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Polio clinical trials

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NCT ID: NCT06162104 Completed - Fatigue Clinical Trials

Evaluation of Fatigue Severity, Mood, and Quality of Life in Post-Polio Syndrome

Start date: December 1, 2023
Phase:
Study type: Observational [Patient Registry]

The aim of this study is to investigate the differences in the severity of fatigue, impact on quality of life, and mood between individuals with post-polio syndrome and healthy volunteer groups. Additionally, the interrelationships of these parameters within the post-polio syndrome patient group will be examined. The goal is to raise awareness during the follow-up process for individuals with post-polio syndrome by questioning fatigue and mood symptoms, and to facilitate the implementation of necessary precautions.

NCT ID: NCT05721274 Completed - Polio Clinical Trials

Community Engagement and Conditional Incentives to Accelerate Polio

GLIDE
Start date: December 1, 2022
Phase: N/A
Study type: Interventional

Immunization is one of the most cost-effective and successful public health strategy in reducing the health, economic and societal burden of many infectious diseases. Pakistan and Afghanistan remain the only countries where polio is endemic, and Pakistan reports the most cases in the world. Although the rate is lower than in previous years, the situation remains alarming. This study objective is to decrease polio vaccine refusals and zero-dose vaccines by motivating behaviour change

NCT ID: NCT05083039 Completed - Clinical trials for Coronavirus Infections

Observational Program, Study the Preventive Efficacy of the BiVac Polio Vaccine Against the Incidence of Acute Respiratory Infections, Including COVID-19

Start date: May 14, 2020
Phase:
Study type: Observational

Observational program, double-blind, placebo-controlled to study the preventive efficacy of the BiVac polio (Oral polio vaccine, divalent, live attenuated of types 1 and 3 vaccine against the incidence of acute respiratory infections, including COVID-19

NCT ID: NCT04576910 Completed - Vaccine Reaction Clinical Trials

Immunogenicity and Safety of the Booster Dose of Polio Vaccine With Different Primary Sequential Schedules in China

Start date: November 5, 2020
Phase: Phase 4
Study type: Interventional

This study is to evaluate the immunogenicity and safety of Sabin IPV or bOPV, given as a booster vaccination in children aged 4 years who were previously immunised with different sequential immunization history by Sabin IPV and bOPV, and to observe the antibody persistence three years after different primary sequential immunization with Sabin IPV or bOPV at age 2, 3 and 4 months.

NCT ID: NCT04264598 Completed - Polio Clinical Trials

Safety and Immunogenicity of a Sabin Inactivated Poliovirus Vaccine

Start date: August 21, 2017
Phase: Phase 1
Study type: Interventional

The purpose of this phase I study is to evaluate the safety of a Sabin Inactivated Poliovirus Vaccine (sIPV) in adults and children, and the safety and immunogenicity of it in infants. 20 adults aged 18~45 years and 20 children aged 4 years were only administered one dose of sIPV with medium D antigen content. 60 infants aged 2 months (60~90 days) were randomized to receive three doses of sIPV with medium D antigen content, conventional IPV (cIPV, manufactured by Sanofi Pasteur) or sIPV (manufactured by the Institute of Medical Biology, the Chinese Academy of Medical Biology), respectively, on the month 0, 1, 2 schedule. Serum samples were collected before the 1st dose and 30 days after the 3rd dose vaccination to assess the immunogenicity in infants. Adverse events occurring within 30 days after each dose were collected to assess the safety.

