Walker et al³⁰ estimated the effects of CTX prophylaxis on “clinical outcomes” (including malaria) in a retrospective study, which enrolled HIV-infected ART-naive adults who were started on ART, with CD4 cell counts <200 per microliter. This observational analysis used data from the “routine versus clinically driven laboratory monitoring of HIV antiretroviral therapy in Africa” (DART) study, conducted in 2 centers, in Uganda and in Zimbabwe. Because of low malaria endemicity in Zimbabwe, the analysis of the effect of CTX on malaria was confined to Uganda. The study showed a statistically significant reduction in the frequency of malaria with diagnosis based on either symptoms or positive microscopy, in persons on CTX (OR: 0.74, 95% CI: 0.63 to 0.88, P = 0.0005); the effect was sustained until 72 weeks of follow-up [between 48 and 72 weeks on ART, persons receiving CTX prophylaxis had an OR of developing malaria of 0.50 (95% CI: 0.33 to 0.74, P = 0.001)].³⁰ Mermin et al (2006) was a 4-phase prospective longitudinal study whose primary purpose was to address the effect of ART on the frequency of “clinical malaria” in PLHIV and to determine the “additive effects” of CTX prophylaxis, ART, and ITNs. The study showed a statistically significant association between CTX prophylaxis and reduced malaria incidence, defined as a febrile episode combined with a positive microscopic examination (adjusted IRR: 0.24, 95% CI: 0.15 to 0.38).³²

The study by Iliyasu et al³³ was a cross-sectional study whose primary aim was to assess the “prevalence and predictors” (including CTX prophylaxis and ITNs use) of malaria among adult PLHIV. Most of the respondents in this study (86.0%) were receiving CTX prophylaxis and 53.5% reported use of ITNs. The study did not demonstrate a significant difference in prevalence of “clinical malaria” (symptomatic parasitemia) among those who reported use of CTX prophylaxis, compared with those not having been on CTX prophylaxis (adjusted odds ratios (aOR): 1.27, 95% CI: 0.98 to 1.64, P = 0.13).³³ Statistically significant differences were, however, identified using a multivariate analysis aimed at addressing potential associations between reported “clinical malaria” with baseline CD4 cell count <350 per microliter vs. >600 per microliter and non-use of ITNs (aOR: 2.41, 95% CI: 1.23 to 3.74, P = 0.023; and 1.97, 95% CI: 1.17 to 2.85, P = 0.017, respectively).³³

Saracino et al,²⁹ in a prospective longitudinal study, enrolled consecutively hospitalized adults who received “HIV testing, malaria blood smear, and, in a subgroup of patients, a rapid malaria test (RDT).” The study aimed at assessing the association between a positive malaria blood smear and/or RDT and the prevalence of “clinical malaria” (symptomatic parasitemia) with concomitant HIV infection and, secondarily, with the use of CTX and/or ART. 66.7% of enrollees were HIV positive and 35.4% of HIV-positive patients reported having a CTX prophylaxis prescription at the time of admission. The study showed a statistically significant association between CTX prophylaxis and positive malaria testing (OR: 0.20, 95% CI: 0.14 to 0.61, P < 0.001).²⁹

The study by Campbell et al¹⁹ was an RCT in which HIV-infected persons stable on ART and with CD4 cell counts above 200 per microliter were assigned to either continuation or discontinuation of CTX prophylaxis. Participants were assessed primarily for malaria and diarrhea-related outcomes. Enrollees who discontinued CTX prophylaxis were at a significantly higher risk of developing clinical malaria compared with those who continued CTX prophylaxis (RR of malaria 32.5, 95% CI: 8.6 to 275.0, P < 0.001). This study was stopped in its fourth month, as recommended by the Data Safety and Monitoring Board (DSMB); consequently, it was impossible to exclude a “short-lived rebound effect” as an explanation of the increased incidence of malaria illness.¹⁹ “Rebound effects” are thought to be a result of an “impairment of the immunity protective effect,” as a consequence of the use of antimalarial therapies^39–41 (it has been suggested that the role of “persisting asymptomatic and polyclonal P. falciparum infections,” which occur in the absence of malaria prophylaxis in settings of intense malaria transmission, could be a potential explanation of the observed “rebound effect” after the interruption of prophylaxis).^41–43

