View clinical trials related to Healthy Volunteers.
Filter by:The purpose of this study is to evaluate the concurrent validity between the Brain Performance Test (BPT) subtests and corresponding conventional in-person neuropsychological assessments (NP).
This study is a single-centre, open-label, dose escalation , safety, tolerability and pharmacokinetics (PK) study in healthy male and female subjects. The study include a screening day and a 5-day dosing period. Subjects will be enrolled in sequential cohorts and each cohort will include 8 subjects. there will be 24 subjects total included in the study. The duration of the clinical part of the study will be approximately 2 months.
RV6153 is a new medicine being developed for possible treatment of asthma and smoking related lung disease (also known as chronic obstructive pulmonary disease - COPD). The main purpose of this study is to investigate the safety, tolerability, pharmacokinetics and pharmacodynamics of single and repeat doses of RV6153
The primary objective of the study is to assess the safety and tolerability of a single dose of subcutaneous (SC) or intravenous (IV) administered fasinumab in healthy Japanese subjects.
There are no equivalent experiment setups to create comparable changes of gravitation such as during parabolic flights. To determine the initial orthostatic responses of the cardiovascular system under the gravitational conditions of mars and moon is an essential step for a better understanding of 1) the fundamental functions of the human cardiovascular system (basic research) 2) specific impact of partial-g on the human heart, lungs and vessels in a spaceflight-context 3) approaches for countermeasure development against orthostatic intolerance on moon and mars (applied research). Non-invasive measurement methods will be used to achieve the cardiovascular key values of the study: stroke volume (SV) and cardiac output determination by pulse contour analysis, impedance cardiography and inert gas rebreathing, beat-to-beat finger blood pressure measurement, heart rate and heart rate variability determination by ECG. All of these methods have proven their accuracy during parabolic flights. Nevertheless pulse contour analysis and impedance cardiography are known to provide only relative SV and CO values. Thus inert gas rebreathing gives us the possibility to calibrate these stroke volumes and cardiac outputs to absolute values. Success of this procedure was shown during former parabolic flights.
Previous studies have neglected two important aspects for the China National Space Administration. First, while biomechanical models are very sensitive to the characteristics of the subjects, data have been collected on subjects with biomechanical characteristics very different from those of "typical" Chinese astronauts. Second, pure video analysis techniques and kinematic data lack the necessary acceleration information important to understanding the forces exerted during movement and control of human motion. While some studies used force and moment sensors to aid in robot torque control and human joint work estimation, investigators are unaware of any studies performed in a microgravity environment that have combined the kinetic force and moment information with acceleration measurements to enable more reliable motion tracking without the need for acceleration estimation. This is why MICR0-G sensors and accompanying kinematic video system have been developed in order to provide for detailed analyses of the astronaut movement control strategy (joint forces and torques, kinetic and acceleration measurements). Knowledge of the joint torques permits us to calculate the joint and musculoskeletal dynamics required to execute the microgravity motions, as well to provide insight into the altered movement strategies in reduced gravity as compared to 1-G locomotion.
Parabolic flight is the only ground-based condition in which weightlessness (0G) can be created long enough for safely testing changes in human perception and behavior. In addition to the 0G period, parabolic flight generates equal duration periods of 1.8G, which present another unique opportunity to test the same responses to hypergravity and back to 1G. Cognitive function, together with good oculomotor control, eye-hand coordination, and spatial orientation perception, is a critical subsystem that is used by the CNS in the control of vehicles and other complex systems in a high-level integrative function. Evidence from space flight research demonstrates that the function of each of these subsystems is altered by the transitions in gravito-inertial force levels. These neuro-vestibular alterations, unfortunately, correspond to mission phases where physical and cognitive performance are particularly critical for crew safety and mission success. To date, there is only limited operational evidence that these alterations cause functional impacts on mission-critical vehicle (or complex system) control capabilities. However, the true operational risks will be estimable only after the investigators have filled the knowledge gaps and when the investigators can accurately assess integrated performance in off-nominal operational settings. Accurate perception of self-in-space motion and self-motion relative to other objects are critical to piloting, driving, and remote manipulator operations. Immediately after space flight, most crewmembers have reported some degree of disorientation/perceptual illusion, often accompanied by nausea (or other symptoms of motion sickness), and frequently manifested by lack of coordination, particularly during locomotion. Despite recent, intensive training, some Shuttle landings were outside of the desired performance boundaries. Scores indicating neurovestibular dysfunction in returning astronauts generally correlated with poorer flying performances, including a lower approach and landing shorter, faster, and harder. An underestimation of distance, coupled to an overestimation of tilt magnitude or misperception of the type of motion, could be at the origin of these poorer performances. This study should confirm that the unloading of the otoliths in weightlessness induces an alteration in the egocentric reference during space flight. Errors in egocentric localization might contribute at a higher level to the computation of misleading world-centered representations, and therefore be partly responsible for illusory sensations and motion sickness symptoms during space flight, and postural instability and oscillopsia after returning in a reduced or terrestrial gravitational force level. Beside their fundamental implications, the results of this study have also practical implications in the design of man-machine interfaces. Changes in judgment of distance in microgravity or in reduced gravity affect crew posture and reach, display orientation, and other visual cues, which should be considered in hardware and operations design.
The purpose of this study is to determine the relative bioavailability of alogliptin 12.5 milligram (mg) and immediate-release metformin 1000 mg when administered as individual tablets and as a fixed-dose combination (FDC) product.
The main goal of the study is demonstrate that e-Nose system function is not altered in weightlessness and more specifically that gas concentration measurements are the same in weightlessness and normal gravity.
Background: - People with dystonia have muscle contractions they can t control. These cause slow, repeated motions or abnormal postures. People with dystonia have abnormalities in certain parts of the brain. Researchers want to study the activity of two different brain areas in people with writer s cramp and cervical dystonia. Objective: - To compare brain activity in people with dystonia to that in healthy people. Eligibility: - Right-handed people ages of 18-65 with cervical dystonia or writer s cramp. - Healthy volunteers the same ages. Design: - Participants will be screened with a physical exam. They will answer questions about being right- or left-handed. - At study visit 1, participants will:<TAB> - Have a neurological exam. - Answer questions about how their disease impacts their daily activities. - Have a structural magnetic resonance imaging (MRI) scan. Participants will lie on a table that can slide <TAB>in and out of a metal cylinder. This is surrounded by a strong magnetic field. - Do 2 simple computer tasks. - At study visit 2: - Participants will have transcranial magnetic stimulations (TMS) at 2 places on the head. Two wire coils will be held on the scalp. A brief electrical current creates a magnetic pulse that affects brain activity. Muscles of the face, arm, or leg might twitch. Participants may have to tense certain muscles or do simple tasks during TMS. They may be asked to rate any discomfort caused by TMS. - Muscle activity in the right hand will be recorded by electrodes stuck to the skin of that hand.