A multiantigen assay for the simultaneous detection of PfHRP2, pAldo, and pLDH was developed and validated with purified recombinant antigens and on a panel of 239 known monoinfections in anonymized samples from returning US resident travelers with each of the 4 species of human malaria, as previously confirmed by PCR. The signal intensity cutoff for antigen positivity by the bead assay was determined using a panel of 73 malaria-negative US blood donors without travel to malaria endemic countries. The multiantigen assay was then used to screen 1267 dried blood spot samples previously collected during a 2016 health facility survey in Huambo and Uíge Provinces in Angola [24]. A subset of samples was chosen based on multiantigen profile and further assayed by quantitative reverse transcription PCR (qRT-PCR) for ultrasensitive detection of parasite nucleic acid to characterize malaria infection status. Separately, samples with an antigen profile showing no detected PfHRP2 but positive for pAldo and/or pLDH had another blood spot eluted and assay repeated to confirm antigen detection results. DNA was then extracted from these target samples and assayed by molecular methods for the presence of Plasmodium DNA and to determine species. Of these, samples that were confirmed to harbor P. falciparum infections were then analyzed using the standard confirmatory assay for Pfhrp2/3 gene deletions. See Supplementary Methods 1–4 for detailed sample collection and analysis methods.

All persons involved in the study provided informed consent before blood sample collection. For the samples from both the United States and Angola, testing was approved as research not involving identifiable human subjects by the Office of the Associate Director for Science in the Center for Global Health at the Centers for Disease Control and Prevention. For the Angola samples, collection and antigen detection was approved as part of the health facility survey by the Angolan Ministry of Health.

In order to determine a signal intensity of the bead assay that would indicate a true positive signal for detecting a given antigen, 73 blood samples of US residents with no reported history of travel to malaria endemic countries (living in a malaria nonendemic setting) were tested at a 1:10 dilution. For each of the 3 antigens assayed in this sample set, the median fluorescence intensity minus background (MFI-bg) lognormal mean plus 3 standard deviations of this population was used as the positivity cutoff value to indicate which MFI-bg signal represented a true positive value when testing human blood samples [9], and these signals and estimated antigen detection limits of the assay are shown in Supplementary Table 1.

For the Angola survey, characteristics for each patient whose sample was profile positive for at least 1 antigen were compared to characteristics of patients testing negative for all 3 antigens. The proportion of patients with recorded fever or reported history of fever in the last 24 hours was compared using a Χ² test. Differences in mean patient age were assessed using a 2-sample Student t test. The proportion of Pfhrp2/3-deleted parasites was calculated as the number of samples with genomically confirmed Pfhrp2/3 deletions divided by the total number of samples positive for any Plasmodium antigen.

The relationship between patient age and antigen concentration was modeled through locally weighted scatterplot smoothing (LOESS) regression in SAS v9.4 (Cary, NC).

The MFI-bg assay signal titrated below 1000 pg/mL for all 3 antigens regardless of differences in the Plasmodium species isoforms of the recombinant proteins (Figure 1). Greater absolute detection capacity was shown when assaying for the pAldo and PfHRP2 antigens, with appreciable MFI-bg signals below 100 pg/mL and 10 pg/mL, respectively. For each recombinant antigen, signal cutoff values and limits of antigen detection appropriate for reporting (as described in Methods) are displayed in Supplementary Table 1.

The assay was also found to reliably detect antigen from samples from known monospecies malaria infection. For all 4 major species of human malaria, the bead assay was able to detect 1 or more expressed antigens in 98.7% (236/239) of patient samples (Figure 2A and Supplementary Figure 1). Detection of antigens in P. vivax infection appeared to be most reliable, with all 54 P. vivax-infected patient samples testing positive for either pAldo or pLDH, and 81.5% (44/54) testing positive for both. All patient samples with P. falciparum infection were positive for the PfHRP2 antigen, with most P. falciparum-infected patient samples giving a high PfHRP2 assay signal (Figure 2A). For all 3 antigens, positive correlation was observed between antigen concentration and parasite density at the time of patient sampling with R² correlation values ranging from 0.10 to 0.40 (Figure 2B and Supplementary Table 2). Using these regression estimates, and the detection capacity of the bead assay (Supplementary Table 1), it would be predicted that assaying for Plasmodium antigens would allow identification of active infections of less than 1 parasite/μL (p/μL) blood by using detection of any of the 3 antigens. The only exception to this finding was pLDH expression in P. falciparum infections, which modeled a substantially lower intercept. For all species, the absolute quantity of pLDH detected in an individual sample was on average greater than pAldo by a factor of 2- to 10-fold, with P. vivax infections showing the highest ratio and P. falciparum the lowest (Figure 2C and Supplementary Table 2).