The study by Polyak et al (an RCT) aimed to determine the impact of CTX prophylaxis discontinuation on morbidity among HIV-infected adults who had been on ART for more than 18 months and who had a CD4 cell count >350 per microliter (CD4 count at enrollment was estimated at 595 cells/μL, and median ART duration was 4.5 years).²⁸ The primary end-point consisted of a “composite of morbidity (malaria, pneumonia, and diarrhea) and mortality.” Enrollees who discontinued CTX prophylaxis had a significantly higher risk of the predefined end-point compared with those who continued CTX prophylaxis (combined morbidity/mortality IRR: 2.27, 95% CI: 1.52 to 3.38, P < 0.001). Malaria, defined here as a febrile episode confirmed with either a positive RDT or smear examination, was deemed to be the “driver” of the higher risk finding (IRR estimated at 33.02, 95% CI: 4.52 to 241.02, P = 0.001).²⁸

Five individual studies, including 2 RCTs^20,24 and 3 OS,^21,23,27 addressed the effect of CTX on malaria end-points in HIV-infected pregnant women, compared with either IPTp-SP or mefloquine (MQ). Klement et al²⁴ (an RCT) assessed the risk of developing malaria in HIV-infected pregnant women with a CD4 cell count >200 per microliter. The study compared the effectiveness of CTX prophylaxis with that of IPTp-SP in preventing malaria during pregnancy in a P. falciparum–endemic area in Togo. In the CTX arm, 75.4% of women did not develop malaria (defined as a thick blood smear or RDT-confirmed case of a symptomatic malaria episode) compared with 84.7% of women in the IPTp-SP arm. The difference was estimated at 9.3%, 95% CI: −0.53 to 19.1, not meeting the predefined “non-inferiority” criterion. The authors did not conclude that CTX was inferior to IPTp-SP regarding malaria-free survival (the study was designed to assess “non-inferiority”), but the difference in point estimates of malaria-free rates suggests that CTX could potentially be inferior to IPTp-SP. It is noteworthy that the author did not report on the proportions of enrollees who received 2 vs 3 doses of IPTp-SP; the third dose of IPTp-SP was given “when possible.”²⁴ It is therefore possible that CTX prophylaxis would have been shown to be inferior had the subjects received the WHO-recommended 3 doses of IPTp-SP.⁸

In the RCT conducted by Denoeud-Ndam et al,²⁰ CTX was found to be non-inferior when compared with CTX plus MQ in preventing microscopically diagnosed placental malaria in HIV-infected women with CD4 cell counts <350 cells per microliter. However, using polymerase chain reaction (PCR)–based diagnosis, placental malaria was significantly less likely to be diagnosed in women who received CTX + MQ compared with those who received CTX only (0/105 and 5/103, respectively, P = 0.03).²⁰

The study by Dow et al²¹ was a retrospective study whose main purpose was to assess the effect of CTX prophylaxis on malaria during pregnancy, low birth weight, and preterm birth in women enrolled in the “Breastfeeding, Antiretroviral, and Nutrition” RCT, which was conducted in Malawi between 2004 and 2009. The implementation of CTX prophylaxis 2 years after the start of this RCT represented an opportunity to assess the effect of CTX prophylaxis. CTX prophylaxis was implemented in 2006. The analysis showed a statistically significant protective effect of CTX prophylaxis against malaria (defined as “the first episode after the second prenatal visit,” clinically diagnosed and laboratory-confirmed), as compared with IPTp (malaria HR: 0.35, 95% CI: 0.20 to 0.60). However, a “sensitivity analysis” of malaria rates in CTX-ineligible women (with CD4 counts >500/μL) in the 2 time-periods indicated that women were at lower risk of malaria after 2006; after adjustment for time-period, CTX prophylaxis was no longer found to be protective against malaria (aHR 0.66, 95% CI: 0.28 to 1.52).²¹