NCT ID: NCT04264546 Completed - Polio Clinical Trials

Safety and Immunogenicity of a Sabin Inactivated Poliovirus Vaccine (Phase Ib)

Start date: November 24, 2017
Phase: Phase 1/Phase 2
Study type: Interventional

The purpose of this phase Ib study is to evaluate the safety of a Sabin Inactivated Poliovirus Vaccine (sIPV) in adults and children, and the safety and immunogenicity of it in infants. 20 adults aged 18~45 years and 20 children aged 4 years were only administered one dose of sIPV with high D antigen content. 20 infants aged 2 months (60~90 days) were administered three doses of sIPV with high D antigen content, on the month 0, 1, 2 schedule. Serum samples were collected before the 1st dose and 30 days after the 3rd dose vaccination to assess the immunogenicity in infants. Adverse events occurring within 30 days after each dose were collected to assess the safety.

NCT ID: NCT04232943 Completed - Polio Clinical Trials

Inactivated Poliovirus Vaccine (IPV) With or Without E.Coli Double Mutant Heat-Labile Toxin (dmLT) Challenge Study in Healthy Adults

Start date: January 22, 2020
Phase: Phase 1
Study type: Interventional

In this study, the safety and tolerability of inactivated polio vaccine (IPV) co-administered with dmLT will be assessed, as well as whether co-administration of dmLT with IPV enhances mucosal responses compared to those with IPV alone.

NCT ID: NCT04177485 Completed - Hepatitis B Clinical Trials

Evaluating a Caregiver SMS Reminder Intervention to Reduce Immunization Drop-out in Arua, Uganda

Start date: February 1, 2016
Phase: N/A
Study type: Interventional

Faced with high rates of immunization drop-out, Uganda's immunization program requires innovative approaches to address this weakness. Building upon Uganda's growing mHealth infrastructure to pilot a scalable short message service (SMS) system to remind caregivers of their children's upcoming vaccination visits, it was hypothesized that the SMS intervention will increase immunization coverage in a cost-effective and affordable manner that would make it scalable. The study design was an investigator-blinded, multi-center, parallel groups randomized controlled trial with randomization occurring at the caregiver level in select health facilities of Arua District in Uganda. Enrollment took place at the time of Pentavalent 1 vaccination, and both arms included standard of care provided by the health worker. However, in the intervention arm, caregivers also received SMS text messages reminding them to return for their children's second and third doses of Pentavalent vaccine (four and eight weeks after the first dose of Pentavalent vaccine) and measles-containing vaccine (9 months of age). The primary outcome of interest is vaccination coverage at 12 months of age among children enrolled in the study and will be measured by comparing Penta3 and MCV coverage between arms. The study will also examine the SMS impact on timeliness of vaccine receipt, as it is hypothesized that those children receiving the SMS intervention will be more likely to have timely vaccination than those in the control group. The study will also assess caregiver acceptability and cost-effectiveness of the SMS intervention. In addition to assessing its impact on strengthening the immunization program, this intervention has implications for strengthening other programs of the health system through similar health messaging directed toward caregivers.

NCT ID: NCT04027036 Completed - Polio Clinical Trials

Comparison of Immunogenicity of Inactivated Poliovirus Vaccine (IPV) Administered Intramuscularly or Intradermally

