Effectiveness and safety of artesunate–amodiaquine versus artemether–lumefantrine for home-based treatment of uncomplicated Plasmodium falciparum malaria among children 6–120 months in Yaoundé, Cameroon: a randomized trial

The presence of malaria parasite was detected in capillary blood or venous blood using the SD BIOLINE Malaria Ag P. falciparum (HRP2/pLDH) (Standard Diagnostics, Incorporation, South Korea) and CareStart™ Malaria HRP2/pLDH (Pf/PAN) Combo (Access Bio, Incorporation, Somerset, New Jersey, United State of America) rapid diagnostic test kits before proceeding with microscopy. Thick and thin blood films for parasite counts and speciation of non-falciparum species were obtained and examined at screening on day 0 to confirm adherence to the inclusion and exclusion criteria [39]. Thick blood films were also examined on days 3, 7, 14, 21, and 28 or on any other day if the patient returned spontaneously and parasitological reassessment was required. The slide for each patient was prepared in duplicates. Thick and thin blood films were dried and stained with 10% Giemsa for at least 15–20 min. Giemsa-stained thick and thin blood films were examined at a magnification of 1000 × to identify the parasite species and to determine the parasite density. At least 200 white blood cells (WBCs) were counted. Parasite density was calculated by multiplying the number of parasites counted per microscopic field by a factor of 40 on the assumption that the average count of WBC is 8000 per µl. If on counting 200 WBCs, the number of parasites was not up to 100, the count continued till 500 WBCs and calculations made to get the estimated parasitemia of the patient. Parasitemia was reported in parasites/μl. A microscopy slide was considered negative when examination of 1000 white blood cells or 100 fields containing at least 10 white blood cells per field revealed no asexual parasites. The presence of gametocytes on an enrollment or follow-up slide was also recorded. To detect the presence of gametocyte, at least 1000 white blood cells were counted. Two qualified microscopists read all the slides independently, and parasite densities were calculated by averaging the two counts. Blood smears with discordant results (differences between the two microscopists in species diagnosis, in parasite density of > 50% or in the presence of parasites) were re-examined by a third, independent microscopist, and parasite density was calculated by averaging the two closest counts. Additionally, 10% of all the slides were randomly selected and read by a senior microscopist for quality control. Enrollment into the study depended on a positive malaria rapid diagnostic test and microscopy.

Hemoglobin level was measured from finger prick blood sample using portable Hemocue 201 and Hemocue 301 spectrophotometers (HemoCue®, Ängelholm, Sweden). Whole blood was collected in ethylene diamine tetra acetic acid (EDTA) tubes and dry tubes for hematology and biochemistry analyses respectively. The samples in EDTA tubes were properly mixed to avoid blood clot before laboratory analyses. Hematological parameters were analyzed with URIT 3000 hematology analyzer (URIT Medical Electronic Co., Limited, Guangxi, China) and Mindray 3000 Plus (Shenzen Mindray Bio-medical Electronic Co., Limited, Shenzen, China). Blood biochemistry parameters were analyzed using the URIT 810 semi-automated Chemistry analyzer (URIT Medical Electronic Co., Limited, Guangxi, China). Measurements were carried out on days 0, 7, 14, 28 and during unplanned visits. Quality control was carried out daily to validate each test run. Each parameter was evaluated by comparing it values with the established reference ranges (Additional file 2).

The malaria parasite deoxyribonucleic acid (DNA) was extracted from whole blood collected in EDTA tubes and dried blood spots (DBS) on Whatman® N^o 3 mm filter papers using the EZNA Biotek method according to the manufacturer’s guidelines. DNA was extracted from the whole blood in EDTA tubes/DBS on day 0 (before treatment) and during recurrence of parasitemia on day 7 onwards (cases of treatment failure).

Genotyping was done in order to differentiate a recrudescence (same parasite strain) from a newly acquired infection (different parasite strain). The P. falciparum merozoite surface protein 1 (Pfmsp-1), P. falciparum merozoite surface protein 2 (Pfmsp-2) and P. falciparum glutamate-rich protein (Pfglurp) genes were used to discriminate reinfections from recrudescence as previously described [40, 41]. Summarily, DNA fragments obtained from amplification of baseline samples (day 0) and on the day of recurrent parasitemia were compared according to band size and number, considering the 3 families of Pfmsp-1 (MAD20, RO33, K1), the 2 families of Pfmsp-2 (FC27, 3D7/IC) and single family type of Pfglurp. Cases were categorized as new infections when there were no common bands between day 0 and the day of recurrent parasitemia. However, when there was at least one common band between baseline sample and that of the day of parasite reappearance for any of the 3 markers (even if there were additional bands on day 0) the case was recrudescence. Malaria parasite infected cases were considered not to be clinical failures if their recurrent parasitemia were classified as new infections rather than recrudescent infections. The gene amplification was done using the Biometra T3 Thermocycler (United Kingdom).

Adherence to prescribed treatment schedules was assessed through interviews (self-reporting) on day 3 post-treatment about the timing of treatment, the number of doses administered and the number of days over which drug was given. The interviews were conducted at the health facility. Used packs of drugs were inspected where available. Participants who had persistent vomiting (vomited more than once within one hour) after the first dose was administered, were enrolled without meeting all the inclusion criteria, withdrew consent after day 0 and did not show up on day 3 post-treatment were excluded from the assessment. Adherence was classified as follows: poor adherence (adherence rate < 95%) and good or perfect adherence (adherence rate ≥ 95%).

Treatment effectiveness was evaluated based on clinical and parasitological outcomes. This assessment was done according to the WHO 2009 guideline for monitoring therapeutic efficacy studies [3]. Based on this guideline, treatment outcome was classified as treatment failure and treatment success. Treatment failure is defined as early treatment failure (ETF), late clinical failure (LCF) and late parasitological failure (LPF). Treatment success is defined as adequate clinical and parasitological response (ACPR).

Safety was based on assessment of adverse events (AEs) and severe adverse events (SAEs) on day 1 to day 28. A physician from the study team was designated to monitor the safety of ACTs. Adverse events were recorded through interviews or self-reporting about previous symptoms and about symptoms that have emerged since the previous follow-up visit. A clinical examination was performed to determine any adverse event. In addition to clinical assessment, hematological parameters, liver function and renal function were evaluated for abnormal values. An adverse event (AE) is defined according to the International Conference on Harmonization guidelines as any untoward medical occurrences in a patient administered a pharmaceutical product and which does not necessarily have a causal relationship with the treatment of interest [42]. A severe adverse event (SAE) is considered as an untoward medical occurrence that at any dose results in death, is life threatening, requires or prolongs hospitalization, results in persistent and significant disability, is a congenital anomaly/birth defect or is another medically important condition [42].