View clinical trials related to Malaria.
Filter by:This is a clinical trial to evaluate the safety and immunogenicity of R21/MM in healthy Kenyan participants from the different age groups.Participants will receive 3 vaccinations 4 weeks apart.
This is a community-based cluster-randomized trial in which a novel approach to interrupt residual malaria transmission by mass drug administration (MDA) with ivermectin (IVM) combined with dihydroartemisinin-piperaquine (DP) will be tested. This cluster-randomized trial will involve 32 villages in the Upper River Region of The Gambia that will be randomized to MDA with IVM and DP or to standard of care in a ratio 1:1. This trial aims at establishing whether MDA with IVM and DP can reduce or interrupt malaria transmission in medium to low transmission settings by reducing vector survival and the human reservoir of infection. MDA with IVM and DP will be implemented in the intervention villages and all human settlements in the buffer zone, with the aim of minimizing spillover effects. Control clusters will receive standard malaria control interventions as implemented by the National Malaria Control Program. The primary outcomes will be the prevalence of malaria infection determined by molecular methods in all age groups at the peak of the second transmission season (November-December 2019) and the vector's parous rate 7-14 days after MDA.
Many malaria deaths occur in places where people have poor access to preventive and curative health services. Prompt access to quality health services is critical in the case of severe childhood diseases, among which severe malaria is particularly frequent in endemic areas. In communities where parenteral treatment of severe malaria is not available, the World Health Organization (WHO) recommends administration of a single rectal dose of artesunate (RAS) to children less than 6 years, followed by immediate referral to an appropriate facility where the full package of care for severe malaria can be provided. Many African countries have already endorsed the use of pre-referral RAS. But treatment guidelines vary widely across these countries and often do not align with the WHO recommendation. With the impending availability of quality-assured rectal artesunate (QA RAS) and countries poised to scale-up this intervention, it is critical to investigate the safe and effective implementation of RAS as part of a continuum of care for severe malaria patients. To ensure that RAS is well targeted, it is equally urgent to learn more about frequency, treatment seeking and risk factors for severe malaria at community level. The CARAMAL project has two major components: the pilot implementation of QA RAS in selected areas of the Democratic Republic of the Congo (DRC), Nigeria and Uganda, and operational research on the introduction of QA RAS into established integrated community case management (iCCM) platforms. The CARAMAL project is funded by Unitaid and coordinated by the Clinton Health Access Initiative, Inc. (CHAI). UNICEF is responsible for QA RAS implementation. Swiss TPH in partnership with the local research organizations Akena Associates Ltd. in Nigeria, Kinshasa School of Public Health in DRC and Makerere University School of Public Health in Uganda carries out the operational research component to generate evidence for the responsible implementation of RAS. Finally, the CARAMAL project will generate a better understanding of severe febrile illness, its management at all levels and key determinants of health outcomes.
The massive scale-up of Long Lasting Insecticidal Nets (LLIN) has led to a major reduction in malaria burden (up to 50%) in many sub-Saharan African countries. This progress is threatened by the wide scale selection of insecticide resistant malaria vectors. New types of LLIN combining a mixture of two insecticides or an insecticide and a synergist have been developed to control resistant mosquitoes. The efficacy of three bi-treated LLIN are compared to a standard LLIN in a four-arm, single blinded, cluster-randomized trial in Misungwi district, Tanzania. The arms are; 1/ Royal Guard, a net combining pyriproxyfen (PPF), which is known to disrupt female reproduction and fertility of eggs, and the pyrethroid alpha-cypermethrin, 2/Interceptor G2, LLIN incorporating a mixture of two adulticides with different modes of action; chlorfenapyr and a pyrethroid (alpha-cypermethrin), and 3/ Olyset Plus an LLIN which incorporates a synergist, piperonyl butoxide (PBO), to enhance the potency of pyrethroid insecticides, and 4/ The control arm: Interceptor treated a standard LLIN treated with alpha-cypermethrin. The primary outcome of the trial will be cross-sectional community prevalence of malaria infection (by RDT) in children aged 6 months to 14 years at 12 and 24 months post-intervention.
A single-centre Phase 1b study to assess the safety, tolerability, pharmacokinetic profile, and antimalarial activity of single doses of coadministered artefenomel (OZ439) and piperaquine phosphate (PQP) against early Plasmodium falciparum blood stage infection in healthy adult volunteers.
Background: In developing countries, micronutrient deficiency in infants is associated with growth faltering, morbidity, and delayed motor development. One of the potentially low-cost and sustainable solutions is to use locally producible food for the home fortification of complementary foods. Objective: The objectives are to test the hypothesis that locally producible spirulina platensis supplementation would achieve the following: 1) increase infant physical growth; 2) reduce morbidity; and 3) improve motor development. Design: 501 Zambian infants are randomly assigned into a control (CON) group or a spirulina (SP) group. Children in the CON group (n=250) receive a soya-maize-based porridge for 12 months, whereas those in the SP group (n=251) receive the same food but with the addition of spirulina. The change in infants' anthropometric status, morbidity, and motor development over 12 months are assessed.
