The full study methodology as well as the trial protocol were published elsewhere (22). In brief, a double-blind, randomized, controlled, single-center study was conducted in Banfora, a place with intense and markedly seasonal malaria transmission where P. falciparum is responsible for more than 90% of all clinical malaria cases (25, 26). Coinciding with the rainy months of May-November, 60% of clinical cases are reported during the months of June-September (26). The age-de-escalating, phase Ib clinical trial with a single-blind follow-up phase enrolled 108 healthy, malaria-exposed African children. Children in both Cohort 1 (aged 25–60 months, n = 54) and Cohort 2 (aged 12–24 months, n = 54) were randomized into 3 treatment arms in a 1:1:1 ratio receiving: (a) 3 full doses of BK-SE36 by the subcutaneous route (SC), (b) 3 full doses of BK-SE36 by the intramuscular route (IM), and (c) 2 doses of the licensed Pneumococcal polysaccharide conjugate decavalent Synflorix^® vaccine, alternate with 1 dose of physiological saline by the IM route (control arm). The inclusion of a third dose at Week 26 (W26; Day 182) was intended to increase the immune response and evaluate the effect of a booster dose. The first and second vaccine doses were given during the rainy season (peak of malaria transmission); the third dose during the dry (low transmission) season. In Cohort 1, the primary doses (28 days apart) were given in July-Aug 2015 and the booster dose (6 months from the first dose) given January 2016. For Cohort 2, primary vaccinations were given Oct-Nov 2015, and the booster on April 2016.

Anti-SE36 IgG antibody titers were measured by ELISA before vaccination (D0, D182), 4 weeks after each vaccination (D28, D56, D210), and at D365 and D477. ELISA was outsourced to a GLP certified testing facility (CMIC Pharma Science Co., Ltd., Japan) and used a standardized methodology. Results were expressed in titers calculated using an equilibrium line assay (10, 21).

Geometric mean titers (GMTs) were calculated at each time point. IgG1 and IgG3 subclasses were determined (27) for those with detectable anti-SE36 antibody titers 4 weeks after the second (W8/D56) and third (W30/D210) vaccinations.

Prior to each vaccination, capillary blood was also collected to prepare malaria smears. The presence of parasites was assessed by 100 x bright field microscopic examination, assuming 8,000 leukocytes/µl of blood. The count was made by species (P. falciparum, P. malariae or P. ovale), and counts for P. falciparum were made for both sexual and asexual parasites. The parasite presence and density were determined independently by two readers for the same slide; if readings were judged to be discordant, a third independent read was organized. The parasite density (parasites/μL) was calculated as the geometric mean of the two positive readings (two geometrically closest readings in the case of three positive reads). Microscopist competency was evaluated through two external quality control (EQC) programs. The first EQC was carried out by the College of American Pathology; proficiency testing with a set of 5 slides provided to each microscopist for reading thrice a year. Only a performance graded above 80% was considered satisfactory for the laboratory. The second EQC was performed by WHO (National Institute for Communicable Diseases) and involved the reading of a set of 20 slides every quarter by each microscopist. Only those with a score of at least 80%, graded as ‘competent’, were tasked in the reading of trial participants’ slides.

Since the primary analysis showed no difference in terms of immune responses between the intramuscular and subcutaneous routes (22), the two arms were pooled for this study. The control arm is not of interest and was excluded from the current secondary analysis.

There were three categories depending on vaccination days and available blood smears/parasitemia data on those days. The first category (subgroup 1) includes subjects who received Dose 1 and 2 (termed “primary immunization”) and had a blood smear taken at these two occasions with results available. The subgroup considered subjects who received 2 doses since the interest is to see the effect of infection on the full vaccination status; however, the difference in GMTs between infected and non-infected subjects after one dose is provided in Supplementary Table S1 . The second category (subgroup 2) is composed of subjects who received the booster (Dose 3) vaccination and had results of a blood smear taken before the booster dose. The third category (subgroup 3) includes subjects that received both primary and booster vaccinations and had results available for blood smear obtained at each of the three vaccination days.

Antibody titers and P. falciparum count are presented in terms of the geometric mean with 95% confidence interval. Because SE36 antibody titers are not normally distributed (with outliers as well as limits of detection (e.g., undetectable titers were assigned a value of “8” for statistical analyses), we use the Wilcoxon rank sum test. All the comparisons are made between infected and uninfected groups. A p-value of 0.05 was the level of statistical significance.

Statistical analyses were performed using Stata ver. 14 (StataCorp, College Station, TX, USA, www.stata.com) and GraphPad (Prism ver. 9.4.0).

The trial was conducted according to the principles of the Declaration of Helsinki and the International Conference on Harmonization (ICH) Good Clinical Practice (GCP) guidelines. The clinical trial protocol and associated documents were reviewed and approved in Burkina Faso by CNRFP institutional bioethics committee (Ref: n°2014/071/MS/SG/CNRFP/CIB, N°2016/000008/MS/SG/CNRFP/CIB), the Ministry of Health Ethical Committee for Biomedical Research (Ref: 2014-12-144) and the National Regulatory Authority (Approval for the clinical trial: (N°2015_658/MS/CAB). The trial package was also approved by the Scientific Committee/Institutional Review Committee of the Research Institute for Microbial Diseases (Ref: 26-6), Osaka University (Ref: 574) in Japan; and the London School of Hygiene and Tropical Medicine Research Ethics Committee (Ref: 9175) in United Kingdom.

