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            You are hereHome » Research » Intervention Reports » Seasonal Malaria Chemoprevention Seasonal Malaria Chemoprevention     FacebookTwitter>Print>Email                   Summary  What is the program? Seasonal malaria chemoprevention (SMC) involves giving children under the age of 5 full malaria treatment courses intermittently during the malaria season. In general, we focus our discussion on work similar to that of Malaria Consortium’s SMC program (one of our top charities). What is its evidence of effectiveness? Seven randomized controlled trials provide strong evidence that this program reduces cases of malaria in the treated population. The trials were insufficiently powered to detect effects on all-cause mortality. One randomized controlled trial provides evidence we find compelling that SMC also reduces cases of malaria incidence in the untreated population. How cost-effective is it? SMC programs appear to be in the range of cost-effectiveness of our other priority programs. Does it have room for more funding? It appears that there is a large remaining global need for additional funding for SMC programs. Bottom line: SMC is one of our priority programs.  Published: November 2017; Last updated: October 2018

 



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 November 2017 version  Table of Contents   Summary What is the problem? What is the program? Does the program have strong evidence of effectiveness?  Evidence from randomized controlled trials How does the Malaria Consortium SMC program compare to the programs addressed in these studies?  Does the reduction in malaria incidence cause a similar reduction in mortality?  Evidence of implementation at scale Indirect effects on the untreated population Possible developmental effects Possible negative / offsetting impacts   How cost-effective is the program? Does the program appear to have room for more funding? Our process  2016 2017 2018   Sources    What is the problem? Malaria is one of the leading causes of child deaths in Africa.1 It is transmitted from person to person by infected mosquitoes.2 It involves flu-like symptoms including fever.3 As discussed below, there is evidence connecting malaria with death (particularly in children under 5), anemia, splenomegaly (enlarged spleen), other nutrition-deficiency-related indicators, and low birthweight.

 It is also believed that malaria can cause permanent disability (hearing impairment, visual impairment, epilepsy, etc.).4

 What is the program? The World Health Organization (WHO) defines seasonal malaria chemoprevention as "the intermittent administration of full treatment courses of an antimalarial medicine to children during the malaria season in areas of highly seasonal transmission."5 It "consists of administering a maximum of four treatment courses of SP [sulfadoxine–pyrimethamine] + AQ [amodiaquine] at monthly intervals to children aged 3–59 months in areas of highly seasonal malaria transmission"6 and "during the high malaria transmission period."7 SMC was "formerly known as ‘intermittent preventive treatment of malaria in children [IPTc].'"8

 According to the World Health Organization (WHO):

  The suitability of an area for SMC is determined by the seasonal pattern of rainfall, malaria transmission and the burden of malaria. SMC is recommended for deployment in areas: where more than 60% of the annual incidence of malaria occurs within 4 months; where there are measures of disease burden consistent with a high burden of malaria in children (incidence ≥ 10 cases of malaria among every 100 children during the transmission season); where SP and AQ retain their antimalarial efficacy.9  According to the WHO, "SMC provides protection for up to 1 month after each complete (3-day) course…. Health workers should give the dose of SP and the first dose of AQ to the children under their direct observation and should advise the children’s caregivers on how to give the second and third doses of AQ to the child at home."10

 Does the program have strong evidence of effectiveness? Seven randomized controlled trials provide strong evidence that this program reduces cases of malaria. A 2012 Cochrane Collaboration review concluded, "In areas with seasonal malaria transmission, giving antimalarial drugs to preschool children (age [less than] 6 years) as IPTc during the malaria transmission season markedly reduces episodes of clinical malaria, including severe malaria. This benefit occurs even in areas where insecticide treated net usage is high."11 The trials were insufficiently powered to detect effects on all-cause mortality.

 Evidence from randomized controlled trials The Cochrane review summarizes the results of seven randomized controlled trials (RCTs). It states:

  Seven trials (12,589 participants), including one cluster-randomized trial, met the inclusion criteria. All were conducted in West Africa, and six of seven trials were restricted to children aged less than 5 years. IPTc prevents approximately three quarters of all clinical malaria episodes (rate ratio 0.26; 95% CI 0.17 to 0.38; 9321 participants, six trials, high quality evidence), and a similar proportion of severe malaria episodes (rate ratio 0.27, 95% CI 0.10 to 0.76; 5964 participants, two trials, high quality evidence). These effects remain present even where insecticide treated net (ITN) usage is high (two trials, 5964 participants, high quality evidence). 

 IPTc probably produces a small reduction in all-cause mortality consistent with the effect on severe malaria, but the trials were underpowered to reach statistical significance (risk ratio 0.66, 95% CI 0.31 to 1.39, moderate quality evidence). The effect on anaemia varied between studies, but the risk of moderately severe anaemia is probably lower with IPTc (risk ratio 0.71, 95% CI 0.52 to 0.98; 8805 participants, five trials, moderate quality evidence). Serious drug-related adverse events, if they occur, are probably rare, with none reported in the six trials (9533 participants, six trials, moderate quality evidence). 

 Amodiaquine plus sulphadoxine-pyrimethamine is the most studied drug combination for seasonal chemoprevention. Although effective, it causes increased vomiting in this age-group (risk ratio 2.78, 95% CI 2.31 to 3.35; two trials, 3544 participants, high quality evidence). When antimalarial IPTc was stopped, no rebound increase in malaria was observed in the three trials which continued follow-up for one season after IPTc.12 

 We have applied two adjustments to the results of the Cochrane meta-analysis on clinical malaria incidence:

 We identified two additional RCTs (Tagbor et al. 2016, Matalinga et al. 2015) published after the Cochrane review, which compare SMC with placebo. Both found smaller effect sizes on incidence of clinical malaria than the pooled results of the Cochrane meta-analysis.13 We added Tagbor et al. 2016 to our updated version of the Cochrane meta-analysis, but did not add Matalinga et al. 2015 because courses were delivered at three monthly (rather than one monthly) intervals, and so are unlikely to have achieved similar reductions in malaria incidence to Malaria Consortium’s SMC program.14  One of the RCTs (Dicko et al. 2008) included in the meta-analysis treated participants every eight weeks (rather than monthly, as in the Malaria Consortium program). We have removed this study from the meta-analysis.15 After these two adjustments, the pooled estimate of the effect of SMC on clinical malaria episodes increases slightly (rate ratio 0.25; 95% CI 0.18 to 0.37).16

 A World Health Organization report claims that SMC offers a high level of protection for about four weeks after the last treatment, after which protection appears to decline.17 We have not independently vetted this claim. We note that some of the trials continued to collect malaria incidence up to six weeks after the last treatment was administered, which could underestimate the level of protection over a four week period. We have not included an adjustment to account for this underestimate because the trials do not report sufficiently granular data to separately estimate protective efficacy for the period up to four weeks after the last treatment.18

 The Cochrane review also notes there is substantial heterogeneity between the program results, meaning the variance between results of different trials is unlikely to have occurred by chance.19 The authors note there are insufficient trials to make meaningful conclusions about the causes of this heterogeneity.20 We reviewed two of the studies which find substantially lower reductions in malaria incidence (Dicko et al. 2008; Tagbor et al. 2016), and note possible causes in this footnote.21 

 How does the Malaria Consortium SMC program compare to the programs addressed in these studies? We examined the individual studies included in the Cochrane review to better understand how they compared to the Malaria Consortium SMC program (one of our top charities).

