17 Clinical Trials for Various Conditions
The purpose of the study is to determine how adding a carbohydrate beverage to a meal with different protein levels affects the rate at which one's body burns fats, sugars, and proteins.
This study aims to evaluate the safety and effectiveness of the BTL-785F system equipped with the BTL-785-7 applicator for non-invasive reduction of subcutaneous submental fat.
This study will evaluate the clinical safety and the performance of the BTL-785F system equipped with the BTL-785-7 applicator for non-invasive reduction of submental fat and skin laxity treatment.
This study will evaluate the clinical efficacy and performance of the BTL-899 device for changes in subcutaneous fat and muscle tissue in the lateral abdomen region (also referred to as flanks or "love handles"). The study is a prospective, multi-center, open-label, single-arm study. The subjects will be enrolled and assigned into a single study group. Subjects will be required to complete four (4) treatment visits and two follow-up visits. All of the study subjects will receive the treatment with the subject device.
This study will evaluate the safety and performance of the BTL-899 device for non-invasive treatment of subcutaneous fat. The changes in the fat tissue related to the activity of caspase-3 will be assessed histologically. The study is a prospective single-center single-blinded two-arm study. The subjects will be enrolled and assigned into two study groups; Group A which will receive active treatment and Group B which receives sham treatment and will serve as a control to verify the treatment outcomes. Subjects will be required to complete only one (1) treatment visit and three (3) follow-up visits (at 8 hours, 24 hours and 7 days post treatment). All of the study subjects will receive the treatment (either active or sham) with the subject device. At the baseline visit, health status will be assessed. Inclusion and exclusion criteria will be verified and informed consent will be signed. Punch biopsies from the treated abdominal area will be taken to examine the changes related to caspase-3 activity.
This study will evaluate the clinical efficacy and safety of a simultaneous application of high-intensity focused electromagnetic procedure and radiofrequency energy for changes in subcutaneous fat tissue and muscle toning of thighs.
This study will evaluate the clinical efficacy and safety of a simultaneous treatment by high power magnet and radiofrequency energy for toning of abdomen and reduction of subcutaneous fat. The study is a prospective multi-center single-blinded sham-controlled study. The subjects will be enrolled and assigned into two study groups; active and sham group. Subjects of both groups will be required to complete three (3) treatment visits and two to three follow-up visits.
This study will evaluate the clinical efficacy and safety of a simultaneous treatment by repetitive pulse magnetic stimulation and radiofrequency energy for toning of abdomen and reduction of subcutaneous fat. The study is a prospective multi-center open-label single-arm study. The subjects will be enrolled and assigned into a single study group. Subjects will be required to complete three (3) treatment visits and two to three follow-up visits. All of the study subjects will receive the treatment with the subject device.
The study is a prospective multi-center open-label single-arm study. The subjects will be enrolled and assigned into a single study group. Subjects will be required to complete four (4) treatment visits and four follow-up visits, 1 month, 3, 6 and 12 months after the final treatment. At the baseline visit photographs of the abdomen will be taken. In addition, patient umbilical circumference will be measured and the subject's weight will be recorded. In addition, at the last therapy visit, subjects will receive Subject Satisfaction and Therapy Comfort Questionnaires to fill in. Safety measures will include documentation of adverse events (AE) including subject's experience of pain or discomfort after the procedure. Following each treatment administration and at the follow-up visits, subjects will be checked for immediate post-procedure adverse event assessment. Post-procedure evaluation (follow-up visits) will be conducted 1 month, 3, 6 and 12 months after the final treatment. Umbilical circumference and weight measure will be conducted at every follow-up visit. Also, subject's satisfaction will be noted. During the first (1 month), third (6 months) and last (12 months) follow-up visits, photographs of abdomen will be taken.
The study is a prospective multi-center open-label single-arm study. The subjects will be enrolled and assigned into a single study group. Subjects will be required to complete four (4) treatment visits and four follow-up visits, 1 month, 3, 6 and 12 months after the final treatment. At the baseline visit, photographs of the abdomen will be taken. In addition, adipose/muscle layer thickness will be measured with the computed tomography and the subject's weight will be recorded. In addition, at the last therapy visit, subjects will receive Subject Satisfaction and Therapy Comfort Questionnaires to fill in. Safety measures will include documentation of adverse events (AE) including subject's experience of pain or discomfort after the procedure. Following each treatment administration and at the follow-up visits, subjects will be checked for immediate post-procedure adverse event assessment. Post-procedure evaluation (follow-up visits) will be conducted 1 month, 3, 6 and 12 months after the final treatment. Computed tomography and weight measure will be conducted at every follow-up visit. Also, subject's satisfaction will be noted. During the first (1 month), third (6 months) and last (12 months) follow-up visits, photographs of abdomen will be taken.
The study is a prospective multi-center open-label single-arm study. The subjects will be enrolled and assigned into a single study group. Subjects will be required to complete four (4) treatment visits and three follow-up visits, 2 months, 6 and 12 months after the final treatment. At the baseline visit photographs of the abdomen will be taken. In addition, adipose/muscle layer thickness will be measured with the magnetic resonance imaging and the subject's weight will be recorded. Safety measures will include documentation of adverse events (AE) including subject's experience of pain or discomfort after the procedure. Following each treatment administration and at the follow-up visits, subjects will be checked for immediate post-procedure adverse event assessment. In addition, at the last therapy visit, subjects will receive Subject Satisfaction and Therapy Comfort Questionnaires to fill in. Post-procedure evaluation (follow-up visits) will be conducted 2, 6 and 12 months after the final treatment. During those visits, magnetic resonance imaging, photographing and weight measure will be conducted. Subject Satisfaction Questionnaire will be given at every follow-up visit.
