12 Clinical Trials for Various Conditions
This study will investigate the effect of Tafenoquine (TQ) 150 mg tablet ageing (dissolution profiles) on human exposure of TQ comparing the relative bioavailability of TQ from tablets exhibiting different dissolution profiles in healthy subjects. This is a single-centre, 2-arm, randomized open-label, parallel-group study in healthy subjects. All subjects will arrive in the unit approximately 24 hours prior to dosing and will be discharged after the 72-hour post-dose assessments are completed. Subjects will return for outpatient visits on Days 7, 14, 21, 28, and 56 after dosing. A total of 14 subjects (n=7 subjects in each arm) are planned to be enrolled. All subjects will receive a single dose of study medication (2x150 mg TQ tablets + 30 mg TQ SIL in solution) and participate through a 56-day post dose follow-up visit. To enable the application of peripheral microsampling in planned paediatric studies, a comparison of the measured pharmacokinetic (PK) exposure via peripheral blood collection (via microsampling) to venous collection will also be performed in this study.
The study aims to provide evidence of retinal safety to support the use of tafenoquine as a potential single dose radical cure treatment for patients with Plasmodium vivax (P. vivax) malaria (i.e., co-administration of a schizonticidal drug with TQ). The study will be conducted as a single masked, randomized, placebo-controlled, parallel group design. It will assess retinal changes from baseline using spectral domain optical coherence tomography (OCT) and fundus auto fluorescence (FAF) at Month 3 (90 days) post-dose in adult healthy volunteers (participants). A placebo control group will be used to compare the results in the TQ group. Interim analysis will be conducted after completing 100 out of 300 participants in TQ group and 50 out of 150 participants in matched placebo.
This will be a single-centre, 5-cohort, randomized open-label, parallel-group study in healthy volunteer subjects. This study aims to provide sufficient pharmacokinetic (PK) evidence to support the safe usage of Tafenoquine (TQ) in studies and markets where the Artemisinin-based Combination Therapies (ACTs) are the standard of care for patients with Plasmodium vivax malaria (i.e., co administration with TQ). The objective of this study is to assess the pharmacokinetics, safety and tolerability of TQ when co-administered with the chosen ACTs (AL and DHA + PQP), administered concomitantly in healthy subjects. Specifically, the study will evaluate whether there are drug-drug interactions between TQ and each of the ACTs and if these interactions are considered to be clinically significant. The co-primary objectives of this study are to characterize both the effects of a 300 milligram (mg) single dose of TQ on the pharmacokinetics; changes in (area under the concentration-time curve from 0 to time t) AUC (0-t), AUC (0-infinity), and maximum observed concentration (Cmax) of each of the two Artemisinin-based Combination Therapies (ACT) according to their prescribed dose when co-administered as well as the effects of the ACTs on the PK of TQ. A total of 120 subjects (24 subjects in each of 5 cohorts) are planned to be enrolled in order to ensure a target sample size of at least 22 subjects completing the study per cohort. All subjects will arrive in the unit at least 24 hours prior to dosing and be discharged after 72-hour post first dose assessments have been completed. Subjects will return for outpatient visits on Days 7, 14, 21, 28, and 56 after first dose.
This will be a randomized, single-blind, placebo controlled, parallel group study. Approximately 260 subjects will be enrolled in five groups. This study is designed to compare the effects of tafenoquine, administered as single dose as well as administered over three consecutive days, on the changes in QT duration to those observed in subjects dosed with either moxifloxacin or placebo.
OZ439 is a synthetic trioxolane that has potential value as a peroxide antimalarial agent. This was a Phase I, single-centre, multi-component, double-blind, randomised, placebo-controlled study in healthy male and female subjects. The study was conducted in 3 parts: * Part A investigated the safety, tolerability and pharmacokinetics (PK) of single oral escalating doses of OZ439. Up to 6 dose levels will be investigated to estimate dose proportionality. * Part B, the effect of food on a single oral dose of OZ439 was investigated in a 2-way crossover design. * Part C investigated the safety, tolerability and PK profile of multiple oral doses of OZ439. The starting oral dose was 50 mg and the maximum single dose to be administered did not exceed 1600 mg per subject. The maximum duration of dosing proposed was 3 days.
The purpose of this study is to demonstrate that volunteers can be safely and reproducibly infected with Plasmodium vivax (P. vivax) by the bites of experimentally infected Anopheles dirus (An. dirus) mosquitoes carrying P. vivax sporozoites in their salivary glands.
