Active clinical trials for "Insulin Resistance"

The goals of this research study are to: 1) understand why some people with obesity are protected from developing conditions such as type 2 diabetes and cardiovascular disease while others are more likely to develop obesity-related conditions; 2) assess the effect of small extracellular vesicles (sEVs also called exosomes), obtained from human participants, on metabolic function in cultured cells and in mice.

Study Purpose: The combination of caloric restriction and exercise is the most common first-line treatment for obesity-related disorders, yet we know very little about how these two very different treatments work together. A deeper understanding about mechanisms underlying the health benefits of adding exercise to a weight loss program will not only aid efforts to optimize more effective lifestyle interventions, but it can also uncover novel targets for the treatment/prevention of obesity-related diseases. Although a reduction in body fat is the fundamental adaptation to weight loss, we know almost nothing about the effects that adding exercise has on structural and functional changes within fat tissue that may further enhance metabolic health. This is very important because many obesity-related metabolic health complications are tightly linked with abnormalities in abdominal fat tissue. We argue exercise-induced modifications in abdominal fat tissue will reveal persistent health benefits even if some weight is regained Study Summary: 10% Weight Loss Phase - Subject participation in the study will involve a series of metabolic tests before, at midpoint, and after undergoing a 10% weight loss program (with or without exercise training depending on group randomization). During this, subjects will be randomized into one of two different experimental groups: Moderate Intensity Continuous Training (MICT) exercise group No exercise (control) group Follow-up Phase: After completing the metabolic testing post-weight loss, all study-related diet and exercise supervision will end and subjects will be free to make their own choices regarding diet and exercise/physical activity behavior. Subjects will then be asked to complete follow-up testing at 2-, 4- and 6- months post-weight loss. Total involvement in the study for each subject will likely be about 10-13 months (4-7 months during weight loss phase, 6 months during follow-up phase).

It's a randomized control trial to compare the effect of preoperative carbohydrate loading versus fasting on post operative insulin resistance after donor hepatectomy in terms of donor outcomes. Investigator will analyze the data and elucidate the value of post operative insulin resistance in reducing the occurrence of complications, length of hospital stay and fastening the recovery in donors of Live donor liver transplantation.

Obesity if known to be associated with brain insulin resistance in humans. This condition has not only implication for the brain but also for whole-body energy homeostasis. Research in rodents indicates that weight loss is able to improve insulin sensitivity of the brain. The current project will test this hypothesis in humans. Therefore, brain insulin sensitivity will be assessed by fMRI in combination with intranasal insulin administration, using an established protocol. Furthermore, effects of daily administration of insulin nasal spray (versus placebo) over 8 weeks will be assessed as secondary (exploratory) variables.

This proposal will investigate the underlying mechanisms of enhanced insulin sensitivity and improvement of muscle loss and performance in insulin resistant people by resistance exercise training. Based on the investigator's preliminary data, they hypothesize that the key regulators of health benefits of resistance training are two genes: PGC-1a4 and PPARB;, and that the increased expression of these genes following resistance training facilitates storage of glucose in muscle and enhances its utilization for the energy need of muscle for contraction as well as enhancing muscle mass and performance. The investigators will also determine whether resistance training can reduce the higher oxidative stress in insulin resistant humans and improve their muscle protein quality.

The purpose of this study is to study the role of sympathetic mechanisms involved in chronic regulation of cardiovascular and metabolic abnormalities seen in obesity. The investigators will study the effects chronic sympathetic inhibition on insulin sensitivity, inflammation and endothelial function in obese hypertensive human subjects.

Muscle insulin resistance is a hallmark of upper body obesity (UBO) and Type 2 diabetes (T2DM). It is unknown whether muscle free fatty acid (FFA) availability or intramyocellular fatty acid trafficking is responsible for muscle insulin resistance, although it has been shown that raising FFA with Intralipid can cause muscle insulin resistance within 4 hours. The investigators do not understand to what extent the incorporation of FFA into ceramides or diacylglycerols (DG) affect insulin signaling and muscle glucose uptake. The investigators propose to alter the profile and concentrations of FFA of healthy, non-obese adults using an overnight, intra-duodenal palm oil infusion vs. an overnight intra-duodenal Intralipid infusion (both compared to saline control). The investigators will compare the muscle FFA storage into intramyocellular triglyceride, intramyocellular fatty acid trafficking, activation of the insulin signaling pathway and glucose disposal rates, providing the first measure of how different FFA profiles alter muscle FFA trafficking and insulin action at the whole body and cellular/molecular levels. By identifying which steps in the insulin signaling pathway are most affected, the investigators will determine the site-specific effect of ceramides and/or DG on different degrees of insulin resistance. Hypothesis 1: Palm oil infusion will result in abnormal FFA trafficking into intra-myocellular ceramides and abnormal insulin signaling. Hypothesis 2: Intralipid infusion will result in abnormal FFA trafficking into intra-myocellular saturated DG and abnormal insulin signaling.

