View clinical trials related to Insulin Resistance.
Filter by:Hyperglycemia is a major risk factor for the micro- and macro-vascular complications of diabetes . Lowering blood glucose levels has been shown to reduce the incidence of diabetes complications. Therefore, there is a need for a simple surrogate biochemical marker for glycemic variability. Glycated hemoglobin (HbA1c) is the standard clinical measurement used to monitor glycemic status and is recommended to assess control of diabetes over the preceding 2-3 months. However, being a measure of mean glucose, it does not reflect glucose variability. It is well known that insulin secretion defects of islet β cells and/or tissue insensitivity to insulin are common pathophysiological mechanisms of diabetes mellitus (DM) . The elevation in the blood glucose level usually represents the degree of glucose metabolism disorder, which is generally assessed by glycated hemoglobin A1c ( HbA1c) and indirectly reflects the extent of β-cell function damage . In the recent years, 1,5-anhydroglucitol (1,5-AG) has received attention as a short-term blood glucose index that reflects the average blood glucose level 1,5 AG reflects the average maximum blood glucose level during the past 1-2 weeks and is reported to be a more sensitive marker of glucose variability and postprandial hyperglycemia than HbA1c, even for patients with prediabetes and for those with well or moderately controlled diabetes . (1,5 AG ) is structurally similar to glucose . Due to this similarity, glucose inhibits renal reabsorption of 1,5 AG by competitive inhibition ,resulting in an inverse correlation of 1,5 AG with hyperglycemia . 1,5-AG levels are acting as an effective supplement to HbA1c. Additionally, previous study showed that 1,5-AG and HbA1c had opposite curves with increasing blood glucose levels; specifically, with the increase in HbA1c levels, 1,5-AG levels decreased significantly . Therefore, we speculate a ratio of 1,5- AG / HB A1C in relation to islet β-cell function and insulin resistance. The aim of our study was to evaluate the role of 1,5 anhydroglucitol and 1,5 anhydroglucitol / HbA1c ratio as a potential biomarker for islet β-cell function and insulin resistance among patients with type 2 diabetes .
In this study, we investigate the impact of insulin resistance on the acceleration of brain aging, and test whether increased neuron insulin resistance can be counteracted by utilization of alternate metabolic pathways (e.g., ketones rather than glucose). This study has three Arms, which together provide synergistic data. For all three Arms, subjects are tested in a within-subjects design that consists of 2-3 testing sessions, 1-14 days apart, and counter-balanced for order. During each session we measure the impact of fuel (glucose in one session, ketones in the other) on brain metabolism and associated functioning. For Arms 1-2, our primary experimental measure is functional magnetic resonance imaging (fMRI), which we will use to trace the self-organization of functional networks following changes in energy supply and demand. Arm 1 tests the impact of endogenous ketones produced by switching to a low carbohydrate diet, while Arm 2 tests the impact of exogenous ketones consumed as a nutritional supplement. For Arm 3, we use simultaneous magnetic resonance spectroscopy/positron-emission tomography (MR/PET) to quantify the impact of exogenous ketones on production of glutamate and GABA, key neurotransmitters. Subjects will be given the option to participate in more than one of the Arms, but doing so is not expected nor required. Prior to scans, subjects will receive a clinician-administered History and Physical (H&P), which includes vital signs, an oral glucose tolerance test (OGTT), and the comprehensive metabolic blood panel. These will be used to assess diabetes, kidney disease, and electrolytes. If subjects pass screening, they will be provided the option to participate in one or more Arms, which include neuroimaging. To provide a quantitative measure of time-varying metabolic activity throughout the scan, based upon quantitative models of glucose and ketone regulation, as well as to be able to implement safety stopping rules (see below), we will obtain pin-prick blood samples three times: prior to the scan, following consumption of the glucose or ketone drink, and following completion of the scan. To assess effects of increased metabolic demand, we measure brain response to cognitive load, transitioning from resting-state to spatial reasoning through a Tetris task. To assess effects of increased metabolic supply, we measure brain response to glucose or ketone bolus.
