View clinical trials related to Malaria, Falciparum.
Filter by:Across sub-Saharan Africa, school-age children bear an under-appreciated burden of malaria. An estimated 200 million school-age children are at risk of malaria and in many areas prevalence of infection exceeds 50%. The high infection rates in this group serves as a source of onward parasite transmission, undermining elimination and control efforts. Furthermore, malaria illness and malaria-induced anemia in this age group lead to school absenteeism, and impaired cognitive function and classroom attention, ultimately resulting in reduced academic achievement. Although universal malaria interventions, such as insecticide treated nets (ITNs) and access to prompt diagnosis and treatment are available to school-age children, this age group is the least likely to benefit from these interventions. Furthermore, efficacy of these approaches may be compromised by increasing anti-malarial drug and insecticide resistance. A malaria vaccine could help to avert the burden of malaria in this age group. The RTS,S/AS01 malaria vaccine has recently been recommended for vaccination of young children (< 24 months) by the World health organization (WHO) after a Phase 3 trial and an implementation trial showed that the vaccine had moderate but significant efficacy to prevent clinical and severe malaria in young children. Previous randomized trials suggest that the vaccine is safe for older children. However, efficacy of the vaccine has never been assessed in school age children. Kamuzu University of Health Sciences in partnership with the Malawian Ministry of Health seeks to evaluate the efficacy of the newly introduced RTSS/AS01 malaria vaccine in school aged children. The study hypothesizes that vaccination will decrease the morbidity and transmission of malaria, as well as improve school absenteeism and educational outcomes.
Mali faces a significant challenge with malaria, particularly among its younger population. While existing measures like seasonal chemoprevention and vaccination have shown efficacy, further innovations are necessary to combat this disease. The monoclonal antibody TB31F shows promise in reducing the transmission of malaria. This clinical trial will evaluate the safety and efficacy of the monoclonal antibody TB31F.
Seasonal malaria chemoprevention (SMC) is a highly effective community-based intervention to prevent malaria infections caused by Plasmodium falciparum in areas where the burden of malaria is high and malaria transmission is seasonal. SMC is commonly seen as a success story in the Sahel region, however, there are regions in east and southern Africa where malaria transmission is seasonal, and the burden is high. However, the same decision-making frameworks that was used in the Sahel are unlikely to be applicable to east and southern Africa due to higher pre-existing resistance to the drugs used, seasonality heterogeneity, contextual difference, and unknown cost-effectiveness, amongst others. This study aims to estimate the chemoprevention efficacy, potential upscale impact, acceptability, and feasibility of SMC with sulfadoxine-pyrimenthamine + amodiaquine (SP+AQ) medicines in Niassa Province in Mozambique. The study is divided into two separate components with different objectives which outputs feed into each other: a non-randomized controlled trial to estimate the chemoprevention efficacy of SP+AQ; and a qualitative study that will evaluate the feasibility and acceptability of the intervention. These will be the first studies analysing the chemoprevention efficacy, feasibility, acceptability, and potential scale-up impact of SMC in Niassa Province, Mozambique The outcomes of these studies aim to guide future policy changes at local, national, and international levels and potentially allow for a historically successful program to expand in a sustained and cost-effective way beyond the Sahel region.
This study will assess the durability of protection of a single immunisation with the Genetically Attenuated Parasite 2 (GA2) against controlled human malaria infection by rechallenging previously immunised and protected participants from the CoGA study (NCT05468606)
This is an individually randomized, controlled, single blind four arm clinical trial of malaria chemoprevention strategies Arm 1: Intermittent preventive treatment with dihydroartemisinin-piperaquine (IPT-DP). Arm 2: Intermittent preventive treatment with sulfadoxine-pyrimethamine (SP) plus chloroquine (CQ) (IPT-SPCQ). Arm 3: Intermittent preventive treatment with sulfadoxine-pyrimethamine (SP) plus amodiaquine (AQ) (IPT-SPAQ).Arm 4: Control - students will receive standard of care (no preventive treatment). Outcomes include P. falciparum infection and parasite density, anemia, cognitive function and educational testing, as well as infection prevalence and disease incidence in young children sleeping student's households to assess the impact on transmission.
This is an open i.e. not blinded, cluster-randomised, controlled intervention study. The study will use a factorial design to estimate the protective effectiveness of mass drug administrations, mass vaccinations, combined mass vaccinations and drug administrations versus the current standard of care.