In Kapito et al, data from a cross-sectional study that was conducted to assess the effects of iron supplementation on “maternal morbidities” were used to assess the prevalence of malaria parasitemia and anemia in HIV-infected pregnant women who received CTX prophylaxis, with or without IPTp-SP, compared with women who received IPTp-SP only. Women enrolled in this study were aged 15 or older, less than 34 weeks pregnant, and were attending a routine antenatal care routine visit. Participants were required to respond to a questionnaire and submit to a physical examination, followed by malaria laboratory testing (smear microscopy and PCR).²³ Enrollees had a median CD4 cell count of 423 cells per microliter (ranging from 11 to 1528 cells/μL), use of nets was reported by 59.6% of enrolled women, and 48.5% of the women reported ART. After adjusting for potential confounders, women taking CTX, with or without IPTp-SP, were less likely to have “microscopic” or “PCR-detected” malaria infection, compared with women who received IPTp-SP alone (infection OR: 0.09, 95% CI: 0.01 to 0.66 and 0.43, 95% CI: 0.19 to 0.97, respectively). Possible confounding factors, such as “ITN use, ART use,” and the change in the newly implemented national malaria prevention guidelines, may have prevented a more accurate analysis and interpretation of the study's findings, a challenge that could not be addressed, given the non-randomization nature of this study.²³

Newman et al conducted a cross-sectional study that aimed at comparing the prevalence of placental malaria in HIV-infected pregnant women receiving CTX prophylaxis with that in HIV-uninfected pregnant women receiving IPTp-SP. After adjusting for factors including “gravidity, age, and season at the time of delivery,” no significant difference was found in terms of placental malaria prevalence at delivery, between HIV-infected women who received CTX prophylaxis as compared with HIV-uninfected women on IPTp-SP.²⁷

In the study by Manyando et al,²⁵ which included some of the individual studies in this review,^{23,26,27,30,32} CTX was found to reduce malaria incidence by 46%–97%.

Of the 19 studies that addressed malaria-related morbidity outcomes (excluding the 3 health economics studies), 4 studies addressed the use of ITNs.^32–35

The study by Mermin et al³² (2006) was a 4-phase study in which 3 interventions (CTX prophylaxis, ART, and nets) were sequentially offered to participants who were enrolled at different points throughout the study's duration. CTX prophylaxis was found to have a protective effect against “clinical malaria” (“reported fever in the previous 2 days,” confirmed through both a thick and a thin smear exam). Malaria adjusted-IRR (aIRR) was estimated at 0.05, 95% CI: 0.03 to 0.08.³²

A descriptive cross-sectional study reported by Olowookere et al³⁴ enrolled a “convenience sample” of newly recruited PLHIV who were submitted to malaria screening, treated if diagnosed with malaria, educated about malaria infection, provided with an ITN, and finally evaluated for malaria infection on a monthly basis during a 3-month follow-up period. A decrease in prevalence of positive P. falciparum parasitemia from 59.7% at baseline to 5.1% at the end of the 3-month period was observed. The authors did not report on a precise value of the effect estimate.³⁴

The study by Walson et al was a prospective cohort study that assessed the potential effect of “LLINs and simple point-of-use water filters” on the slowing of HIV-1 disease progression. The study's 2 primary end-points consisted of “time to CD4 cell count <350 cells per microliter” and “a composite end-point of time to CD4 cell count <350 cells per microliter and non-traumatic death.” Enrollment criteria included “HIV-1 infection, age >18, absence of a history of ART, a CD4 cell count >350 per microliter, and WHO stage I or II disease.”³⁵ The study addressed malaria morbidity as a secondary end-point by measuring the incidence of both “self-reported” (symptomatic) and “laboratory-confirmed malaria.” Enrollees were followed for up to 24 months. Participants in the intervention cohort (receiving LLINs and water filters) were less likely to self-report malaria within the previous 3 months compared with participants in the control cohort (RR: 0.75, 95% CI: 0.60 to 0.93). “Clinically diagnosed” malaria was also less likely to be identified by a health care provider within the previous 3 months among subjects who received LLINs and water filters, compared with those who did not (RR: 0.66, 95% CI: 0.49 to 0.88). There was no difference in the use of CTX prophylaxis between the cohorts (99.7% and 99.8% in the intervention and in the control group of patients, respectively, P = 0.8).³⁵ Finally, participants who received and used LLINs and point-of-use water filters were found to have a significantly lower risk of having their CD4 cell counts decline to below 350 cells per microliter (HR: 0.73, 95% CI: 0.57 to 0.95).³⁵

The study by Iliyasu et al³³ was a cross-sectional study that primarily aimed at estimating the “prevalence and predictors of malaria infection among HIV-positive patients attending a referral center.” The study showed that “clinical malaria” (symptoms and parasitemia) was significantly associated with the non-use of ITN (aOR: 1.97, 95% CI: 1.17 to 2.85, P = 0.017).³³

No relevant studies meeting the selection criteria for this review were found.

