Introduction
Following considerable successes in the control of malaria in the last two decades, progress plateaued or stalled in many settings in Africa [
1]. Ethiopia runs a successful malaria control programme [
2] that makes it one of the four countries (together with India, Rwanda, and Pakistan) that continues to maintain the declining trend in malaria burden [
3]. As a result, the country is on track for a 40% reduction in incidence (together with Rwanda, Zambia, and Zimbabwe) and malaria mortality rates (together with Zambia) by 2020 [
1]. To guide elimination efforts that currently targets 239 selected districts, the National Malaria Control Programme (NMCP) of Ethiopia stratified the country into four strata using district level annual parasite index (API) data from 2017 [
4] as malaria-free (API, 0), low (API, 0–5), moderate (API, 5–100), and high (API, ≥ 100) [
4]. Despite its value, the adopted stratification lacks granularity and is not able to capture relevant spatial and temporal heterogeneities in low endemic settings [
5,
6]. The unique epidemiology of malaria transmission in Ethiopia; the presence of strictly seasonal transmission in some settings and perennial transmission elsewhere, as well as different levels of co-endemicity of
Plasmodium falciparum and
Plasmodium vivax [
2], calls for the use of tailored approaches to characterize the epidemiology of malaria.
District level stratification that relies on malaria incidence data has limitations in settings where case numbers are extremely low. Incidence data are also sensitive to changes in care seeking behavior, rates of testing of suspected cases, and reporting completeness [
7]. Screening approaches to determine the prevalence of (often asymptomatic) infections that are present in communities have great potential to define transmission intensity [
8]. However, parasite prevalence estimates are greatly affected by parasite density distributions in communities that determine the detectability of infections by different diagnostics. Malaria elimination efforts may benefit from targeting all infections present in communities, irrespective of clinical presentation [
9‐
11]. There is a growing body of evidence on the public health importance of asymptomatic malaria infections and their contribution to onwards malaria transmission in high [
12,
13] and low transmission settings [
13,
14]. Importantly, most asymptomatic infections detected in community surveys are of low parasite density and the proportion of all infections that are submicroscopic varies between settings [
15]. Previous studies in Ethiopia detected a significant burden of asymptomatic
P. falciparum and
P. vivax infections [
16‐
19]. These studies used different diagnostic techniques and sampling designs, making it difficult to compare parasite prevalence estimates or diagnostic performance indicators across settings. The aim of the present study was to understand the epidemiology of asymptomatic
Plasmodium infections in different settings in Ethiopia and their detectability by microscopy, rapid diagnostics test (RDT) and molecular methods.
Study population and sample collection
Samples were collected in community and school-based cross-sectional surveys from 2016 to 2020. Specifically, community-based surveys were conducted at Abobo, Lare, Mao-komo, Menge, and Gomma districts in 2016, Babile district in 2018, and Arba Minch Zuria district in 2020. School based surveys were conducted at North Achefer, Bahir Dar Zuria, and Jawi districts in 2017. For the school-based surveys, students were randomly selected from elementary school students stratified by age as described before [
21] following protocols developed by Brooker and colleagues [
22].
Prior to recruitment of participants for community surveys, sensitization was undertaken by teams that involve study team members, village-based health extension workers, malaria focal person of the district, local administrators, and elderly. The study purpose, procedure, risk, and benefit were explained in local language. After this first step, volunteer community members were invited to join the study upon obtaining informed written consent and enrolled in the study on first come, first served basis.
