View clinical trials related to Vector-Borne Diseases.
Filter by:Effective control of Aedes aegypti mosquitoes in breeding sites with high reproductive rates could have a major impact on reducing arbovirosis in endemic communities. The application of a safe, effective, low cost and sustained insecticide coating (IC) could be an affordable response to dengue for local health services. Therefore, a cluster randomised trial for the application of a new vector control tool (insecticidal coating of water containers) was conducted in the metropolitan area of Cúcuta, Colombia. The IC is an aqueous solution containing polymeric microcapsules of insecticides and insect growth regulators (pyriproxyfen-PPF (0.063%) and alphacypermertrin-ACM (0.7%) in suspension, without interaction between them, development by INESFLY®, Spain. The main questions it aims to answer are: Whether the control of the main breeding sites of Aedes mosquitoes, through the application of insecticide coating, in clusters of dwellings, could reduce dengue transmission in a sustainable way, compared to untreated clusters, in Cúcuta, Colombia. Whether the control of the main breeding sites of Aedes mosquitoes through the application of insecticide coating, in clusters of dwellings, could reduce the Aedes Indices in a sustainable way, compared to untreated clusters. The initial preparation phases: i) socialization ii) A safety evaluation to determine the health risks of IC in domestic water containers; iii) The determination of the effects and efficacy of IC on Aedes aegypti. The Baseline study to characterise the study clusters from entomological, epidemiological and socio-economic approaches was carried out in 2019-2020. The IC application phase in the intervention arm was carried out between Nov-2021 and Jan-2022, with the respective monitoring of the safety of IC use. This was followed by entomological monitoring. Finally, the 9-month post-intervention evaluation. Epidemiological data were obtained from the National Public Health Surveillance System - SIVIGILA. The study was conducted in 20 clusters of 2000 dwellings each, where 10 clusters were randomly assigned to the control arm and 10 clusters to the intervention arm. In order to determine the effect of IC application in household tanks, the dengue incidence and entomological indices are compared in the study clusters. The data are analysed under the difference in difference approach. Additionally, the acceptance of IC in the intervened communities and local health services is determined.
The aim of this study is to determine the effectiveness of a new spatial repellent (called Mesh) at repelling multiple disease vectors and, reducing clinical malaria rates in temporary shelters and camp settings. The design of the study will be a two-armed cluster randomised trial. By conducting the research in challenging camp settings in the north of Nigeria, the MENTOR Initiative aims to determine whether Mesh can be effective in harsh camp conditions where communities are living in conflict area temporary shelters.
Malaria is a major public health problem. There were around 240 million cases of malaria and 627,000 deaths worldwide in 2020. Most of the deaths are in children under five living in Africa. It is a major problem for those who live in affected areas and for travellers. There is a great need for a safe, effective malaria vaccine. This study is being done to evaluate an experimental malaria vaccine for its safety and also look at the body's immune response to the vaccine. The vaccine tested in this study is called and "RH5.1". This is given with an adjuvant called "Matrix-M". This is a substance to improve the body's response to a vaccination. The aim is to use the vaccines and adjuvant to help the body make an immune response against parts of the malaria parasite. This study will assess: 1. The safety of the vaccines in healthy participants. 2. The response of the human immune system to the vaccines. This will be achieved by giving participants three doses of the RH5.1 vaccines at two different dose levels (10 micrograms and 50 micrograms). One group will have 3 doses of 10 micrograms given at 0, 1 and 6 months whilst the other will receive 2 doses of 50 micrograms (at 1 and 2 months) followed by a 10 microgram dose at 6 months- known as a 'delayed fractional dose'. Blood tests and information about any symptoms will be performed/collected that occur after vaccination. Information from previous studies suggests that a delayed fractional dose improves the immune response to the vaccine, particularly in terms of the antibody response. Current prediction is that this improvement is due to the delay in dosing, rather than the reduction in dose, and this study will help to answer that. Having a vaccine at a single dose is important for efficient production and dosing for vaccines rolled out in national programs so being able to move away from 'delayed fractional dose' regimens to 'delayed final dose' regimens will be important for vaccine development.
This is an open-label, adaptive study using the P. falciparum induced blood stage malaria (IBSM) model to characterise the pharmacokinetic/pharmacodynamic (PK/PD) profile and safety of MMV367 (the IMP). Up to 18 participants will be enrolled in cohorts of up to 6 participants each. The study will proceed as follows for all participants: - Screening period of up to 28 days to recruit healthy adult participants. - Day 0: Intravenous inoculation with approximately 2,800 viable P. falciparum-infected red blood cells. - Days 1-3: Daily follow up via phone call or text message. - Days 4-7: Daily site visits for clinical evaluation and blood sampling to monitor malaria parasite numbers via quantitative polymerase chain reaction (qPCR). - Day 7 PM: Start of confinement within the clinical trial unit. - Day 8: Administration of a single oral dose of the IMP (MMV367). Different doses of MMV367 will be administered across and within cohorts in order to effectively characterise the PK/PD relationship. - Days 8-11: Regular clinical evaluation and blood sampling while confined to monitor malaria parasite numbers and measure MMV367 plasma concentration. - Day 11 AM: End of confinement within clinical trial unit. - Days 12-23: Outpatient follow-up for clinical evaluation and blood sampling. - Day 24: Initiation of compulsory definitive antimalarial treatment with Riamet® (artemether/lumefantrine) and/or other registered antimalarials if required. Treatment will be initiated earlier than Day 24 in the event of: - Insufficient parasite clearance following IMP dosing - Parasite regrowth following IMP dosing Characterising the pharmacokinetic/pharmacodynamic relationship of MMV367 - Participant discontinuation/withdrawal, - Investigator's discretion in the interest of participant safety. - Day 27: End of study visit for final clinical evaluation and to ensure complete clearance of malaria parasites.
