View clinical trials related to Human.
Filter by:Ultrasonography will be used to determine the total blood flow to and from the uterus. This is done by measuring the blood vessels coming from and going to the uterus. This wil hopefully prove viable and open the possibility to further research in the clinical relevance of these measurements.
This clinical study is prospective, single-center, randomized, controlled, double-blind clinical trail, which entitled transcranial electrical stimulation for the treatment of acute tinnitus approved by Sun Yat-sen University, and intends to recruit 86 patients with sudden deafness and tinnitus. For acute subjective tinnitus, a common otological disease, the study gave the experimental group patients received tDCS with electrodes positioned over the left temporal cortex for 5 days. To assess the efficacy of conventional medical therapy and tDCS by comparing changes in anterior and posterior tinnitus-related subjective scale scores, such as THI, VAS, BAI, BDI, PSQI, and hearing recovery, in patients who received tDCS, to determine whether tDCS is effective in improving acute tinnitus, and whether it is superior to conventional tinnitus treatment. In addition, the study will continue to follow patients for 1 month,3 months, and 6 months after the end of treatment to observe the long-term sustained efficacy of tDCS. This clinical trail will also evaluate tDCS from the perspective of compliance and safety, and explore the factors affecting the efficacy of this therapy.
Rationale: Deep brain stimulation (DBS) of the nucleus subthalamicus (STN) is an effective surgical treatment for the patients with advanced Parkinson's disease, despite optimal pharmacological treatment. However, individual improvement after DBS remains variable and 50% of patients show insufficient benefit. To date, DBS-electrode placement and settings in the highly connected STN are based on 1,5-Tesla or 3-Tesla MR-images. These low resolution and solely structural modalities are unable to visualize the multiple brain networks to this small nucleus and prevent electrode activation directed at its cortical projections. By using structural 7-Tesla MRI (7T MRI) connectivity to visualize (malfunctioning) brain networks, DBS-electrode placement and activation can be individualized. Objective: Primary objective of the study is to determine whether visualisation of cortical projections originating in the STN and the position of the DBS electrode relative to these projections using 7T MRI improves motor symptoms as measured by the disease-specific Unified Parkinson's Disease Rating Scale (UPDRS-III). Secondary outcomes are: disease related daily functioning, adverse effects, operation time, quality of life, patient satisfaction with treatment outcome and patient evaluation of treatment burden. Study design: The study will be a single center prospective observational study. Study population: Enrollment will be ongoing from April 2023. Intervention (if applicable): No intervention will be applied. Application of 7T MRI for DBS is standard care and outcome scores used will be readily accessible from the already existing advanced electronic DBS database. Main study parameters/endpoints: The primary outcome measure is the change in motor symptoms as measured by the disease-specific Unified Parkinson's Disease Rating Scale (UPDRS-III). This is measured after 6 months of DBS as part of standard care. The secondary outcome measures are the Amsterdam Linear Disability Score for functional health status, Parkinson's Disease Questionnaire 39, Starkstein apathy scale, patient satisfaction with the treatment, patient evaluation of treatment burden, operating time, hospitalization time, change of tremor medication, side effects and complications. Nature and extent of the burden and risks associated with participation, benefit and group relatedness: The proposed observational research project involves treatment options that are standard care in daily practice. The therapies will not be combined with other research products. Participation in this study constitutes negligible risk according to NFU criteria for human research.
The purpose of this clinical study is to learn about the safety, extent of the side effects (reaction to vaccine), and immune response (your immune system's reaction) of the study vaccine called Varicella Zoster Virus modRNA (VZV modRNA). We are seeking for healthy participants who are between 50 and 69 years of age. This study will be conducted in 2 substudies: Substudy A (Phase 1) and Substudy B (Phase 2). Substudy A: This substudy is the Phase 1 portion of the study. In this substudy, participants will receive 1 of 3 VZV modRNA vaccine candidates (different construct, different dose levels and different formulation [frozen or freeze dry powder]) or the approved shingles vaccine intramuscularly. Participants will be assigned in 1 of 14 groups in the study. Vaccination will be given either as a 2-dose series using one of two dosing schedules (either 2-months apart or 6-months apart), or (in one of the groups), as a single VZV modRNA vaccine at the first vaccination visit and saline at the second vaccination visit. Participants will take part in this study for 8 to 12 months depending on the group they are assigned to. Some group(s) will continue into persistence-of-immunity (overtime assessment of effect of vaccine) portion of the study. Those participants assigned to these selected groups will be involved in the study for up to 5 years. Substudy B: This substudy is the Phase 2 portion of the study. In this part of the study, participants will receive either VZV modRNA vaccine at selected dose level/schedule/formulation or approved shingles vaccine. This selection will be determined from Substudy A. Participants will be involved in this study for up to 5 years.
In-utero exposure to drugs and chemicals through maternal smoking, alcohol use, drug abuse, prescription medicines and occupational/lifestyle exposures is widespread. Such exposures can alter fetal development and programming, leading to the effects becoming "locked in" from birth and causing long-term adverse consequences for the individual. These include costly and widespread conditions such as obesity, hypertension, metabolic syndrome and infertility. The weight of evidence linking these conditions to fetal recreational drug or environmental chemical exposures, including cigarettes, alcohol, air pollution, food contact materials, is overwhelming. What is lacking is an understanding of how fetal drug exposure translates to adult ill-health and this is due, largely, to an inability to study the problem directly in affected human fetuses. The investigators, and others, have shown that human fetal development, which lays the foundations of adult health and function (fetal programming), is quite different from the rodent and frequently exhibits surprising aspects. It has become evident that the close interconnectivity of the developing fetal organs and also the placenta, means that a much more holistic approach to research aiming to understand human fetal development and the challenges posed to programming for a health adulthood is critical. To that end the investigators have established a carefully considered gestational age range (7-20 weeks of gestation) of fetuses we can study together with multiple fetal organs and body fluids collected and maternal information recorded. The overarching objective of the study is to intensively and systematically study the human fetus during a normal pregnancy and pregnancies where aspects of maternal lifestyle and environment will challenge the fetus. The investigators aim to provide fundamental information to better understand the mechanisms involved and to detect and treat or ameliorate adverse effects during pregnancy (such as maternal smoking/drinking, deprivation, exposure to pollution). In the long term findings from this research will be important for future studies aimed at enabling better health in later life.
The investigators will study the influence of initial fat cell size/number and adipose function (in particular lipolysis) on weight development over very long time periods (years). By comparing investigations of fat biopsies or blood samples obtained at baseline, the investigators will determine the association between adipose morphology/function and changes in weight or development of metabolic complications (e.g. metabolic syndrome, glucose intolerance, type 2 diabetes, dyslipidemia and hypertension).
A novel algorithm for bioimpedance measurements to detect nerve tissue, and discriminate it from other tissue types has been developed in a porcine model, by analysing a complex impedance dataset based on multiple measurement frequencies. It must now be confirm that the previous results are applicable in humans. Measurements from 24 predefined needle positions will be obtained in 16 of the 32 volunteers that are included in the study (part A). A new algorithm to detect nerve tissue will be developed based on these measurement results. Further impedance algorithms will be developed for other tissue type. The efficacy of the algorithms (sensitivity and specificity) will be evaluated in the 16 following volunteers (part B).