Finger prick blood samples (~ 300 µL) collected from all participants were used to diagnose malaria using RDT (First Response® malaria Antigen pLDH/HRP2 P.f and Pan Combo Card Test, Premier Medical Corporation Ltd, Dist. Valsad, India) or thin and thick blood films, and to prepare dried blood spots (DBS) on 3MM Whatman filter papers (Whatman, Maidstone, UK). Malaria was diagnosed using RDT at Abobo, Lare, Mao-Komo, Menge, and Gomma districts whilst microscopy was used at the school surveys, Arba Minch Zuria and Babile districts. Detailed clinical and socio-demographic data were captured using a pretested semi-structured interview-based questionnaire. Axillary body temperature was measured for all participants. If a participant was found febrile (axillary temperature ≥ 37.5 °C) or reports history of fever in the past 48 h, malaria status was checked using RDT and treated immediately when found positive following the national treatment guideline [
23]. DBS were air dried, protected from direct sunlight, and enclosed in zip locked plastic bags individually with self-indicating silica gel (Loba Chemie, Mumbai, India). Samples were transported at ambient temperature and stored at − 20 °C until further use. Giemsa-stained thick and thin smears were read independently by two experienced malaria microscopists. A third expert microscopist was consulted in case of discordant results. Thick smear slides were declared negative if no parasites were detected after observing 100 fields under oil immersion (100× magnification).
Species specific detection of Plasmodium parasites by 18S rRNA based nested polymerase chain reaction
Genomic DNA was extracted from 6 mm diameter DBS punches using Chelex-Saponin extraction method [
24]. In brief, DNA was eluted after an overnight lysis in 0.5% saponin (SIGMA)/PBS (SIGMA) buffer and washing step followed by boiling at 97 ˚C in 150 µL of 6% Chelex (Bio Rad) in DNase/RNase free water (SIGMA). From the final eluate, 80 µL was transferred into a new plate and stored at − 20 ˚C until further use.
Plasmodium species identification was done by nested polymerase chain reaction (nPCR) that targeted the small subunit 18S rRNA gene as described before [
25]. A positive control (for
P. falciparum NF54 culture from Radboudumc, Nijmegen, The Netherlands; for
P. vivax the malaria reference laboratory positive controls from the London School of Hygiene and Tropical Medicine, London, UK) and negative controls (PCR grade water) were run in every reaction plate. Amplified products were visualized using UV transilluminator (Bio Rad, USA) after electrophoresis using 2% agarose gels (SIGMA, ALDRICH) stained with Ethidium Bromide (Promega, Madison, USA).
Statistical analysis
For the school surveys, sample size was calculated based on protocols by Brooker and colleagues [
22] for the original study that aimed at assessing longitudinal evaluation of parasite prevalence in school children [
21]. For this study, 70.0% (231/330) of the students were successfully sampled. For the community surveys, an overall prevalence of 6.8% asymptomatic
Plasmodium infections was expected based on previous observations [
17,
19,
26‐
35] with a precision of 5%. Based on previous experience, a minimum of 75 samples for the school surveys and 114 for the community samples was targeted across the study sites [
21]. Data was double entered into excel, compiled, checked for consistency, and analyzed using Stata version 15 (Stata corporation; College Station, TX, USA) and GraphPad Prism 5.3 (GraphPad Software Inc., CA, USA). Proportions were compared between categories using Fisher’s exact test and Pearson’s chi-squared test where it was appropriate. Equality tests on unmatched data such as age between school and community surveys were tested by two-sample Wilcoxon rank-sum (Mann-Whitney) test. Generalized Estimating Equation (GEE) was used to allow parameter estimates and standard errors adjusted for clustering across the study sites; exchangeable correlation matrix and robust standard errors were used. Sample characteristics such as age, gender, and transmission intensity were tested in the model for their association with infection prevalence and roles as potential confounders. A 5% level of significance was considered in all cases.
Discussion
This study describes the prevalence and detectability of asymptomatic Plasmodium infections in ten different transmission settings by nPCR and conventional diagnostics (i.e. microscopy/RDT). More asymptomatic infections were detected in high transmission settings by both methods. The detectability of asymptomatic Plasmodium infections using microscopy/RDT relative to nPCR increased as transmission intensity increases. As a result, most infections in low transmission settings were not detectable by microscopy/RDT.
In Ethiopia, several cross-sectional studies have documented asymptomatic parasite carriage using conventional and molecular methods [
16‐
18,
33,
34]. The current multi-site study allowed an assessment of factors influencing the prevalence of infections as well as their detectability by microscopy-RDT. The prevalence of asymptomatic
Plasmodium infections in the current study was in the same range as other reports from high [
18,
34] and moderate [
27] transmission settings in Ethiopia and elsewhere [
17,
29,
36,
37].