Start date: August 6, 2020
Phase: Phase 2
Study type: Interventional

Polio is an acute transmissible disease caused by any of the three polio virus serotypes (types 1, 2 or 3). In Mozambique, polio vaccination is part of the immunization schedule of the expanded vaccination program. The oral vaccine (OPV) is administered at months 0,2,3, and 4 and a single dose of the inactivated poliovirus vaccine (IPV) is given intramuscularly at month 4. In 2016 shortage of IPV supply caused stock-outs and put strain on IPV use for routine immunizations as well as for poliovirus outbreak response. Therefore, assessment of new vaccine regimens using smaller doses of IPV are needed. Administration of fractionated IPV (fIPV), i.e., 1/5 (0.1mL) of the standard dose, intradermally has shown to be safe and to provide an immune response similar to the standard dose of IPV that is currently given intramuscularly. However, intradermal administration of fIPV is technically difficult and many countries are hesitant to adopt fIPV in their routine immunization schedules. Therefore, the investigators need data confirming that the use of the fIPV vaccine intramuscularly is safe and the immune response is not inferior to the use of fIPV intradermally. Study Objective: to compare the immunogenicity of fIPV administered intramuscularly or intradermally in infants at 2 and 4 months of age. Study Hypotheses: the seroconversion rate after administration of one or two doses of fIPV intramuscularly is not inferior to the fIPV intradermally. The priming effect after fIPV administered intramuscularly is not inferior to the fIPV intradermally. Study Methods: This will be a phase II non-inferiority clinical trial. 360 children will be enrolled in two study groups, with prior consent of the parents / guardians. In group I, 180 children will receive 0.1 ml of IPV intramuscularly and in group II 180 children will receive the same dose intradermally. There will not be a group control. The children will be selected at birth at pre-defined health units in Maputo city. The fractional IPV vaccine will be given to children at 2 and 4 months of age during routine vaccinations. In total there will be four study visits, of which the first two are vaccination visits. All visits will be performed at the health units. 1 ml of blood will be collected at each study visit to assess the immune response before and after vaccination. Data will be collected by trained and qualified personnel and in accordance with Good Clinical Practice standards. Adverse events following administration of the vaccine will be monitored and all serious adverse events will be reported to ethics and regulatory committees, and to World Health Organization (WHO). Evaluation of the immune response: Seroconversion rates and priming effect will be evaluated. Serum will be tested for the presence of neutralizing antibodies against poliovirus using standard neutralization assays and immunogenicity will be assessed by titration of anti-polio 2 immunoglobulin G.

NCT ID: NCT03922061 Completed - Polio Clinical Trials

Evaluation of Safety, Reactogenicity and Immunogenicity of Fractional-dose Inactivated Polio Vaccine (fIPV) Given Intradermally With Double Mutant Enterotoxigenic Escherichia Coli Heat Labile Toxin (dmLT) Adjuvant

Start date: March 19, 2019
Phase: Phase 1
Study type: Interventional

Polio is a serious disease that can cause paralysis and death. It is caused by a virus and can be prevented by vaccine. The World Health Organization's (WHO) Global Polio Eradication Initiative is trying to get rid of all polio disease around the world. Researchers want to help by testing a new vaccine. In many countries, people are vaccinated with oral polio vaccine (OPV) given by mouth during childhood. OPV is good at giving immunity (protection from polio) in the body and the gastrointestinal (GI) tract. Immunity in the GI tract is called mucosal immunity. The downsides of using OPV are that it can be shed into the environment in people's feces after vaccination where it can infect people who are not vaccinated, and it can cause paralysis in 2-4 of every one million children vaccinated with OPV. The United States (U.S.) stopped giving any OPV to people for vaccinations in the 1990's. Since then, a polio vaccine called inactivated polio vaccine (IPV) is given as an injection for routine childhood immunizations in the U.S. You cannot get polio infection from IPV and it will not be shed into the environment. In 2016, the WHO started a plan to help other countries gradually get rid of OPV. The downside of using IPV by itself is that, unlike OPV, it doesn't give enough mucosal immunity to protect people living in places where there is still polio. There are also supply shortages of IPV, which is a problem if there are outbreaks of polio. For the supply of IPV to help more people, it is safe and effective to use a tiny dose of IPV injected under the top layer of skin (intradermal or ID injection) rather than getting the full dose in the muscle. This is called a fractional dose of IPV, or fIPV. To help stop using OPV globally, a better fIPV vaccine is needed. fIPV vaccine needs a substance to help stimulate a mucosal immune response. dmLT is a substance that has been shown to stimulate a mucosal immune response. It has been shown to be safe and effective in both humans and animals, both by itself and when given with other vaccines. This study will test a mixture of fIPV-dmLT given intradermally (under the outer layer of the skin). This is the first study done in humans to give this combination intradermally. The IPV vaccine has already been approved by the FDA. The fIPV-dmLT vaccine has not been approved by the FDA.