This study, conducted at Johns Hopkins University Center for Immunization Research in Washington DC, will test the safety and immune response of healthy volunteers to two experimental malaria vaccines. Malaria is a disease of red blood cells caused by a parasite that spreads from person to person by mosquitoes. It affects people of all ages, but is particularly severe in children. Patients may have a high fever, chills and muscle aches. They sometimes can have severe complications that may even result in death. The vaccines in this study are called "transmission blocking" vaccines. These vaccines stimulate the person's immune system to produce antibodies against malaria. When a mosquito bites a vaccinated person, it ingests some of the person's blood. The antibodies in the ingested blood stop the malaria parasite from developing inside the mosquito. The mosquito would not be able to transmit malaria to other people. PpPfs25/ISA51 (Vaccine A) stimulates production of antibodies against the malaria parasite Plasmodium falciparum, and ScPvs25/ISA51 (Vaccine B) stimulates antibodies against the malaria parasite Plasmodium vivax. The vaccines also contain a substance called Montanide ISA51, which boosts the immune response to the vaccine. Healthy volunteers between 18 and 50 years of age may be eligible for this study. Candidates are screened with a medical history, physical examination, and blood and urine tests. Women who are able to become pregnant have a urine pregnancy test before each immunization. Participants are randomly assigned to receive two injections, spaced 4 months apart, of either Vaccine A or Vaccine B at one of three doses-high, medium, or low. Two subjects in each dose group additionally serve as "controls" and receive only Montanide ISA51 mixed with saline. The vaccine is injected into the muscle of the upper arm. Subjects are monitored for 30 minutes after each injection for possible side effects and take home a diary card to record their temperature and any symptoms that may appear over the next 13 days. A blood sample is drawn before and on several occasions after each vaccination to check the subject's health and to evaluate the immune response to the vaccine. At 1, 3, 7, 14, and 21 days after each vaccination, participants come to the clinic for a check of vital signs (temperature, pulse, respiration, and blood pressure), brief physical examination, and history of symptoms since the previous visit.
Background: Malaria is a disease caused by parasites transmitted to people by mosquitoes. Around the world, there were 241 million cases and 627,000 deaths from malaria in 2020. Researchers are working to develop vaccines and treatments for this disease. Objective: To learn how malaria develops in people; how the body s immune system reacts to malaria; and how malaria spreads from people to mosquitoes. Eligibility: Healthy people in the Washington DC area, aged 18 to 54 years. They cannot live alone during parts of the study. Design: Participants will be infected with a parasite that causes malaria. The parasite will be in donated blood; it will be given through an IV. Participants will likely develop symptoms within a week after the injection. Researchers will call daily to check on their health. After about 6 days, participants will come to the NIH clinic each day for blood tests. Participants will check in to the NIH clinic around 10 days after the injection. They will stay in the clinic 3 to 6 days. They will have multiple blood tests every day. Participants will be bitten by mosquitoes up to 4 times. Cups containing mosquitoes will be held against their skin for 15 minutes. Participants will begin taking chloroquine close to the end of their clinic stay. Chloroquine is a pill taken by mouth once or twice a day for 3 days. It is FDA-approved to treat malaria. Participants will have follow-up visits 1 and 3 weeks after discharge....
Background: Malaria is a disease carried by mosquitoes in tropical countries around the world. It can cause symptoms like fever, body aches, and weakness. More than half a million people worldwide died of malaria in 2021, mostly children. Researchers want to find ways to prevent the spread of this disease. Objective: To test the effects of a new malaria vaccine. (Volunteers will not be exposed to malaria.) Eligibility: Healthy adults aged 18 to 50 years. Design: Volunteers will be screened. They will have a physical exam with blood and urine tests. They will take a short quiz to make sure they understand the study. Volunteers will have 3 visits to receive the vaccine. These visits will be about 1 month apart. The vaccine will be injected into the muscle of the upper arm. Volunteers will have 12 additional clinic visits. These will start after the first vaccine visit and continue for 8 months. The visits may include a physical exam and blood tests. There will also be 7 follow-up phone calls. These will occur the day after each vaccine visit and then continue for another 12 months. Participants will be asked how they are doing and whether they have had any changes in their health.
Background: Malaria is caused by a parasite (a type of germ called P. vivax) that is carried by mosquitoes. The disease is transmitted to people when they are bitten by infected mosquitoes. To make drugs and vaccines for malaria, researchers need malaria-infected blood. Plasmodium vivax cell cultures are currently not cultured in vivo, and thus establishing a blood bank from P. vivax infections will be vital for future research. Objective: The goal of this study is to infect people with early-stage malaria, then collect infected blood samples to store in a cell bank for future use. Eligibility: Healthy adults ages 18-50 who will not be living alone during the study period. Design: Participants will be screened with a physical exam, heart health test, and medical history. They will have blood and urine tests. They will take a mental health survey. They must pass an exam to prove they understand the study. Participants will have red blood cells infected with P. vivax injected into an arm vein. They will be observed for side effects. They will get a thermometer to measure their temperature at home. For the next 3 days, they will be monitored via phone call or text. Starting on day 4 after the infection, they will have daily study visits to give blood samples. They will likely develop symptoms of malaria, such as fever, chills, headache, and muscle pain. Participants will be admitted to the hospital for 2-3 days when either they develop symptoms or the daily blood tests detect a certain amount of parasites. Once malaria is confirmed, a sample of their blood will be collected for the cell bank. Then they will be treated for malaria with oral medication that will cure the infection. Those who do not develop malaria will begin treatment after 15 days. Participants will have follow-up visits 28 and 90 days after infection. Participation will last for 3-5 months.
This is a first-in-humans safety, immunogenicity and efficacy study with recombinant protein VMP001, a Plasmodium vivax circumsporozoite (CS) protein based vaccine. This open label study will be performed in malaria-naïve adults in the United States. Three doses of VMP001 formulated in AS01B (adjuvant system) will be given intramuscularly at different intervals followed by a challenge with P. vivax infected mosquitoes. Safety, immunogenicity and efficacy parameters will be studied.
The investigator proposes to 2D6 (Cytochrome P-450 Isoenzyme 2D6) genotype and phenotype a group of active duty service members and assess the effects on primaquine metabolism.