The goal of this open-label randomised, controlled, non-inferiority trial is to assess and compare the efficacy, tolerability and safety of a fixed dose TACT artemether-lumefantrine-amodiaquine (ALAQ) to the ACTs artemether-lumefantrine (AL), artesunate-amodiaquine (ASAQ) (with single low-dose primaquine in some sites) for the treatment of uncomplicated Plasmodium falciparum malaria in patient. The main question it aims to answer is whether ALAQ, a fixed dose TACT, is as efficacious, safe and tolerable in comparison with AL and ASAQ. Participants will be enrolled, admitted and randomised to receive the study drug (ALAQ, AL or ASAQ). Patients will receive directly observed treatments and will be followed up at least once daily for the first 3 days after enrolment followed by weekly visits from D7 up to D42. Patients will be asked to report to the clinics between scheduled visits in case of any illness or other symptoms or complaints.
Malaria is caused by protozoan parasites of the genus Plasmodium and it is the most important parasitic disease in terms of mortality and morbidity. Estimates of 247 million malaria cases and 619.000 deaths worldwide were reported by WHO for the year 2021 (1). Plasmodium falciparum can lead to severe malaria and accounts for 90% of malaria deaths that mainly occur in children below the age of 5 years in Sub-Saharan Africa. A simplified treatment regimen, ideally a single-day cure (or at most 2-day dosing regimen), of uncomplicated malaria due to P. falciparum would be the magic in the antimalarial armamentarium. Improving treatment adherence is one of the key factors in reducing mortality and morbidity and also the transmission of malaria, and such a regimen would substantially increase adherence. To find a new non-artemisinin combination therapy with a shorter regimen, ideally, a single-dose cure, with low resistance potential would be the aim. The two compounds tested here are ZY19489, a triaminopyrimidine, and ferroquine (FQ), a next-generation 4-aminoquinoline. Both compounds show unique features in terms of long half-life, and activity against current drug-resistant strains. Therefore, the main goal of this clinical trial is to assess the safety of the ZY19489-FQ combination given as a 1- or 2-day dose regimen.
The investigators believe that to effectively achieve malaria elimination in Rwanda, it is critical to target the human reservoirs of Plasmodium falciparum using local and readily available Artemisia tea. Asymptomatic infections detectable by PCR are important reservoirs because they often persist for months and harbor gametocytes, the parasite stage infectious to mosquitoes. Lessons learnt from this study will be of critical importance for health decision makers with regard to potential malaria control. MSc and PhD students will be trained and the impact of this research project will be enormous on the socioeconomic transformation of Rwanda.
Background: Artemisinin resistance has emerged in parts of Southeast Asia, and there are reports in Africa of reduced susceptibility of Plasmodium falciparum parasites against artemisinin-based combination therapy (ACT). No new drugs are available in the pipeline to replace ACTs in case they fail. This study aims to assess whether a sequential administration of triple ACTs with different partner-drugs can improve the efficacy of ACT for treatment of uncomplicated malaria. Methods: A health facility-based, three-arm partially blinded randomized clinical trial will be conducted to assess efficacy and safety of a sequential administration of artemether-lumefantrine followed immediately by artesunate-amodiaquine (AL+ASAQ) or artemether-lumefantrine with by amodiaquine (AL+AQ) compared to artemether-lumefantrine plus placebo (AL+PBO). Eligible children aged 6 - 120 months and with microscopy confirmed uncomplicated P. falciparum malaria will be enrolled, administered with trial medicines and followed-up at 0 (just prior to first drug intake) and 8 hours on day 0, 12 hourly on days 1, 2, 3, 4, 5, followed by once daily on days 6, 7, 8, 9, 10, 11, 12, 13, 14, 21, 28, 35, 42 and 56 for clinical and laboratory evaluations. Clinical evaluation will involve assessment of signs and symptoms related to the disease and or trial medicine during follow-up. Laboratory evaluation will include microscopic determination of presence of malaria parasites and species, hemoglobin level, molecular analysis for markers of drug resistance and to differentiate recrudescence from new infection. The primary outcome will be Polymerase Chain Reaction (PCR)-adjusted adequate clinical and parasitological cure rate on days 28 and 42. Expected outcomes: The findings will give an insight on whether 3 ACTs are more efficacious than the use of first-line regimen alone, and are tolerable for treatment of uncomplicated falciparum malaria.