The study is a prospective multi-center open-label single-arm study. The subjects will be enrolled and assigned into a single study group. Subjects will be required to complete four (4) treatment visits and four follow-up visits, 1 month, 3, 6 and 12 months after the final treatment. At the baseline visit photographs of the abdomen will be taken. In addition, adipose/muscle layer thickness will be measured with the ultrasound and the subject's weight will be recorded. In addition, at the last therapy visit, subjects will receive Subject Satisfaction and Therapy Comfort Questionnaires to fill in. Safety measures will include documentation of adverse events (AE) including subject's experience of pain or discomfort after the procedure. Following each treatment administration and at the follow-up visits, subjects will be checked for immediate post-procedure adverse event assessment. Post-procedure evaluation (follow-up visits) will be conducted 1 month, 3, 6 and 12 months after the final treatment. An ultrasound imaging and weight measure will be conducted. Also, subject's satisfaction will be noted. During the first (1 month), third (6 months) and last (12 months) follow-up visits, photographs of abdomen will be taken.
Consuming a carbohydrate-rich food as the final food in a meal, as compared to the first food in a meal, has been shown to reduce blood glucose levels after eating in both diabetes patients and in healthy controls. However, gaps remain in the literature in this area of research, and currently little is known about how substrate (fuel) use is impacted by altering food order. In addition, most studies to date have used a mix of meat and plant foods, while little research has focused exclusively on vegetarian foods. This randomized experiment will examine how altering the order of foods eaten in a vegetarian meal impacts blood glucose and fuel utilization at rest.
BACKGROUND GLP1 booster (GB) was designed to stimulate the endogenous production of GLP1, which in turn releases insulin, controls blood glucose level, suppresses appetite and thus helps people lose weight. PURPOSE The purpose of this study is to assess several clinical endpoints and questionnaires in healthy volunteers taking the new GB formula. SCOPE The scope of this protocol covers the non-clinical portion as well as the assessment of several clinical endpoints and questionnaires. In brief, the non-clinical design will be an open-label study involving volunteers taking GB everyday for 12 weeks. Data analysis will involve measuring the clinical endpoints across the group at different timepoints.
The purpose of this investigation was to examine the acute effects of consuming two different fitness drink formulas on the physiological response at rest and to exercise in healthy men and women.
The trial was designed to provide empirical evidence with which to compare the efficacy and safety of the invisa-RED Technology Elite Low-level Laser Therapy (LLLT) device with a sham device as a placebo, when both are used in the treatment of individuals to reduce body fat and improve body aesthetics. At the conclusion of the trial; the change in body fat percentage, the change in total body fat in pounds, and total inches lost of the two groups were statistically analyzed to determine the efficacy of the invisa-RED Technology Elite when used for body fat (adipose tissue) loss and/or aesthetics therapy.
Insulin resistance and hyperglycemia contribute to negative outcomes in burned patients. We will assess insulin sensitivity in traditional terms of glucose metabolism, and with regard to the responsiveness of both muscle and liver protein metabolism, in severely burned patients. Plasma free fatty acid (FFA) and tissue TG levels will be manipulated via inhibition of peripheral lipolysis with nicotinic acid or activation of plasma lipoprotein lipase activity with heparin, stimulation of tissue fatty acid oxidation and thus reduction of tissue TG with the peroxisome proliferate-activated receptor (PPAR) alpha agonist fenofibrate. Methodological approaches will include stable isotope tracer techniques to quantify kinetic responses of protein, glucose and lipid metabolism in vivo, quantification of intracellular stores of TG and glycogen by means of magnetic resonance spectroscopy (MRS), as well as quantitative analysis of tissue levels of active products of fatty acids, key intermediates of the insulin signaling pathway, glycogen, the enzyme activities of citrate synthase and glycogen synthase and the activity of the muscle mitochondria. These studies will clarify the physiological and clinical significance of the alterations of tissue lipid metabolism that occur after burn injury, thereby forming the basis for new therapeutic approaches not only in this specific clinical condition but in other clinical circumstances in which hepatic and/or muscle TG is elevated. We will investigate the general hypothesis that the accumulation of intracellular TG in liver and muscle either directly causes insulin resistance in those tissues or serves as an indictor of the intracellular accumulation of active fatty acid products, such as fatty acyl CoA and diacylglycerol, which in turn disrupt insulin action. The following specific hypotheses will be investigated: 1. Intracellular TG is elevated in both muscle and liver in severely burned patients. The reduction of the fat in the liver and the insulin resistance will improve clinical outcomes, glucose and protein metabolism. 2. The insulin signaling pathway, as reflected by phosphoinositol-3-kinase (PI3K) and PKC activity, is impaired in tissues with elevated TG. 3. Fatty acids, or their active intracellular products, are the direct inhibitors of insulin action, rather than the tissue TG itself.