  We found:

 Six of the seven trials delivered treatment on a monthly basis, as in Malaria Consortium's program.22 Four of the seven trials treated children with a combination of sulfadoxine-pyrimethamine (SP) and amodiaquine (AQ), as in Malaria Consortium's program.23 All seven trials were conducted in West Africa, where Malaria Consortium operates.24 Six of the seven trials only treated children under 59 months of age, as in Malaria Consortium's program.25 The number of courses ranged between two and five. Malaria Consortium typically delivers four courses.26 Coverage of insecticide treated nets (ITNs) varied widely between <5% and 93%.27 Weighted average coverage of SMC was ~90%, higher than our estimate of Malaria Consortium's coverage.28 We conclude that the trials in the Cochrane review are reasonably similar to Malaria Consortium's SMC program. We have included an adjustment in our cost-effectiveness analysis to account for differences in coverage between the RCTs and Malaria Consortium’s program.29

  Does the reduction in malaria incidence cause a similar reduction in mortality? The trials included in the Cochrane review were underpowered to detect a significant effect on all-cause mortality.30 

 Our best guess is that the reduction in malaria incidence results in a similar reduction in mortality. We have limited evidence to support this claim but note that:

 We would expect that a reduction in clinical malaria from SMC results in a similar reduction in malaria mortality unless there was evidence that SMC was disproportionately likely to prevent non-severe cases of malaria. The Cochrane review finds that SMC prevents a similar proportion of severe malaria episodes and all clinical malaria episodes, though only two trials measured effects on severe malaria.31 The Cochrane review notes that "IPTc probably produces a small reduction in all-cause mortality consistent with the effect on severe malaria, but the trials were underpowered to reach statistical significance (risk ratio 0.66, 95% CI 0.31 to 1.39, moderate quality evidence)."32 We have included an optional downward adjustment (which some contributors use) in our cost-effectiveness analysis to account for the possibility that SMC causes a smaller reduction in malaria mortality than malaria incidence.33

 Evidence of implementation at scale We haven't seen rigorous evaluations of SMC's impact on mortality at large scale. However, we discuss implementation of SMC at scale and the coverage achieved by such programs in our Malaria Consortium review.

 Indirect effects on the untreated population Treating children with seasonal malaria chemoprevention may disrupt malaria transmission, reducing incidence of malaria in the wider (untreated) population. One RCT (Cisse et al. 2016) estimates protection to the untreated population. We place weight on this study because it appears to be a high-quality study with a large number of participants.34 

 We discuss Cisse et al. 2016 below.

 Study design and intervention

 Cisse et al. 2016 is a stepped-wedge cluster-randomized controlled trial of SMC delivered to children aged between 3 months and 10 years in Senegal between 2008 and 2010.35 The intervention was similar to the program implemented by Malaria Consortium, involving monthly treatment of children with sulfadoxine-pyrimethamine (SP) and amodiaquine (AQ) during the high-transmission season.36 However there were also substantial differences between this intervention and Malaria Consortium programs, such as that it treated children over 5 years old. Below, we discuss how we adjust for such differences when applying these results to Malaria Consortium programs.

 Results

 The trial found a 60% reduction (95% CI 55%-67%) in malaria incidence (measured by rapid diagnostic test) in children living in areas which received SMC in a particular year, relative to children living in areas not receiving SMC that year.37 Malaria incidence amongst the untreated population (over the age of 10) was 26% lower (95% CI 18%-33%) in areas where SMC was delivered compared to controls.38 

 The study did not detect an effect on all-cause mortality.39 It was initially designed to have sufficient power to detect a decline in all-cause mortality,40 but mortality was lower than expected in both the treatment and control areas.41

 Conclusion Overall, we take Cisse et al. 2016 as providing some evidence that SMC reduces incidence of malaria in the untreated population. 

 In order to apply the findings from Cisse et al. 2016 to Malaria Consortium programs, we adjust for major differences between Cisse et al. 2016's intervention and context versus Malaria Consortium's. Two factors make us believe that the indirect effects in Malaria Consortium programs are likely to be about a third as large as Cisse et al. 2016:42

 The typical Malaria Consortium program treats children between the ages of 3 months and 5 years old (rather than children aged 3 months to 10 years, as in Cisse et al. 2016). We expect that since a smaller proportion of the population is directly treated in Malaria Consortium-supported contexts, there would also be smaller effects on the untreated population. We asked a malaria researcher how they would adjust for this factor and adopted their assumptions, which are based on an unpublished model. We have not vetted this model and our understanding is that it has been tested against limited empirical data, but it represents our current best guess.43 Our understanding from a conversation with a malaria researcher is that Cisse et al. 2016 was conducted in an area of Senegal with lower malaria transmission intensity than the typical Malaria Consortium program, and this would lead to somewhat smaller indirect effects in Malaria Consortium’s program. To adjust for this factor, we relied on the aforementioned model that we have not vetted.44 Possible developmental effects Reducing exposure to malaria during childhood may have an effect on long term productivity and earnings, although we are uncertain about the magnitude of this effect. We have reviewed the evidence for the developmental effects of malaria prevention here.

 

Possible negative / offsetting impacts Possible development of drug resistance. Resistance to Amodiaquine (AQ), and sulphadoxine-pyrimethamine (SP) may reduce the effectiveness of SMC over time. We spoke with Professor Sir Brian Greenwood (Professor of Clinical Tropical Medicine at London School of Hygiene & Tropical Medicine) about timelines for possible development of drug resistance. He told us: Timelines are uncertain, but he believes based on historical experience that resistance to AQ/SP is unlikely to develop in the next 5-10 years.45 Some resistance to SP may have emerged in East Africa46, but AQ has relatively little history of resistance.47 If resistance to SP/AQ did develop, dihydroartemisinin-pipearquine (DHAPQ) may be a viable alternative, although we have not carefully reviewed the evidence for DHAPQ.48 We have not vetted these claims but they are consistent with our general impressions from reviewing relevant literature.

 Possible rebound effects. One potential issue with SMC is the possibility of disease rebound after treatment ends. We have not investigated this possibility in depth, but note that the Cochrane review includes three RCTs with post-intervention follow-up, none of which find evidence of a rebound effect.49 We are not aware of any studies done to measure rebound effects after multiple years of treatment.50 Possible interaction with insecticide treated nets (ITNs). Two of the RCTs in the Cochrane review promoted the use of ITNs to both the intervention and control group.51 These trials found similar proportional reductions in malaria incidence to trials which did not promote ITNs.52 If SMC and ITN coverage are expanded in the same area at the same time, it is possible that the absolute reduction in malaria incidence attributable to each would be reduced. We have not carefully considered whether Malaria Consortium’s SMC program is operating in areas where ITN coverage is being expanded. Possible serious adverse events. We lightly reviewed two large studies that tracked adverse events in recent SMC distributions in sub-Saharan Africa. We did not deeply vet these studies' methodologies, but they seemed to implement reasonable universal surveillance systems and found very low rates of serious adverse events and no deaths that were clearly attributable to SMC. We did a back-of-the-envelope calculation using very pessimistic assumptions that suggests severe adverse events from SMC are very small in comparison to the magnitude of the benefits. More details in this document. We discuss possible minor side effects of treatment here. How cost-effective is the program? SMC programs appear to be in the range of cost-effectiveness of our other priority programs. See our most recent cost-effectiveness model for estimates of the cost per life saved through Malaria Consortium-supported SMC programs. See our Malaria Consortium review for more details on the cost-per-treatment for SMC.