Malaria is a major public health problem. There were around 240 million cases of malaria and 627,000 deaths worldwide in 2020. There is a great need for a safe, effective malaria vaccine and the team at University of Oxford is trying to make vaccine(s) which can prevent serious illness and death. This study is being done to assess an experimental malaria vaccine for its ability to prevent malaria illness. This is done using a 'blood-stage challenge model'. This is when volunteers are infected with malaria parasites using malaria-infected red blood cells. The vaccine we are testing in this part of the study is called "RH5.2-VLP". It is given with an adjuvant called "Matrix-M". This is a substance to improve the body's response to a vaccination. RH5.2-VLP is being tested for the first time in humans in this trial. The Matrix-M adjuvant has been given to tens of thousands of people, with no major concerns, such as illness. The aim is to use this vaccine and adjuvant to help the body make an immune response against parts of the malaria parasite. This study will assess: 1. The safety of the vaccine in healthy participants. 2. The response of the human immune system to the vaccine. 3. The ability of the vaccine to prevent malaria illness (Group 2 only). We will do this by giving healthy adult participants (aged 18-45) three of the vaccines and/or expose participants to malaria infection at the Centre for Clinical Vaccinology and Tropical Medicine (CCVTM), Churchill Hospital in Oxford. We will then do blood tests and collect information about any symptoms that occur after vaccination. There will be 19 to 54 visits, lasting between 3 months to 2 years and 2 months.
The goal of this clinical trial is to test whether In2Care EaveTubes (ETs) as a stand-alone tool can reduce malaria in an area where transmission is driven by insecticide-resistant Anopheles gambiae. Children who live in homes with ETs will be monitored for malaria infection and compared to children living in homes without ETs in Côte d'Ivoire where there is universal coverage of long lasting insecticide nets and pyrethroid resistance is high.
The primary objective of the study is to demonstrate and quantify the protective efficacy of a single Spatial Repellent (SR) product, in reducing malaria infection in a human cohort. The study design will be a prospective cluster Randomized Control Trial (cRCT).
Background: Zika, dengue, and chikungunya are spread by mosquitos. These diseases have a major impact on public health. This is especially true in in Southeast Asia. Non-human primates (such as macaques) could play an essential role in spreading these diseases. Researchers want to further understand the relationship between humans and these primates. They want to see how this affects how mosquito-borne viruses are spread in Southeast Asia. Objective: To describe the prevalence of Zika virus, dengue virus, and chikungunya virus in the blood of people who live close to long-tailed macaques in Thailand and Cambodia. Eligibility: Healthy people aged 18-55 who have lived or worked within approximately 10 kilometers of the Wat Amphae Phnom monkey habitat in Kampong Speu, Cambodia, for a minimum of 2 years Design: Participation will last 1 day. Participants will be screened in person through an interview. Their medical history will be reviewed. Participants will give information about themselves. This will include sex, age, and behaviors related to the spread of mosquito-borne disease. For example, they will be asked about the number of water containers at their home. They will be asked about recent travel. They will be asked about the extent of their contact with the macaques. Participants will give a blood sample....
Background: Mosquito-borne viruses like dengue cause major illness and death worldwide, particularly in Southeast Asia. When mosquitoes deliver a virus into the skin of humans, they also leave saliva. Researchers want to learn more about skin immunity to mosquito saliva. They hope this will help with future vaccines and treatments for these diseases. Objective: To compare the early and late innate immune response in the skin of Aedes aegypti bitten versus unbitten skin. Eligibility: Healthy people ages 18-45 who live within about 15 km of the study site in Chbar Mon Design: Participants will have 3 visits. The baseline/screening visit will include: Medical and medication history Questions about participants demographic information, mosquito biting risk factors, and responses to mosquito or other insect bites Physical exam Urine sample for some participants Mosquito feeding. A feeding device will be placed on the participant s arm for up to 20 minutes. The insects will feed through a mesh on the bottom of the feeding device. Participants may be given standard treatments for any skin reactions. Blood tests Four skin biopsies taken from bitten and unbitten skin. Local anesthetic will be administered, and a small tool will be used to remove the participant s skin. Participants will have a second visit the next day. They will have a physical exam and blood tests. They will have 1 skin biopsy. Participants will have a final visit about 2 weeks later. They will have a physical exam and blood tests. During the study, participants will be asked to take measures to prevent more mosquito bites.
Background: Vector-borne diseases are caused by the bite of an infected mosquito, fly, flea, tick, or other blood-feeder. These diseases cause almost 1 million deaths per year. And they are on the rise, particularly in Southeast Asia in particular. Researchers think that these diseases make up about 10 percent of fevers in Cambodia. But many of these illnesses are never diagnosed. Studying these diseases can help find new ways to identify and treat them. Objective: To find pathogens in people who have a fever using metagenomic pathogen sequencing platforms. Eligibility: People aged 2 months to 65 years with a fever of at least 38 degrees Celsius or those diagnosed with infection by a pathogen of concern who visit the referral hospital in Cambodia. Close contacts of people diagnosed with infection by a pathogen of concern may also be enrolled. Design: Participants will be screened with their medical history. Children will be weighed to make sure they are big enough to give blood samples. Participants will share data about their sex, age, and where they live. They will answer more questions about their heath history. They will answer questions about and any places to which they have recently traveled. They will take a questionnaire. They will have a blood test. If they have respiratory symptoms, they will have a nasal swab. Participants may be contacted within 1-2 weeks (early) and/or within 3 months (late) from their enrollment date to provide an optional follow-up blood samples and nasal swabs.