The vaccination of Cohort 1 started on July 4, 2015 (Dose 1), and the last vaccination (Dose 3) was completed by January 11, 2016. Vaccination of Cohort 2 began on October 12, 2015 (Dose 1) and was completed by April 18, 2016 (Dose 3). In total 72 participants received 2 primary doses of BK-SE36 (22), however 1 subject in Cohort 1 had a missing blood smear during Dose 2 vaccination day and thus only 71 subjects were included in subgroup 1 analyses. For subgroup 2, all subjects who have received Dose 3 and had a blood smear before vaccination were included in the analyses (n=68). For subgroup 3, all subjects with primary and booster vaccination and a blood smear at these vaccination days were included (n=68).

The median age was 25.4 (IQR 28.2) months, and 38.9% of subjects were male.

The proportion of individuals carrying P. falciparum infection at the time of primary immunizations is shown in Figure 1 . Infection is defined as any asexual parasitemia > 0 by microscopy. In this study, the vaccine treatment arms (SC and IM) were pooled for analysis due to the small sample size, the randomized nature of the trial, and the results indicating no difference in the vaccine induced immune response between the two routes. Therefore, it is unlikely that there are differences in malaria infection during vaccinations days and vaccine induced antibody response in the SC and IM arms. During vaccinations days there were no recorded P. malariae, P. vivax and P. ovale infections.

For subgroup 1, 64.8% (46/71) participants were free of infection at both Dose 1 and 2. At either dose, 35.2% (25/71) were harboring malaria parasites. The mean age was 39.6 ( ± 14.9) and 27.9 ( ± 14.6) months in infected and uninfected children, respectively. The difference in the proportion of children infected during vaccination days was statistically significant (p = 0.002).

In subgroup 2, no P. falciparum infection was found for 83.8% (57/68) of the vaccinees at the time of the booster vaccination. The mean age was 45.2 ( ± 14.6) and 29.5 ( ± 14.9) months in infected and uninfected children, respectively. The difference was statistically significant (p = 0.001).

In total, 58.8% (40/68) receive their primary and booster doses in the absence of any P. falciparum infection (subgroup 3). The mean age was 39.7 ( ± 15.8) and 26.7 ( ± 13.8) months in infected and uninfected children, respectively. Again, the difference was statistically significant (p < 0.001).

The geometric mean of P. falciparum parasites density was 1077.6 trophozoites/µL (95% CI, 451.5-2571.9), 1811.4 trophozoites/µL (95% CI, 4716.9-4576.8) and 2359.9 trophozoites/µL (95% CI, 649.3-8577.6) respectively at Dose 1, 2 and 3. Individual P. falciparum count is provided in Supplementary Figure S1 .

Immune responses to BK-SE36 vaccination in infected and uninfected individuals are shown in Figure 2 . At baseline (before Dose 1, Figure 2A ), the GMT of SE36 antibody titers was 15.1 (95% CI, 11.3-20.2) in uninfected individuals compared to 17.3 (95% CI, 8.7-34.4) in infected participants (p = 0.877). One-month post-primary vaccinations (after Dose 2), the geometric mean of SE36 antibodies was 263.2 (95% CI, 178.9-387.1) in uninfected individuals compared to 77.1 (95% CI, 47.3-125.7) in infected participants. The difference was statistically significant (p < 0.001). In terms of fold change for each subject, there was a 2.2 (95% CI, 0.1.3-3.5) and 1.6 (95% CI, 1.0-2.6) fold change respectively in uninfected and infected participants from baseline to one-month post Dose 2. The difference, however, was not statistically significant (p = 0.361, Figure 2C ).

Before Dose 3 or booster dose (22 weeks post Dose 2), the GMT was 34.6 (95% CI, 24.3-49.3) in uninfected individuals compared to 25.4 (95% CI, 15.4-41.9) in infected participants. The difference was not statistically significant (p = 0.212) ( Figure 2B ). One month post Dose 3, participants uninfected at the time of booster vaccination had significantly higher GMTs compared to those who were infected on vaccination day (424.1 (95% CI, 301.9-595.8) vs. 92.8 (95% CI, 34.9-246.6); p = 0.002). There was a 14.3 (95% CI, 9.7-21.1) and 2.4 (95% CI, 1.3-4.4) fold change respectively in uninfected and infected participants between one-month post Dose 2 and Dose 3. The difference was statistically significant (p < 0.001, Figure 2D ).

Study participants who did not have any microscopically detectable P. falciparum infection during primary and booster vaccinations had the highest GMT at one-month post Dose 3 (602.2; 95% CI, 421.5-860.3) compared to those who were found with P. falciparum infection at some point in time during vaccination days (139.2; 95% CI, 80.7-240.3). The difference between uninfected and infected subjects was statistically significant (p < 0.001). This difference was maintained towards the study end with GMTs of 101.0 (95% CI, 62.3-163.8) vs 27.21 (95% CI, 15.5-44.5) (p = 0.006) at visit 32 (D365); and 96.7 (95% CI, 59.4-157.3) vs. 25.6 (95% CI, 15.5-42.4), (p = 0.001) at visit 36 (D477) (uninfected vs infected subjects). A subgroup analysis by cohort is provided in Supplementary Table S2 .

Anti-SE36 IgG antibody subclasses levels in uninfected and infected children are presented in Supplementary Figure S2 . The IgG1 concentrations measured 4 weeks after Doses 2 and 3 were significantly higher in uninfected children as compared to those who had an infection during vaccination days. For IgG3, a statistically significant difference in titers between both groups was only observed post-Dose 2.