Arterial disease is the leading cause of morbidity/mortality in Metabolic syndrome (MetS). This occurs early as evidenced by arterial dysfunction that, in turn, raises blood pressure and glucose. Health organizations recommend exercise in an intensity based manner to promote cardiovascular adaptation and prevent disease. Metformin is a common anti-diabetes medication that reduces future type 2 diabetes and cardiovascular risk. However, the optimal exercise dose to be combined with metformin for additive effects on vascular function is unknown. Based on the investigator's preliminary work, the overall hypothesis is that metformin blunts adaptation following high intensity exercise training (HiEx) by lowering mitochondrial derived oxidative stress signaling. The investigators further hypothesize that low intensity exercise (LoEx) training combined with metformin will promote additive effects on vascular function compared to LoEx or HiEx+metformin, and maintain/improve non-exercise physical activity patterns. In this double-blind trial, obese 30-60y MetS participants will be randomized to: 1) LoEx+placebo; 2) LoEx+metformin, 3) HiEx+placebo; or 4) HiEx+metformin for 16 weeks.
Epidemiological studies show a very rapid increase in the epidemic of obesity in the Caribbean population. 6 out of 10 adults are overweight and 1 out of 4 is obese. Most are women. Consequences : harm to health and possible reduction in life expectancy due to the association with many cardiovascular comorbidities. Adverse effects of obesity on the cardiovascular and endocrine systems are attributed a chronic low-grade inflammatory state in obese patients. Visceral adipose tissue is largely responsible for the inflammatory syndrome. Obesity can also induce the formation of multi-protein platforms called inflammasomes also activated by mitochondrial production. Morbid obesity treatment with sleeve gastrectomy is an effective long term therapeutic for weight loss but also beneficial in terms of insulin resistance and cardiovascular complications. Some patients nevertheless remain resistant to the beneficial cardio-metabolic effects of bariatric surgery. However, the mechanisms that regulate the extent of weight loss and its stabilization after bariatric surgery are still poorly understood. Our study aims to describe the evolution of postoperative weight loss and the place of preoperative inflammation in its amplitude. The hypothesis is that the level of inflammation in visceral fat before surgery determines the extent of postoperative weight loss in obese women who have undergone sleeve gastrectomy.
Participants will be randomized into one of two different experimental groups: 1) Exercise group and 2) No exercise (control group). Subject participation in the study will involve a series of metabolic tests before and after participants undergo a 10% weight loss program (with or without exercise training depending on group randomization). After completing this weight loss portion of the study, participants will then be required to adhere to a high calorie diet program to regain half of the weight the participant lost - followed by the same series of metabolic tests.
The goal of this two-site grant proposal is to determine the role of the decreased insulin-mediated muscle perfusion found in type 2 diabetes in contributing to the development of cardiac and skeletal muscle dysfunction and subsequent functional exercise impairment. In addition, it is also our goal to determine whether exercise training attenuates insulin resistance and restores insulin-mediated perfusion to the heart and to skeletal muscle, leading to improved cardiac function and exercise performance.
The overall aim of this pilot study is to investigate the effects of exercise training on skeletal muscle and adipose tissue insulin resistance in subjects with Type 2 Diabetes (T2D).
this study will be carried to investigate the effect of cryolipolysis and high intensity interval training on insulin resistance and body composition in pco women
The main purpose of research is to examine and understanding the development of hypertension in obese adults with insulin resistance. Findings from our studies will identify unique mechanisms that can be targeted to limit increases in vascular dysfunction and reduce the excessively high prevalence of hypertension and risk for cardiovascular disease (CVD). This study is testing the health of the blood vessels and the activity of the nerves that control the blood vessels in adults with insulin resistance. The extent to which ascorbic acid (Vitamin C) improves the function of the blood vessels will be determined. The primary outcome is blood pressure, which is the result of blood vessel health and activity of the nerves, and the reduction in blood pressure that is observed with ascorbic acid.
This study will test the effect of four common oral anti-diabetic agents on hepatic insulin sensitivity in South Asian women with impaired glucose tolerance or impaired fasting glucose. In a 12-week, double-blind, randomized controlled intervention trial, the following drugs will be tested head-to-head: Metformin, Pioglitazone, Empagliflozin and Linagliptin. Additional, exploratory outcomes include whole body insulin sensitivity, insulin secretion and other markers of glucose and lipid metabolism, measured by the euglycemic clamp with stable isotope tracer dilution, indirect calorimetry and CT-measurements of abdominal adipose tissue compartment volumes and hepatic and pancreatic volume and attenuation. The study is part of the DIASA - DIAbetes in South Asians - Research Programme, which aims to find ways to improve both prevention and treatment of type 2 diabetes in people of South Asian ethnicity.