PURPOSE: to determine the effect of interval training on sex hormones, metabolic and tumor markers BACKGROUND: Cancer is one of death top causes in many countries1. In Egypt for example, cancer incidence is 157.0 per 100 000 women with probability increasing up to three-fold by 2050 especially in older adult women2. Who exhibit multiple factors leading to cancer including but not limited to physical inactivity and postmenopausal obesity which considered the starting point of developing insulin resistance3. High blood insulin level stimulates cancer progression by enhancing cell proliferation, decreasing cells apoptosis, increased level of fatty acids in conjunction with higher tumor cell formation capacity invasion and survival4. Moreover, high level of insulin resistance and adipose tissue increase the hormonal level of estradiol and testosterone coupled with lower SHBG level. It was noticed that being postmenopausal women with high adipose tissue content will increase the risk of having cancer in which adipose tissue is considered as the main source of steroids hormones that functioning in a different way rather than in premenopausal age. Based on the mentioned underlying conditions, postmenopausal women subjected to have variable types of cancer such as breast, endometrial, stomach, etc6. So, regular screening of cancer incidence especially in high-risk women through tumor indicators is necessitated to work against further cancer progression. CEA and CA125 are low-cost tumor blood biomarkers used widely for early cancer identification, recurrence monitoring and follow up which linked to proinflammatory cytokines production . HYPOTHESES: may have no effect to interval training on sex hormones , metabolic and tumor markers in postmenopausal women RESEARCH QUESTION: Is there effect to interval training on sex hormones , metabolic and tumor markers in postmenopausal women?

In this study, the drug Akkermania muciniphila has been proved to play an important role in the occurrence and development of obesity related metabolic diseases. The purpose of this study was to evaluate the safety and efficacy of AKK in the treatment of insulin resistance related obesity. In this study, a single center, randomized, double-blind, placebo-controlled design was adopted. 120 patients with obesity related to insulin resistance were included in this study, and were allocated to live bacteria high-dose group, live bacteria low-dose group, and placebo group at a ratio of 1:1:1. The study lasted for 12 weeks. The changes of body fat, glucose metabolism, lipid metabolism indicators, and fatty liver changes compared with the baseline at the end of the treatment were analyzed. In addition, glucagon like peptide-1 (GLP-1) in plasma and inflammatory markers (hsCRP, TNF) in blood will be analyzed before and after treatment- α、 IL-6、IL-8、IL-1 β） Level, plasma LPS level, oxygen/hydrogen/methane level in methane hydrogen breath test, changes in fecal flora structure, and the mechanism of AKK bacteria affecting insulin resistance by analyzing bacterial metabonomics molecular spectrum in plasma and urine.

The goal of this clinical trial is to compare a two-week course of diazoxide (at two different doses) and placebo in people with overweight/obesity and insulin resistance (IR) with, or at high risk for, non-alcoholic fatty liver disease (NAFLD). The main questions it aims to answer are how mitigation of compensatory hyperinsulinemia with diazoxide affects parameters of glucose and lipid metabolism (how people with IR and NAFLD respond to lowering high insulin levels so that the investigators can see what happens to how the liver handles fat and sugar). Participants will: Take 27 doses of diazoxide (at 1 mg per kg of body weight per dose [mpk] or 2 mpk) or of placebo, over 14 days Take 32 doses of heavy (deuterated) water (50 mL each) over 14 days Have blood drawn and saliva collected after an overnight fast on four mornings over the two-week study period Consume their total calculated daily caloric needs as divided into three meals per day Wear a continuous glucose monitor for the two-week study period Researchers will compare fasting blood tests at intervals during the study period in participants randomized (like the flip of a coin) to diazoxide 1 mpk, diazoxide 2 mpk, or placebo, to see how the drug treatment affects plasma glucose, serum insulin, and serum lipid parameters (triglycerides, free fatty acids, and apolipoprotein B). They will also consume heavy (deuterated) water to assess de novo lipogenesis (building of new fatty acids by the liver).