This study is a single site, randomized, double-blind, placebo-controlled trial. The trial will assess the safety, tolerability, immunogenicity and vaccine efficacy (VE) of PfSPZ Vaccine in Gabonese children that are naturally exposed to malaria parasites. Healthy children aged 1- 12 years living in the surrounding areas of Lambaréné and/or Fougamou Province in Gabon will be eligible for participation.
Light microscopy, which is based on century-old technology, remains a key indicator in drug efficacy testing performed in the context of clinical trials for monitoring existing antimalarial drugs or in the context of regulatory clinical trials for registration of new drugs. It is one of the main diagnostic methods for malaria diagnosis in general, as in an ideal setting it can provide low-cost accurate diagnosis, determine the density of parasites in the blood, and accurately differentiate between different malaria parasite species, characteristics vital to the implementation of global plans for drug efficacy monitoring. Malaria rapid tests (RDTs), while useful for rapid diagnosis and case management, do not provide information on the parasite density nor the species differentiation necessary for research and drug efficacy assessment. Microscopy therefore retains key advantages over a number of newer technologies, but its reliability is severely impeded by dependence on high technical competence of the human operators as well as availability of high quality equipment and reagents. Recent studies have demonstrated frequent poor specificity and sensitivity associated with manual microscopy diagnostics in operational conditions. These drawbacks constitute a major limiting factor to effective monitoring and preservation of vital anti-malarial medicines. Advances in digital microscopy performance and affordability have now opened the door to potentially significant improvements in the performance of malaria microscopy, overcoming serious deficiencies in current drug efficacy assessment, and more broadly in malaria diagnosis and management. Global Good (GG)/Intellectual Ventures Laboratory (IVL) sponsored by the Global Good Fund, has developed a microscope prototype consisting of low cost components to scan and capture images from Giemsa-stained thick blood films on slides. The captured images are analyzed with custom image analysis software developed at GG/IVL, using algorithms that are designed for automatic malaria diagnosis, without user input. Versions of a prototype of the device were first tested in field settings in Thailand in 2014-2015 at clinics operated by the Shoklo Malaria Research Unit (SMRU) and then again in 2016-2017. When compared to expert microscopy at SMRU, the performance of the device with respect to diagnostic sensitivity (87.8%), species identification (85.6% species correctly identified) and parasite density estimation (44% of estimates within +/-25% of reference microscopy result) corresponded to WHO Competence Level 2. The device and the accompanying image analysis algorithms have since been further developed and a new, third version of the prototype is now available for testing in diverse settings with varying malaria prevalence and user expertise.
Background: The disease malaria affects many people in Mali and other parts of Africa and the world. It is caused by germs spread by mosquito bites. Malaria may be mild. But it can also be serious or lead to death if it is not treated promptly. Researchers want to find a safe vaccine that prevents malaria. Objective: To study how safe and tolerable the malaria vaccine called PfSPZ Vaccine is for healthy adults. Eligibility: Healthy adults: - ages 18-35 in Ouelessebougou, Mali - not infected with HIV, hepatitis B, or hepatitis C - for females, not pregnant or breastfeeding and must use reliable birth control during the study Design: Participants will be screened with questions about malaria and will undergo blood, urine, and heart tests. Participants will be randomly assigned to 1 of 4 groups. They will get injections of either the PfSPZ Vaccine or a salt-water placebo. They will not know which one they get. Vaccinations will occur leading into the malaria transmission each year with 3 injections leading into Year 1 (malaria transmission season in 2018) and 1 injection prior to Year 2 (malaria transmission season 2019). One vaccine group and one placebo group will get an injection 3 times over 4 weeks with an additional vaccination ~10 months later. The other two groups (vaccine group and placebo) will get an injection 3 times over 16 weeks with an additional vaccination ~10 months later. All participants will be treated with an antimalarial medication prior to the third injection and prior to fourth injection. They will be followed for approximately 6 months after third and fourth injection. At vaccine visits, female participants will have a pregnancy test before injection. All participants will have an arm cleaned and the vaccine injected in a vein. They will be watched for 30 minutes. At non-vaccine visits, participants will have a physical exam and be asked how they are feeling. They will usually have blood tests.
The main aim of this study is to test the primary hypothesis that the addition of intermittent screening and treatment of malaria in pregnant women (ISTp) who receive routine antenatal care (ANC) in health facilities in high malaria transmission areas in Rwanda will reduce malaria prevalence among pregnant women when compared to routine antenatal cares services alone.