 Note that our cost-effectiveness analyses are simplified models that do not take into account a number of factors. For example, our model does not include the short-term impact of non-fatal cases of malaria prevented. It also does not include possible offsetting impacts or other harms.53

 There are limitations to this kind of cost-effectiveness analysis, and we believe that cost-effectiveness estimates such as these should not be taken literally, due to the significant uncertainty around them. We provide these estimates (a) for comparative purposes and (b) because working on them helps us ensure that we are thinking through as many of the relevant issues as possible.

 Does the program appear to have room for more funding? For information on the global need for treatment and other potential funders of this program, see this section of our Malaria Consortium review.

 Our process 2016 In 2016 we completed an interim intervention report on SMC. We reviewed the Cochrane Collaboration review (discussed above), the ACCESS-SMC website, the section of the WHO website devoted to SMC, and some documents provided to us by Malaria Consortium.

 2017 We investigated a small number of high-priority research questions based on our impression of the likelihood that they could substantively change our view of SMC:

  We reviewed the individual studies in the Cochrane Collaboration review and removed one (Dicko et al. 2008) because it delivered treatments bi-monthly rather than monthly.  We searched for additional RCTs published after the Cochrane Collaboration review and added one (Tagbor et al. 2016) to the meta-analysis.  We investigated possible negative / offsetting impacts including (i) possible emergence of drug resistance, (ii) possible interaction with ITNs, (iii) rebound effects.  We updated our coverage adjustment to account for imperfect coverage in the trials in the Cochrane Collaborate review.  We explored possible sources of heterogeneity in the effects of SMC, which we will use to inform our questions for potential top charities. 2018 We prioritized reviewing research in two areas that we believed were most likely to substantially affect our cost-effectiveness analysis:

 We reviewed a new trial (Cisse et al. 2016), which found reductions in malaria incidence in the untreated population and discussed how to extrapolate from the trial to the Malaria Consortium program with two malaria researchers (more here). This work led to a moderate positive update. We reviewed the literature on the long run economic impact of preventing malaria. We have not yet published our conclusions from this work. We also considered using sub-national (rather than country-level) estimates of malaria prevalence to improve the precision of our cost-effectiveness analysis. We decided not to incorporate these adjustments into our model, because we believed the effect on the bottom line was insufficient to justify the additional complexity. See this blog post for more details.

 Sources Document Source ACCESS-SMC: Partners Source (archive) Catholic Relief Services: ACCESS-SMC in the Sahel Source (archive) Cissé et al. 2006 Source (archive) Cisse et al. 2016 Source Cochrane: Identifying and measuring heterogeneity Source (archive) Dicko et al. 2008 Source (archive) Dicko et al. 2011 Source (archive) GiveWell - SMC indirect effects calculations Source GiveWell update of Meremikwu et al. 2012 meta-analysis (Forest plot) Source GiveWell update of Meremikwu et al. 2012 meta-analysis (RevMan file) Source GiveWell's analysis of SMC coverage in RCTs Source GiveWell's non-verbatim summary of a conversation with Professor Sir Brian Greenwood, January 4 2017 Source GiveWell's SMC cost-effectiveness analysis Source IHME - malaria prevalence estimates Source Imperial College malaria model Source Jamison et al. 2006 Source (archive) Konaté et al. 2011 Source (archive) Kweku et al. 2008 Source (archive) Malaria Consortium: Seasonal Malaria Chemoprevention Source (archive) Management Sciences for Health. The cost and impact of ACCESS-SMC Source (archive) Matalinga et al. 2015 Source (archive) Meremikwu et al. 2012 Source (archive) Professor Matthew Cairns, email to GiveWell, September 19, 2018 Unpublished Seasonal malaria chemoprevention with sulfadoxine–pyrimethamine plus amodiaquine in children: a field guide Source (archive) Sesay et al. 2011 Source (archive) Tagbor et al. 2016 Source (archive) WebMD. Malaria: Topic overview Source (archive) Wilson 2011 Source (archive) World Health Organization. Seasonal Malaria Chemoprevention Source (archive) World Health Organization. Seasonal Malaria Chemoprevention. A Field Guide. 2013 Source (archive) World Health Organization. World Malaria Report (2015) Source (archive) Zongo et al. 2015 Source (archive) 1. "In 2015, malaria was the fourth highest cause of death, accounting for 10% of child deaths in sub-Saharan Africa." World Health Organization. World Malaria Report (2015), Pg x.

 2. "Human infection begins when the malaria vector, a female anopheline mosquito, inoculates plasmodial sporozoites from its salivary gland into humans during a blood meal. The sporozoites mature in the liver and are released into the bloodstream as merozoites. These invade red blood cells, causing malaria fevers. Some forms of the parasites (gametocytes) are ingested by anopheline mosquitoes during feeding and develop into sporozoites, restarting the cycle." Jamison et al. 2006, Pg 413.

 

 3. "Most malaria infections cause symptoms like the flu, such as a high fever, chills, and muscle pain. Symptoms tend to come and go in cycles. Some types of malaria may cause more serious problems, such as damage to the heart, lungs, kidneys, or brain. These types can be deadly." WebMD. Malaria: Topic overview.

 

 4. See Jamison et al. 2006, Pg 416, Table 21.3 for estimates of cases of hearing impairment, visual impairment, epilepsy, etc. caused by malaria.

 

 5. World Health Organization. Seasonal Malaria Chemoprevention.

 

 6. Seasonal malaria chemoprevention with sulfadoxine–pyrimethamine plus amodiaquine in children: a field guide, Pg 7.

 

 7. Seasonal malaria chemoprevention with sulfadoxine–pyrimethamine plus amodiaquine in children: a field guide, Pg 7.

 

 8. Seasonal malaria chemoprevention with sulfadoxine–pyrimethamine plus amodiaquine in children: a field guide, Pg 7.

 

 9. Seasonal malaria chemoprevention with sulfadoxine–pyrimethamine plus amodiaquine in children: a field guide, Pg 8.

 

 10. Seasonal malaria chemoprevention with sulfadoxine–pyrimethamine plus amodiaquine in children: a field guide, Pg 9.

 

 11. Meremikwu et al. 2012, Pg 2.

 

 12. Meremikwu et al. 2012, Pg 2.

 