Of 1267 samples from the Angola health facility survey, 302 (24%) were found to be positive for pAldo, 171 (13%) positive for pLDH, and 459 (36%) positive for PfHRP2, with a wide range of antigen levels (Supplementary Figure 2A). For antigen-positive samples, an inverse relationship was observed between antigen concentration and increasing patient age (Supplementary Figure 3). In the same manner as the confirmed monospecies infections in Figure 2, a direct correlation was seen between antigen concentration and parasite density in the Angola samples (Supplementary Figure 4), with the performance for detection of each antigen compared with qRT-PCR as the gold standard (Supplementary Table 3). A total of 801 (63%) samples were negative for all 3 antigens (Table 1). Of the 466 samples positive for at least 1 antigen, 167 (36%) of these were positive for all 3 antigens. A similar number (163, 35%) were positive only for PfHRP2. The next most frequent antigen profile was PfHRP2+/pAldo+/pLDH−, observed in 129 (28%) antigen-positive patients. No samples with the PfHRP2+/ pAldo−/pLDH+ profile were observed. Different combinations of the multiantigen profile were predictive of P. falciparum nucleic acid carriage and mean parasite density as estimated by qRT-PCR (Figure 3). For samples with no antigen detected, 16% were positive for P. falciparum by qRT-PCR with a median parasite density amongst nucleic acid-positive samples of 0.41 p/μL (Table 1). Of samples positive only for the PfHRP2 antigen, 43% were qRT-PCR positive with a median parasite density of 2.0 p/μL. Amongst samples with the PfHRP2+/pAldo+/pLDH− profile, 96% were qRTPCR positive, and the median parasite density in positive samples was 208 p/μL. All samples positive for all 3 antigens were qRTPCR positive, with a median parasite density of 3104 p/μL. The prevalence of fever increased with cumulative antigen positivity, with 55%, 62%, 80%, and 88% of persons reporting fever for the 4 categories above, respectively (Table 1). Both PfHRP2+/pAldo+/pLDH+ and PfHRP2+/pAldo+/pLDH− patients were younger than patients negative for all 3 antigens, with mean ages of 9.4 and 17.3 years, respectively, compared to 23.8 years for the all-antigen–negative patients (P value < .01). The mean age of PfHRP2+/ pAldo−/pLDH− patients (23.8 years) was not statistically different from the mean age of patients negative for all 3 antigens. The mean PfHRP2 concentration of individuals became reduced as persons were positive for fewer antigens (Supplementary Figure 2B).

Of 466 Angolan samples positive for any antigens, 7 (1.5%) were negative for PfHRP2, but positive for at least 1 of the other antigens: 3 PfHRP2−/pAldo+/pLDH−, 3 PfHRP2−/pAldo+/ pLDH+, and 1 PfHRP2−/pAldo−/pLDH+ (Figure 4 and Figure 5). There was 1 additional sample with an exceptionally low concentration of PfHRP2 (541 pg/mL) despite considerable concentrations of pAldo (140 609 pg/mL) and pLDH (195 205 pg/mL), and was clearly identified on scatterplots of antigen concentrations (Figure 4B). All 8 samples were pronounced outliers that did not show the characteristic relationship between PfHRP2 concentration and pAldo and pLDH concentration (Figure 4B). Photoinduced electron transfer polymerase chain reaction (PET-PCR) assays confirmed 3 of these samples to be monoinfections with Plasmodium ovale, all 3 from Uíge Province (Table 2). The remaining 5 (1.1%) antigen-positive samples were confirmed to be P. falciparum monoinfections and were assayed for Pfhrp2/3 deletions. One sample from Huambo was confirmed to be an infection with a P. falciparum showing a double Pfhrp2 and Pfhrp3 deletion (Table 2) One sample from Uíge was found to be an infection with a P. falciparum parasite with a deletion of the Pfhrp2 gene, but positive for the Pfhrp3 gene. In 2 samples from Uíge, the Pfhrp2 and Pfhrp3 gene targets were successfully amplified, despite the absence of detectable PfHRP2 antigen. Finally, the Pfmsp1 and Pfmsp2 single-copy genes could not be amplified in 1 sample from Uíge, and thus cannot be reported on for verification of Pfhrp2 and Pfhrp3 genotype [23]. The workflow algorithm and summary of results for the non-falciparum and Pfhrp2/3 screening are summarized in Figure 5 and Table 2.