuscript
Delphine Gabillard, MSc Providing input data
Revision of the manuscript
Rochelle, P. Walensky, MD, MPH Clinical expertise
Modeling expertise
Revision of the manuscript
Kenneth, A. Freedberg, MD, MSc Conception and design
Clinical expertise
Modeling expertise
Critical revision of the manuscript
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Footnotes

Conflicts of Interest Statement

All authors declare no conflicts of interest.

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