 13. “IPTc prevents approximately three quarters of all clinical malaria episodes (rate ratio 0.26; 95% CI 0.17 to 0.38; 9321 participants, six trials, high quality evidence), and a similar proportion of severe malaria episodes (rate ratio 0.27, 95% CI 0.10 to 0.76; 5964 participants, two trials, high quality evidence)” Meremikwu et al. 2012, Pg 2. “Relative to the AL only group, the adjusted hazard ratio (aHR) was 0.62 (95% CI: 0.41, 0.93), P = 0.020 in the SMC group, a protective efficacy of 38.5% (95% CI 7.28%, 59.2%)” Tagbor et al. 2016, Pg 229.  “In endemic areas, malaria and its adverse effects in schoolchildren may be prevented by intermittent preventive treatment (IPTsc). However, the most appropriate drug regimen for IPTsc remains to be identified. A randomised controlled trial was conducted in Kinshasa, DRC. Enrolled schoolchildren were assigned to a passive control arm (n = 212), sulfadoxine/pyrimethamine (SP) (n = 202) or SP plus piperaquine (SP/PQ) (n = 202). The primary endpoint was haemoglobin (Hb) change. Secondary endpoints were anaemia, parasitaemia prevalence and clinical malaria incidence. Analysis was by modified intention-to-treat (mITT) and per-protocol. A linear mixed mode was used due to repeated measurements. Of 616 enrolled children, 410 (66.6%) were eligible for mITT analysis. The control arm was used as reference. After 12 months, the Hb level increased by 0.20 g/dL (95% CI -0.61 to 0.47; P = 0.168) and 0.39 g/dL (0.12-0.66; P < 0.01) in the SP and SP/PQ arms, respectively. SP treatment reduced anaemia, malaria parasitaemia and clinical malaria by 10% (0-20%; P = 0.06), 19% (2-33%; P = 0.042) and 25% (-32 to 57%; P = 0.37), respectively. The corresponding values for SP/PQ were 28% (19-37%; P < 0.001), 40% (26-52%; P < 0.001) and 58% (17-79%; P < 0.01). No deaths or severe adverse events (SAEs) were observed. SP/PQ offered substantial protection against anaemia, malaria parasitaemia and clinical malaria and showed no SAEs. SP/PQ, a combination of two long-acting non-artemisinin-based antimalarials, may be a valuable option for IPTsc in Africa.” Matalinga et al. 2015, Abstract. 

 14. “IPTsc with SP or SP/PQ was given at baseline (November 2012), at Month 4 (March 2013) and at Month 7 (June 2013).” Matalinga et al. 2015, Pg 340. Six of the seven RCTs included in delivered treatment on a monthly basis. See this section for more information. For our updated meta-analysis, see the updated RevMan file at GiveWell update of Meremikwu et al. 2012 meta-analysis (RevMan file) and GiveWell update of Meremikwu et al. 2012 meta-analysis (Forest plot) 

 15. “262 children 6 months-10 years in Kambila, Mali were randomized to receive either IPT with SP twice at eight weeks interval or no IPT during the transmission season of 2002 and were followed up for 12 months.” Dicko et al. 2008, Pg 1.

 

 16. For our updated meta-analysis, see the updated RevMan file at GiveWell update of Meremikwu et al. 2012 meta-analysis (RevMan file) and GiveWell update of Meremikwu et al. 2012 meta-analysis (Forest plot)

 17. “The results of clinical trials indicate that a high level of protection against uncomplicated clinical malaria is likely to be maintained for only 4 weeks after administration of each treatment course of SP+ AQ; thereafter, protection appears to decay rapidly.” World Health Organization. Seasonal Malaria Chemoprevention. A Field Guide. 2013, Pg 4.

 

 18. Cissé et al. 2006 followed up for 13 weeks, for three months of SMC treatment. “During 13 weeks of follow-up, the intervention led to an 86% (95% CI 80–90) reduction in the occurrence of clinical episodes of malaria” Pg 663. “one dose of artesunate and one dose of sulfadoxine-pyrimethamine, given on three occasions during the malaria transmission season, was undertaken in 1203 Senegalese children aged 2–59 months.” Pg 659. Dicko et al. 2011 followed up 6-7 weeks after the last round of SMC. “Passive surveillance for clinical malaria started at the time of the administration of the first dose of IPTc in August 2008 and continued until the end of the malaria transmission season in November/December 2008, 6–7 wk after the last round of IPTc.” Pg 4. Konaté et al. 2011 followed up 6 weeks after the last round of SMC. “A cross-sectional survey of all children enrolled in the study was carried out 6 wk after the last course of IPTc had been given (November 2008). Fever within the last 24 h was documented, and axillary temperature, weight, and height were measured. Thick and thin blood films and filter paper blood spots were prepared and Hb concentration was measured.” Pg 4. Kweku et al. 2008 appears to have followed up for six months for six treatments delivered monthly. “Children received study drugs every 28 days on six occasions.” ”During the six months of the intervention period, the incidence of anaemia, the primary trial endpoint, was significantly lower in all IPTc groups compared to the placebo group.” Sesay et al. 2011: It is unclear from the text what the precise period of surveillance was. Our best guess is surveillance covered a period of 3.5 months, for three treatments delivered at monthly intervals. “SP/AQ (person months at risk, 2248)” (Table 4); “SP/AQ (n = 639)” (Table 1). 2248/639=3.5 months. “monthly IPTc with a single dose of sulphadoxine/pyrimethamine (SP) plus three doses of amodiaquine (AQ) or SP and AQ placebos given by village health workers (VHWs) on three occasions during the months of September, October and November” Tagbor et al. 2016: It is unclear from the text what the precise period of surveillance was. It reports results “during the SMC period” but we are uncertain whether this period extended beyond four weeks after the last treatment.  “The protective efficacy of SMC was lower than expected during the SMC period, at around 38%, with no significant protection over the whole study period” Pg 233. 

 19. "We inspected the forest plots to detect overlapping CIs, applied the Chi2 test and a P value of 0.10 was used as the cut-off value to determine statistical significance. We also estimated the I2 statistic with values of 30 to 59%, 60 to 89% , and 90 to 100% used to denote moderate, substantial and considerable levels of heterogeneity respectively." Meremikwu et al. 2012, Pg 8. "Heterogeneity: Tau2 = 0.20, Chi2 = 84.28, df = 5 (P < 0.00001); I2 = 94%” Meremikwu et al. 2012, Analysis 1, Pg 40. 

 20. “The size of this effect varied from a 45% reduction in Mali (Dicko et al. 2008) to an 86% reduction in Senegal (Cissé et al. 2006). This variation could be explained by differences in efficacy between the antimalarial regimen used, by variation in local transmission or resistance patterns, or other factors related to the conduct of the trials. However there were insufficient trials to make meaningful conclusions from subgroup analyses exploring the effects of these factors (Analysis 2.1; Analysis 3.1).” Meremikwu et al. 2012, Pg 12.

 

 21. Dicko et al. 2008 had (i) a longer follow-up (ii) fewer treatments, and (iii) longer time interval between treatments than the other trials.