Kern et al,³⁸ in a study rated “level 1,” reported the “effectiveness, cost, and cost-effectiveness” of providing “LLINs and point-of-use water filters” to ART-naive HIV-infected adults and their family members. Data for this study were abstracted from an OS that enrolled 589 HIV-infected adults, conducted in Kenya, and which assessed the association between “LLITN use and water filters” and the progression of HIV-1 disease, as measured by “CD4 cell count decline” and/or “time to death.” Total costs averted were estimated at $34,975 [ART-related costs (because of delay in need for ART), costs averted by LLINs (malaria) and “costs averted” by water filters (diarrhea) were estimated at $24,395, $747, and $9,834, respectively]. A net cost savings of about US $26,000 was found for the intervention over 1.7 years. The authors concluded that the combined intervention cost of US $3100 per death averted or US $99 per disability-adjusted life year (DALY) averted, and that the estimated cost-effectiveness ratios were in the range of cost-effectiveness ratios for other prevention interventions for the 3 addressed diseases (HIV/AIDS, malaria, and diarrhea). It is noteworthy that the combined prevention interventions including LLINs averted substantial costs in terms of new ART initiations during the intervention period. For instance, the costs averted from malaria per se are small but the value of CTX and LLINs in terms of delaying ART costs is potentially important.³⁸

Kahn et al³⁶ (2011), in a study rated “level 2,” provided cost information for bednet provision as part of an “Integrated Prevention Campaign,” which consisted of the provision of nets, filters, HIV testing, and condoms. The study helped determine the necessary resources needed for implementation of the campaign. Findings showed a “projected unit cost” per person served, by disease, estimated at $6.27 for malaria (nets and training), $15.80 for diarrhea (filters and training), and $9.91 for HIV (test kits, counseling, condoms, and CD4 testing at each site).³⁶

Kahn et al³⁷ (2012), a level 1–rated study, addressed the CE of the aforementioned “Integrated Prevention Campaign” using a “spreadsheet-based model.” Existing data regarding the impact of the each of the 3 assessed interventions (VCT, LLINs, and water filters) on morbidity and mortality, along with the available costing information from the same campaign (in the study of Kahn et al. 2011), were used to determine estimates of averted deaths, DALYs, and cost savings. The model-based analysis included added costs associated with potential earlier ART initiation as well. Per 1000 campaign beneficiaries, the provision of LLINs allowed for the aversion of 4.31 deaths, 1304 malaria episodes, 125 DALYS, and $10,420 of costs. Findings were robust to the sensitivity analyses performed. Kahn et al³⁷ concluded a more “favorable outcome” in their study, compared with the CE of existing published findings regarding malaria prevention–related interventions (a cost ranging from $2 to 15 per DALY averted⁴⁴).

Of the 17 studies that addressed morbidity (including the 2 studies that addressed both CTX prophylaxis and ITNs use^32,33), the quality of the evidence was rated as “strong” for 6 studies,^{17,19,20,24,25,28} “medium” for 10 studies,^{21–23,26,27,29,30,32–34} and “weak” for 1 study (Table 1; see Table S1, Supplemental Digital Content, http://links.lww.com/QAI/A656).¹⁸ The overall quality of the evidence in these studies was rated as “good.” The expected impact of CTX prophylaxis on malaria-related morbidity reduction was rated as “high” (Table 1).

Data were very limited regarding the impact of ITNs/LLINs provision and/or use on malaria morbidity reduction in HIV-infected persons. Four studies addressed morbidity^32–35 (excluding the 3 health economics studies^36–38 and including the 2 studies that addressed both ITNs use and CTX prophylaxis).^32,33 The quality of each of the 4 studies was rated as “medium.” The overall quality of evidence was rated as “fair” and the impact of ITNs/LLINs was rated as “uncertain” (Table 1). The scarcity of the evidence did not allow for a more robust assessment of the potential impact of LLINs provision and/or use on malaria prevention.