Consistent with other studies [
16,
38,
39], the current study observed that microscopy/RDT detected fewer asymptomatic infections as compared to PCR. The proportion of
Plasmodium infections that was detectable by microscopy/RDT increased with increasing in transmission intensity. Whilst this trend has been reported in meta-analyses for
P. falciparum [
15,
36,
40], it is striking that this trend is also apparent in the current study within one country affected by both
P. falciparum and
P. vivax. Moreover, the effect size was comparatively large with approximately 5-fold higher detectability of infections in high endemic settings compared to low endemic settings. The trend of increasing detectability with increasing transmission intensity may be attributable to the fact that asymptomatically infected individuals have higher average parasite densities in high transmission settings [
15,
41]. Moreover, in low endemic settings individuals will receive fewer infectious bites with, due to the absence of super-infections, lower parasitemia over the course of infection [
9,
36]. Low genetic diversity of the parasite population in low transmission settings may also contribute to rapidly acquired immunity to the specific clones [
42], further limiting parasite density. An impact of immunity on parasite density and the detectability of infections is also illustrated by the negative impact of increasing age on the detectability on infections in line with the current study [
43].
Lower parasite densities in
P. vivax compared to
P. falciparum [
44,
45] also results in a low detectability of
P. vivax infections by microscopy/RDT. This low density in
P. vivax is mainly attributable to the parasite’s preference to infect reticulocytes [
46,
47] that typically constitute less than 1% of the total erythrocyte population [
48] and also to the early acquisition of immunity [
47]. These findings have implications for estimates of the relative burden of
P. falciparum and
P. vivax infections. The introduction of sensitive molecular tools may thus improve the detection of
P. vivax infections substantially. Since treatment strategies differ for
P. falciparum and
P. vivax, this is relevant for public health interventions.
Although RDT and microscopy were used separately in the study sites due to logistics reasons, the prevalence measured by conventional RDT and microscopy was assumed to be comparable [
37].
Nine samples that were declared microscopy/RDT positive were negative by nPCR while seven samples that were detected
P. falciparum positive by RDT were
P. vivax positive by nPCR. False RDT positivity might be due to the presence of parasite antigens after adequate clearance of parasites which might explain the variation between RDT positivity and PCR negative detection among asymptomatic malaria infections [
49,
50]. Hence, there is a possibility that RDT can be positive for lingering antigens of
P. falciparum while missing the low-density
P. vivax infection from the same patient.
Conclusions
Conventional diagnostics missed nearly half of the asymptomatic malaria reservoir detected by nPCR. Moreover, the detectability of asymptomatic
Plasmodium infections in all endemic sites might reflect the long persistence of these infections from weeks up to months in high [
51] as well as in low transmission settings [
52,
53] even in the presence of effective control and elimination interventions. As these infections can have relevance for onward malaria transmission [
13‐
15], a detailed understanding of the distribution, detectability, and contribution to the infectious reservoir of asymptomatic infections will greatly improve our ability to target all relevant infections. The wide scale presence of low-density infections calls for more in-depth studies on understanding parasite density oscillations, their relevance for malaria symptoms, and onward transmission to mosquitoes.
Acknowledgements
We thank all the study participants for their willingness and local facilitators of the study sites for their support during the sample collection. We also thank the WHO certified microscopists (Tewabech Lema and Tsehay Orlando) at Adama Malaria Center for their support. We appreciate the regional and district health officers for their collaboration. The malaria team members and researchers at AHRI (Tizita Tsegaye, Tadele Emiru, Temesgen Tafesse, Mikiyas Gebremichael, Misgana Muluneh, Endashaw Esayas, Tsegaye Hailu, Haile Abera, Demekech Damte, Tiruwork Fanta, Senya Asfer, and Eyuel Asemahegn) played an important role in making the study successful. We are indebted to the drivers of AHRI for their support during the field sample collection.
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