  Dicko et al. 2008 report reduction in incidence of malaria in the period 52 weeks after the start of the intervention. The other RCTs in the Cochrane review report incidence between 13 weeks and 6 months after the start of the intervention. Dicko et al. 2008: “Cisse et al [12] in Senegal found a reduction of 86% in incidence of clinical malaria children less than five years of age over 13 weeks period. This higher efficacy can be explained by the shorter time interval between treatments (four weeks instead of eight weeks), the number of intermittent treatments (three instead of two) and the shorter duration of the follow up (13 instead 52 weeks) [12].” Pg 7. Cissé et al. 2006: “During 13 weeks of follow-up, the intervention led to an 86% (95% CI 80–90) reduction in the occurrence of clinical episodes of malaria” Pg 663. Dicko et al. 2011: “Incidence rate expressed as number of episodes/child/year. Note that this is based on the 3-mo surveillance period and does not correspond to an annual rate.” Pg 9. Konaté et al. 2011: “From mid-September to the end of November 2008, 150 enrolled children were randomly selected and surveyed each week to monitor the prevalence of malaria infection.” Pg 4. Kweku et al. 2008: “During the six months of the intervention period, the incidence of anaemia, the primary trial endpoint, was significantly lower in all IPTc groups compared to the placebo group” Sesay et al. 2011: “SP/AQ (person months at risk, 2248)” (Table 4); “SP/AQ (n = 639)” (Table 1). 2248/639=3.5 months. Dicko et al. 2008 included two treatments with eight weeks between each treatment. The other RCTs in the Cochrane review include three to six treatments, with one month between each treatment.  Dicko et al. 2008: “Cisse et al [12] in Senegal found a reduction of 86% in incidence of clinical malaria children less than five years of age over 13 weeks period. This higher efficacy can be explained by the shorter time interval between treatments (four weeks instead of eight weeks), the number of intermittent treatments (three instead of two) and the shorter duration of the follow up (13 instead 52 weeks) [12].” Pg 7. Dicko et al. 2011: “Eligible children were treated with a course of SP+AQ or matching placebos on three occasions at monthly intervals during the malaria transmission season” Pg 4. Konaté et al. 2011: “to receive three courses of IPTc with SP plus AQ or placebos given at monthly intervals during the peak malaria transmission season.” Pg 14. Kweku et al. 2008: “2451 children aged 3–59 months from 30 villages were individually randomised to receive placebo or artesunate plus amodiaquine (AS+AQ) monthly or bimonthly, or sulphadoxine-pyrimethamine (SP) bimonthly over a period of six months.” Sesay et al. 2011: “During the 2008 malaria transmission season, 1,277 children under five years of age resident in villages within the rural Farafenni demographic surveillance system (DSS) in North Bank Region, The Gambia were randomized to receive monthly IPTc with a single dose of sulphadoxine/pyrimethamine (SP) plus three doses of amodiaquine (AQ) or SP and AQ placebos given by village health workers (VHWs) on three occasions during the months of September, October and November, in a double-blind trial” Tagbor et al. 2016 had (i) low coverage (ii) low malaria incidence prior to treatment (iii) unreliable adherence data, and (iv) the course did not start until the high transmission season was already in progress. “The lower efficacy may partly be due to relatively low coverage of all five SMC cycles (36.4% in the SMC group), but even among children who received five cycles of SMC, protective efficacy was around 47% during the SMC period, lower than the efficacy of 70-80% seen in other studies of monthly SP-AQ [4, 6, 7], or monthly artesunate-amodiaquine” Tagbor et al. 2016, Pg 233. “Overall efficacy might also be lower because incidence is relatively low in the study area as a whole: 7 of the 13 study communities have an annual incidence of malaria below 100 cases per 1000 child-years at risk, the lower limit suggested for SMC to be cost-effective [8]. In three small communities with a high prevalence of malaria at baseline and high incidence during the transmission season (Korase, Sarpeh and Timeabu) the protective efficacy of SMC (any number of cycles) was more consistent with earlier studies: 69.7% (95% CI: 22.7%, 88.1%). Potentially supporting this is the fact that there was no benefit of SMC on anaemia, in contrast to findings from SMC studies in high transmission areas [6, 7] but agreeing with areas of lower transmission [1].” Tagbor et al. 2016, Pg 233. “This could be a chance finding, because malaria incidence was low and confidence intervals for the efficacy are wide. However, if correct, it could suggest failure to complete the 3-day course of SMC (SP plus AQ on day one, AQ only on days two and three): although SP alone retains reasonably high efficacy in most of West Africa, the efficacy of SP plus AQ is higher [5]. Adherence data were collected but implausibly high values of adherence were reported, as seen elsewhere [23]” Tagbor et al. 2016, Pg 233. “Low efficacy may also be a consequence of the timing of administration of the first cycle of SMC. At the baseline survey in July, prevalence was around 26%, suggesting that the transmission season was well underway by this point. Although SP-AQ is likely to have very good curative efficacy in West Africa [24, 25], the benefit of SMC will likely be greater where children are protected prior to exposure each year. If SMC was started too late in 2012 relative to the start of the transmission season, this suggests that five cycles of SMC will be insufficient in this setting, as there was also some malaria incidence in January 2013. Seven or possibly eight cycles could cover the period between May and January, but this raises new questions of cost-effectiveness, and the safety and acceptability of a substantial additional number of SMC cycles.” Tagbor et al. 2016, Pg 233. 

 22. Cissé et al. 2006:"Intermittent treatment: IPTi with sulfadoxine-pyrimethamine plus artesunate given once monthly" Meremikwu et al. 2012, Pg 23. Dicko et al. 2008:"262 children 6 months-10 years in Kambila, Mali were randomized to receive either IPT with SP twice at eight weeks interval or no IPT during the transmission season of 2002 and were followed up for 12 months." Dicko et al. 2008, Pg 1. Dicko et al. 2011:"Sulphadoxine Pyrimethamine (SP) SP + Amodiaquiune AQ or Placebo tablets were given during the peak malaria transmission season, with one month intervals between treatments." Meremikwu et al. 2012, Pg 25. Konaté et al. 2011:"Sulphadoxine Pyrimethamine (SP) SP + Amodiaquiune AQ or Placebo tablets were given in August, September, and October during the peak malaria transmission season, with one month intervals between treatments" Meremikwu et al. 2012, Pg 27. Kweku et al. 2008:"Monthly artesunate plus amodiaquine reduced the incidence of malaria by 69% (95% CI: 63%, 74%) and anaemia by 45% (95% CI: 25%,60%)" Kweku et al. 2008 Sesay et al. 2011:"During the 2008 malaria transmission season, 1,277 children under five years of age resident in villages within the rural Farafenni demographic surveillance system (DSS) in North Bank Region, The Gambia were randomized to receive monthly IPTc with a single dose of sulphadoxine/pyrimethamine (SP) plus three doses of amodiaquine (AQ) or SP and AQ placebos given by village health workers (VHWs) on three occasions during the months of September, October and November, in a double-blind trial" Tagbor et al. 2016:"SMC involves monthly administration of the long-acting antimalarial drugs sulfadoxine-pyrimethamine and amodiaquine (SP-AQ) to all children under five years of age" Tagbor et al. 2016, Pg 224. For more information on Malaria Consortium's program, see our review. 

 23. Cissé et al. 2006:"Intermittent treatment: IPTi with sulfadoxine-pyrimethamine plus artesunate given once monthly" Meremikwu et al. 2012, Pg 23. Dicko et al. 2008:"262 children 6 months-10 years in Kambila, Mali were randomized to receive either IPT with SP twice at eight weeks interval or no IPT during the transmission season of 2002 and were followed up for 12 months." Dicko et al. 2008, Pg 1. Dicko et al. 2011:"Sulphadoxine Pyrimethamine (SP) SP + Amodiaquiune AQ or Placebo tablets were given during the peak malaria transmission season, with one month intervals between treatments." Meremikwu et al. 2012, Pg 25. Konaté et al. 2011:"Sulphadoxine Pyrimethamine (SP) SP + Amodiaquiune AQ or Placebo tablets were given in August, September, and October during the peak malaria transmission season, with one month intervals between treatments" Meremikwu et al. 2012, Pg 27. Kweku et al. 2008:"Intermittent treatment: IPTc with artesunate plus amodiaquine (AS+AQ) monthly or every two months, or sulphadoxine-pyrimethamine (SP) every two months and placebo over a period of six months" Meremikwu et al. 2012, Pg 28. Sesay et al. 2011:"During the 2008 malaria transmission season, 1,277 children under five years of age resident in villages within the rural Farafenni demographic surveillance system (DSS) in North Bank Region, The Gambia were randomized to receive monthly IPTc with a single dose of sulphadoxine/pyrimethamine (SP) plus three doses of amodiaquine (AQ) or SP and AQ placebos given by village health workers (VHWs) on three occasions during the months of September, October and November, in a double-blind trial" Sesay et al. 2011 Tagbor et al. 2016:"SMC involves monthly administration of the long-acting antimalarial drugs sulfadoxine-pyrimethamine and amodiaquine (SP-AQ) to all children under five years of age" Tagbor et al. 2016, Pg 224. For more information on Malaria Consortium's program, see our review. 

 24. "Seven trials (12,589 participants), including one cluster-randomized trial, met the inclusion criteria. All were conducted in West Africa, and six of seven trials were restricted to children aged less than 5 years." Meremikwu et al. 2012, Pg 2. For more information on Malaria Consortium's program, see our review. 

 25. "Seven trials (12,589 participants), including one cluster-randomized trial, met the inclusion criteria. All were conducted in West Africa, and six of seven trials were restricted to children aged less than 5 years." Meremikwu et al. 2012, Pg 2. For more information on Malaria Consortium's program, see our review. 

 26. Cissé et al. 2006:"1136 children aged 2–59 months received either one dose of artesunate plus one dose of sulfadoxine-pyrimethamine or two placebos on three occasions during the malaria transmission season." Cissé et al. 2006, Pg 659. Dicko et al. 2008:"262 children 6 months-10 years in Kambila, Mali were randomized to receive either IPT with SP twice at eight weeks interval or no IPT during the transmission season of 2002 and were followed up for 12 months." Dicko et al. 2008, Pg 1. Dicko et al. 2011:"After screening, eligible children aged 3–59 mo were given a long-lasting insecticide-treated net (LLIN) and randomised to receive three rounds of active drugs or placebos" Dicko et al. 2011, Pg 1. Konaté et al. 2011:"Sulphadoxine Pyrimethamine (SP) SP + Amodiaquiune AQ or Placebo tablets were given in August, September, and October during the peak malaria transmission season, with one month intervals between treatments" Meremikwu et al. 2012, Pg 27. Kweku et al. 2008:"Intermittent treatment: IPTc with artesunate plus amodiaquine (AS+AQ) monthly or every two months, or sulphadoxine-pyrimethamine (SP) every two months and placebo over a period of six months" Meremikwu et al. 2012, Pg 28. Sesay et al. 2011:"During the 2008 malaria transmission season, 1,277 children under five years of age resident in villages within the rural Farafenni demographic surveillance system (DSS) in North Bank Region, The Gambia were randomized to receive monthly IPTc with a single dose of sulphadoxine/pyrimethamine (SP) plus three doses of amodiaquine (AQ) or SP and AQ placebos given by village health workers (VHWs) on three occasions during the months of September, October and November, in a double-blind trial" Sesay et al. 2011 Tagbor et al. 2016:"SMC or placebo was delivered on five occasions during the rainy season" Tagbor et al. 2016, Pg 224. For more information on Malaria Consortium's program, see our review. 

 27. Cissé et al. 2006:"Use of bednets was limited in the study population. In the control group, 128 children (23%) slept under a bednet, compared with 116 (21%) in the active treatment group" Cissé et al. 2006, Pg 662. Dicko et al. 2008:"The bed net coverage in the area at the time of the survey was less than 5%." Dicko et al. 2008, Pg 2. Dicko et al. 2011:"The coverage of ITNs at baseline was 33.4% (312/935) in Siby, 84.7% (563/665) in Djoliba, and 89.8% (2,207/2,458) in Ouelessebougou." Dicko et al. 2011, Pg 3. Konaté et al. 2011:"the proportions of children who used an ITN before the intervention were also similar (less than 0.5%)." Konaté et al. 2011, Pg 5. Kweku et al. 2008: 20.1%-21.7%. Kweku et al. 2008, Figure 1. Sesay et al. 2011:"93% of the study subjects slept under an ITN" Sesay et al. 2011 Tagbor et al. 2016:"Firstly, due to a recent distribution campaign, around 80% of children were regularly sleeping under an insecticide-treated net." Tagbor et al. 2016, Pg 231. 

 28. See GiveWell's analysis of SMC coverage in RCTs

 

 29. See GiveWell's SMC cost-effectiveness analysis (go to most recent version of published cost-effectiveness analysis file, sheet “SMC”, section labelled “Coverage adjustment”).

 

 30. "IPTc probably produces a small reduction in all-cause mortality consistent with the effect on severe malaria, but the trials were underpowered to reach statistical significance (risk ratio 0.66, 95% CI 0.31 to 1.39, moderate quality evidence)." Meremikwu et al. 2012, Pg 2.

 

 31. "IPTc prevents approximately three quarters of all clinical malaria episodes (rate ratio 0.26; 95% CI 0.17 to 0.38; 9321 participants, six trials, high quality evidence), and a similar proportion of severe malaria episodes (rate ratio 0.27, 95% CI 0.10 to 0.76; 5964 participants, two trials, high quality evidence)." Meremikwu et al. 2012, Pg 2.

 

 32. Meremikwu et al. 2012, Pg 13.

 

 33. See GiveWell's SMC cost-effectiveness analysis (go to most recent version of published cost-effectiveness analysis file, sheet “SMC”, row labelled “Ratio of the reduction in malaria mortality to the reduction in malaria incidence”).

 34. “SMC implementation started in September 2008 in Zone 1, treating about 14,000 children aged 3–59 months each month (mid-September, mid-October, and mid-November). About 90,000 children under ten years of age were treated in 2009, and about 160,000 were treated in 2010.” Cisse et al. 2016. For comparison, Meremikwu et al. 2012, the Cochrane review we use to estimate the effect of SMC on treated children, includes 12,859 participants. “Seven trials (12,589 participants), including one cluster-randomized trial, met the inclusion criteria.” Meremikwu et al. 2012 

 35. “SMC was introduced into three districts over three years in central Senegal using a stepped-wedge cluster-randomised design” Cisse et al. 2016 “Fifty-four health posts were randomised. Nine started implementation of SMC in 2008, 18 in 2009, and a further 18 in 2010, with 9 remaining as controls. In the first year of implementation, SMC was delivered to children aged 3–59 months; the age range was then extended for the latter two years of the study to include children up to 10 years of age.” Cisse et al. 2016 See Cisse et al. 2016, Fig 1 Trial profile. 

 36.  “Delivery was organised by health post using community health workers who visited each household once per month during the transmission seasons of 2008, 2009, and 2010 (in mid-September, mid-October, and mid-November) to administer SMC to children aged 3–59 months (in 2008) and to children up to 10 years of age in 2009 and 2010. The dose of SP and the first dose of AQ was administered by the health worker or by the mother/carer under supervision by the health worker; the remaining daily doses of AQ were left with the mother to administer at home over the next two days.” Cisse et al. 2016 “In 2008, co-blister packs of Dualkin (Pfizer) (SP [500/25 mg tablets] and AQ [200 mg tablets]) were used. These tablets had to be broken and crushed to make half doses for infants. In 2009, 200-mg AQ tablets (Chongqing Qinyang Pharmaceutical) and 500/25-mg SP (Shijizhuang Ouyi Pharmaceutical) tablets were used, and, in 2010, sweetened dispersible tablets of SP (500/25 mg) and of AQ (153 mg) (Kinapharma, Ghana) were given.” Cisse et al. 2016 

 37. “The incidence rate ratio comparing SMC and control areas, adjusted for effects of calendar time, for RDT-confirmed malaria during the transmission season was 0.43 In children under five years of age and 0.39 for children five to nine years of age (Table 2), giving reductions of 57% (95% CI 48%–63%) in the younger group and 61% (95% CI 55%–67%) in the older group, an overall effectiveness of 60% (95% CI 54%–64%, p < 0.001).” Cisse et al. 2016 “Effectiveness of SMC was estimated by fitting a Poisson regression model to the data on the number of deaths and the number of RDT-confirmed malaria cases in each health post occurring in the period starting from the date of the first round of SMC and ending one month after the last round of SMC each year. The number of person-months at risk obtained from the DSS was included as an offset, and a gamma-distributed random effect was used to allow for correlation within clusters. Covariates included in the model were age group, calendar year, and indicator variables for the effect of SMC in children (under five years in 2008 and under ten years in 2009 and 2010) and for the indirect effect of SMC in older age groups. Interaction terms were included to compare effects in the two age groups, and combined effects were estimated where there was no evidence of interaction. The indicator variable representing SMC direct effects was set to 1 if that age group received SMC in that cluster in that year and set to 0 otherwise. The indicator variable for indirect effects was set to 1 for all non-SMC age groups if SMC was implemented in children in that cluster and set to zero otherwise. Thus the direct effect that was estimated represents the sum of direct and indirect effects, and the indirect effect estimated represents the indirect effect only. Rebound effects were assessed by comparing the incidence of malaria during 2011 and 2012, after intervention had stopped, in children living in areas where SMC had been provided for up to three years, with children of the same age in areas that did not have SMC.” Cisse et al. 2016 

 38. “Among age groups too old to receive SMC, incidence was reduced by 26% (95% CI 18%–33%, p < 0.001) (RDT-confirmed), or 29% (95% CI 21%–35%, p < 0.001) (confirmed and unconfirmed cases) in areas where SMC was delivered to children compared to control areas” Cisse et al. 2016

 

 39. “During the transmission seasons, the mortality rate among children aged 3–59 months in SMC areas was 4.6 per 1,000 child-years at risk (197 deaths) and 4.5/1,000 in control areas (159 deaths). Among children aged 5–9 years, the mortality rates were 1.30/1,000 in SMC areas (45 deaths) and 1.2/1,000 in control areas (43 deaths). Mortality in infants under three months of age was 19/1,000. The mortality rate ratio SMC: control given by a random effect model that included cluster, time, and age effects was 0.89 (95% CI 0.65–1.2, p = 0.442) for the 3–59 months age group and 0.97 (95% CI 0.61–1.6, p = 0.916) for the 5- to 9-year-olds. The pooled estimate for both age groups combined was 0.90 (95% CI 0.68–1.2 p = 0.496) (S3 Fig, S2 Table).” Cisse et al. 2016

 

 40. “Sample size calculations to detect an effect on all-causes mortality were done for a range of scenarios, with the assumption that the mortality rate (all causes) would be 20 per 1,000 in children 3–59 months of age (based on estimates from the Niakhar DSS) and assuming 30% of deaths were due to malaria (determined from verbal autopsies in Niakhar and the proportion of deaths in hospital attributed to malaria). We also assumed a coefficient of variation between health posts of 0.25 to 0.3 and SMC effectiveness against malaria to be 70%. Calculations using the method of Hemming and Girling [13] for the stepped-wedge design, assuming k = 0.3 and a median population of children aged 3–59 months of 1,400 per cluster, gave a power of about 17%, 52%, and 99% for reductions of 5%, 10%, and 20%, respectively, if the mortality rate was 10/1,000 and 11%, 32%, and 86% power for the same reductions if the rate was 20/1,000.” Cisse et al. 2016

 

 41. “During the transmission seasons, the mortality rate among children aged 3–59 months in SMC areas was 4.6 per 1,000 child-years at risk (197 deaths) and 4.5/1,000 in control areas (159 deaths). Among children aged 5–9 years, the mortality rates were 1.30/1,000 in SMC areas (45 deaths) and 1.2/1,000 in control areas (43 deaths).” Cisse et al. 2016

 

 42. Calculations behind this adjustment are in the spreadsheet: GiveWell - SMC indirect effects calculations.

 

 43. Our understanding is that treating a greater proportion of the infected population is likely to have a more than proportional effect on the indirect effects on the untreated population due to disease transmission dynamics. We have not found relevant published academic literature on this topic, but assume that treating 5-10 year olds results in a ~3x increase in indirect effects based on seeing the early unpublished results of a modelling study shared with us by Professor Matthew Cairns, a researcher at London School of Hygiene and Tropical Medicine. Professor Matthew Cairns, email to GiveWell, September 19, 2018 Professor Cairns told us the model used the Imperial College malaria model, which we have not vetted in detail, to simulate 4 monthly cycles of SMC targeted at different age ranges with 80% coverage, fitting protective efficacy over time with Zongo et al. 2015, an RCT of SMC using a different drug regimen from the one used in the typical Malaria Consortium trials. “The WHO recommends that children living in areas of highly seasonal malaria transmission in the Sahel subregion should receive seasonal malaria chemoprevention (SMC) with sulfadoxine-pyrimethamine plus amodiaquine (SPAQ). We evaluated the use of dihydroartemisinin-piperaquine (DHAPQ) as an alternative drug that could be used if SPAQ starts to lose efficacy.” Zongo et al. 2015, Abstract. We have not investigated whether it is likely that the indirect effects of DHAPQ differ substantially from SPAQ.  The model suggests treating 5-10 year olds would result in ~3x the indirect effects of treating 3 month to 5 year olds in the countries in which Malaria Consortium works. Based on the heuristic that ~doubling the proportion of the population covered increases the indirect effects by ~3x, we estimate that the indirect effects scale according to raising the proportion of the population covered to the power of log2 (3). Based on Malaria Consortium’s monitoring data, we estimate that Malaria Consortium treats ~63% of the proportion of the population treated in Cisse et al. 2016 (see GiveWell - SMC indirect effects calculations). We therefore expect the indirect effects to be ~63%^(log2(3))=48% as large in Malaria Consortium’s typical program as in Cisse et al. 2016 due to the lower proportion of the population covered. Calculations behind this adjustment are in the spreadsheet: GiveWell - SMC indirect effects calculations.

 

 44. We have seen early unpublished results of a modelling study shared with us by Professor Matthew Cairns, a researcher at London School of Hygiene and Tropical Medicine, which suggests that indirect effects would be ~65% lower in the typical area covered by Malaria Consortium than in Cisse et al. 2016 due to higher transmission rates. Professor Matthew Cairns, email to GiveWell, September 19, 2018 Professor Cairns told us the model used the Imperial College malaria model to simulate 4 monthly cycles of SMC targeted at different age ranges with 80% coverage, fitting protective efficacy over time with Zongo et al. 2015, an RCT of SMC using a different drug regimen from the one used in the typical Malaria Consortium trials. Professor Matthew Cairns, email to GiveWell, September 19, 2018 “The WHO recommends that children living in areas of highly seasonal malaria transmission in the Sahel subregion should receive seasonal malaria chemoprevention (SMC) with sulfadoxine-pyrimethamine plus amodiaquine (SPAQ). We evaluated the use of dihydroartemisinin-piperaquine (DHAPQ) as an alternative drug that could be used if SPAQ starts to lose efficacy.” Zongo et al. 2015, Abstract. We have not investigated whether it is likely that the indirect effects of DHAPQ differ substantially from SPAQ. We have not vetted this model in detail, but checked estimates from the Institute for Health Metrics and Evaluation, which suggest malaria prevalence is substantially lower in Senegal than most countries in which Malaria Consortium works (IHME - malaria prevalence estimates). We therefore use the results of this modelling study to inform our best guess of the lower indirect effects in the typical Malaria Consortium program. See Row 16, Sheet "Relative effect size," in GiveWell - SMC indirect effects calculations. 

 45. “Recently, the median time for resistance to a given drug to develop has been roughly 10 to 15 years; for instance, resistance to sulfadoxine-pyrimethamine (SP) resistance took roughly 10 years to emerge in Southeast Asia (where SP was being used as a mainline treatment for malaria).” GiveWell's non-verbatim summary of a conversation with Professor Sir Brian Greenwood, January 4 2017  “Professor Greenwood’s best guess is that SP/AQ will still be working, at least partially, in 5-10 years’ time, but this is quite uncertain (it is possible, though unlikely, that an unanticipated type of resistance mutation could appear at any time).” GiveWell's non-verbatim summary of a conversation with Professor Sir Brian Greenwood, January 4 2017 

 46. “SP has been used alone for intermittent preventive treatment in pregnancy (IPTp) for roughly 20 years. This is likely to have contributed to resistance to SP developing in Tanzania and East Africa, and SP is no longer very effective in those places for IPTp. However, it is still effective in much of the rest of Africa. A mutation associated with a particularly high level of SP resistance that appeared in Southeast Asia (the DHFR 164 mutation) also appeared in Uganda but has not spread in Africa.” GiveWell's non-verbatim summary of a conversation with Professor Sir Brian Greenwood, January 4 2017

 

 47. “AQ has relatively little history of resistance, compared to SP. Some resistance has been reported, but overall efficacy has remained high despite extensive use in West Africa for 40 years.” GiveWell's non-verbatim summary of a conversation with Professor Sir Brian Greenwood, January 4 2017

 

 48. “While Professor Greenwood thinks it is likely that SP/AQ will maintain its effectiveness for up to 10 years, if resistance to SP/AQ does develop, dihydroartemisinin-piperaquine (DHAPQ) could be used to replace its role in prevention. However, there is some risk that broad use of an artemisinin-based drug like DHAPQ for prevention could encourage artemisinin resistance, e.g., by encouraging an artemisinin-resistant parasite that already exists in Cambodia to emerge in Africa. While Professor Greenwood would be concerned about using artemisinin in prevention, he would not rule it out as an option, and other experts might disagree about the level of risk.” GiveWell's non-verbatim summary of a conversation with Professor Sir Brian Greenwood, January 4 2017 “The WHO recommends that children living in areas of highly seasonal malaria transmission in the Sahel subregion should receive seasonal malaria chemoprevention (SMC) with sulfadoxine-pyrimethamine plus amodiaquine (SPAQ). We evaluated the use of dihydroartemisinin-piperaquine (DHAPQ) as an alternative drug that could be used if SPAQ starts to lose efficacy. A total of 1,499 children 3 to 59 months old were randomized to receive SMC with SPAQ or DHAPQ over 3 months. The primary outcome measure was the risk of clinical malaria (fever or a history of fever with a parasite density of at least 3,000/μl). A cohort of 250 children outside the trial was followed up as a control group. Molecular markers of drug resistance were assessed. The risk of a malaria attack was 0.19 in the DHAPQ group and 0.15 in the SPAQ group, an odds ratio of 1.33 (95% confidence interval [CI], 1.02 to 1.72). Efficacy of SMC compared to the control group was 77% (67% to 84%) for DHAPQ and 83% (74% to 89%) for SPAQ. pfdhfr and pfdhps mutations associated with antifolate resistance were more prevalent in parasites from children who received SPAQ than in children who received DHAPQ. Both regimens were highly efficacious and well tolerated. DHAPQ is a potential alternative drug for SMC. (This trial is registered at ClinicalTrials.gov under registration no. NCT00941785.).” Zongo et al. 2015, Abstract. 

 49. ”Post-intervention (rebound) events: Data on post-intervention assessment of trial outcomes were included in meta-analysis if they were adequate; only a few trials provided adequate post-intervention data for meta-analysis. Three trials provided adequate information on incidence of clinical malaria post-intervention (Cissé 2006; Dicko et al. 2008; Kweku 2008).” Meremikwu et al. 2012, Pg 9.  “Three studies continued to monitor children for a full transmission season after IPTc was stopped. There was no observed rebound increase in malaria in children who had received the intervention compared to controls (2299 participants, three trials; Analysis 1.1).” Meremikwu et al. 2012, Pg 12. 

 50. “Since delivery of drugs for up to 5 years will be necessary to achieve sustained protection in young children, assessment of rebound morbidity after several years of intervention will be important. Such assessment will require a trial that lasts for several years, and some form of phased intervention study will probably be needed.” Cissé et al. 2006, Pg 666.

 51. “Two trials distributed and promoted the use of ITNs to both the intervention and control groups (Dicko 2011 and Konate 2011).” Meremikwu et al. 2012, Pg 13.

 

 52. “Two trials distributed and promoted the use of ITNs to both the intervention and control groups (Dicko 2011 and Konate 2011). Despite ITN use being reported as >90% in both treatment arms, IPTc had high protective efficacy against both clinical malaria (rate ratio 0.22, 95% CI 0.13 to 0.38; 5964 participants, two trials; Analysis 2.1) and severe malaria (rate ratio 0.27, 95% CI 0.10 to 0.76; 5964 participants, two trials; Analysis 1.2).” Meremikwu et al. 2012, Pg 13.

 

 53. See GiveWell's SMC cost-effectiveness analysis (go to most recent version of published cost-effectiveness analysis file, “SMC” and "Results" sheets).

 

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