View clinical trials related to Insulin Resistance.
Filter by:The primary aim of this study is to evaluate if a single bout of AM vs PM resistance exercise has different effects on insulin sensitivity and sleep. A randomized cross-over trial be used to compare resistance exercise at two different times of the day. Each condition will take place in a laboratory setting. Each condition will consist of exercise, overnight sleep, and oral glucose tolerance tests the following day. The AM exercise will occur ~1.5 hours after habitual wake, and PM exercise will occur ~11 hours after habitual wake. After a 2-6 week washout, participants will complete the other condition. The hypothesis is that PM exercise will be more beneficial than AM exercise in improving insulin sensitivity. This study could identify if there is a better time of day to perform resistance exercise to decrease risk of developing Type 2 Diabetes Mellitus.
The goal of this clinical trial is to understand how the blood sugar-lowering hormone insulin works in healthy adults versus those who are at risk for type 2 diabetes. The study will use a drug called alpelisib, which interferes with insulin's actions in the body, to answer the study's main question: does the liver continue to respond to insulin's stimulation of fat production even when it loses the ability to stop making glucose (sugar) in response to insulin. Researchers will compare the impact of single doses of both alpelisib and placebo (inert non-drug) in random order (like flipping a coin) in study participants. Participants will be asked to stay twice overnight in the hospital, take single doses of alpelisib and placebo (one or the other on each of the two hospital stays), and receive intravenous (into the vein) infusions of non-radioactive "tracer" molecules that allow researchers to measure the production of glucose (sugar) and fats by the liver. Measurements will be done both overnight, while participants are asleep and fasting (not eating or drinking other than water) and while consuming a standardized diet of nutritional beverages during the following day. The objective is to evaluate the effect of lowering insulin levels, while maintaining constant mild hyperglycemia, on plasma glucose and lipid levels.
The aim of this study was to determine the effect of intravenous infusion of 5% dextrose injection during the recovery period of anesthesia for painless gastroenteroscopy on the patient's blood glucose level, incidence of hypoglycemia and time of awakening from anesthesia, postoperative vertigo, postoperative nausea and vomiting, and quality of recovery in the early postoperative period.
To determine the efficacy and safety of 2 different treatment modalities: 1) acupuncture plus lifestyle management (treatment group), 2) placebo plus lifestyle management (control group) in the treatment of insulin resistance in PCOS patients.
This double-blinded proof-of-concept study is proposed to explore the effects of fecal microbiota transfer (FMT) in human subjects. Here we perform FMTs into obese recipients using stool from lean unoperated donors and from previously obese patients after successfull treatment with bariatric Roux-en-Y Gastric Bypass (RYGB) surgery. Obese patients treated with their own material (autologous FMT) serve as controls. After FMT treatment the functional impact of post-surgery microbiome changes on host energy consumption and regulation of blood glucose levels will be analysed. Additionally the variations on the microbiota and metabolite composition will be profiled using extensive sequencing analyses. The major aim of the study is to explore the scientific rationale for targeted gut microbiota modulation in management of obesity and related metabolic diseases.We estimate the transfer of microbiota from RYGB donors is superior to the transfer of lean microbiota at inducing reduced adiposity and improving high blood glucose levels in obese recipients. Each is better than a sham procedure (autologous FMT), which itself can also induce considerable short-term effects.
Females treated with antipsychotics have higher rates of comorbid metabolic syndrome than males. Despite this, females have historically been excluded from many mechanistic studies due to confounding effects of menstrual cycles. Recent evidence suggests that brain insulin resistance may be an underlying mechanism through which antipsychotics may exert their metabolic side effects. This study seeks to investigate how brain insulin action differs in females according to their menstrual cycle phase, and how a high metabolic liability agent such as olanzapine might interrupt these differential insulin effects. Young healthy females will be given olanzapine and intranasal insulin to test how these treatment combinations change brain processes. Participants will be tested during both the first half of their menstrual cycle (follicular phase) and the second half of their cycle (luteal phase). We predict that intranasal insulin will change MRI-based measures in females, in a comparable way to males, in the follicular phase only. Adding olanzapine will block these effects of insulin in females in the follicular phase. This investigation has the potential to generate new knowledge in an area of significant unmet need. Demonstrating that antipsychotics disrupt brain insulin action, evidenced by inhibition of recognized effects of insulin on neuroimaging measures, will provide novel insights into currently poorly understood mechanisms.
The goal of this study is to collect more information from people with plaque psoriasis and to determine if insulin plays a role in the pathogenesis of psoriasis. The main question it aims to answer is if insulin action is preserved or even enhanced in psoriatic lesions despite insulin resistance elsewhere. Participants with plaque psoriasis will have punch biopsies taken of lesional and non-lesional skin after an overnight fast and then during an oral glucose tolerance test. Biopsy specimens will then be assessed for markers of insulin action.
A combination of generally regarded as safe (GRAS) compounds named GLY-LOW, which included: alpha lipoic acid, pyridoxamine, nicotinamide, piperine and thiamine, were examined in pre-clinical experiments. GLY-LOW supplementation reduced caloric intake and increased insulin sensitivity in mice. In female mice, GLY-LOW supplementation reversed aging-related declines in female hormones. Studies in humans are needed to examine the feasibility, utility and efficacy of GLY-LOW supplementation in post-menopausal women with obesity toward improving aging-related impairments. The effect of GLY-LOW supplementation on these obesity and biological age-related impairments in post-menopausal adult female humans with obesity is unknown. We aim to translate the findings of GLY-LOW supplementation in animals to a cohort of healthy, postmenopausal females at birth with obesity by conducting a one-group, no-placebo comparer, pre post intervention clinical trial. Additionally, we propose to examine the specific effect of supplementation by GLY-LOW on biological aging via retina scan. The objectives of the proposed pilot study are: I. Conduct a 6-month pilot study to examine the feasibility, utility and efficacy of GLY-LOW supplementation in a total of 40 postmenopausal female born adults > 55 years with obesity (> 30 BMI) Ia. Examine alterations in self-reported caloric intake and the following health and biological aging, parameters prior to and after 6 months of GLY-LOW supplementation: 1. Self-reported Caloric Intake 2. Metabolic disease risk 3. Cardiovascular disease risk 4. Metabolic assessments 5. Hormones 6. Physical Function and Fitness 7. Muscular strength 8. Cognitive Function and Depression assessments 9. Systemic inflammation 10. Biological aging 11. Safety parameters (also every 2 months during the intervention; ECG at baseline and 2 months only) 12, Compliance measures (pill counts and interviews every 2 months during the intervention)
Diabetes mellitus (DM) is a complex chronic illness associated with a state of high blood glucose level, or hyperglycemia, occurring from deficiencies in insulin secretion, action, or both. Diabetes mellitus is the name given to a wide spectrum group of disorders characterized by raised plasma glucose.Type 1 diabetes is characterized by an absolute insulin deficiency due to autoimmune destruction of insulin producing beta cells in the pancreas. most adults with diabetes have type 2, characterized by a relative insulin secretory defect, and target tissue resistance to the effects of insulin.
In humans, insulin is secreted in pulses from the pancreatic beta-cells, and these oscillations help to maintain fasting plasma glucose levels within a narrow normal range. Given the fluctuations in insulin concentrations, oscillations enhance precision of control. The hyperinsulinemic euglycemic clamp test (clamp) involves a continuous infusion of insulin and is the gold standard for measuring insulin sensitivity. In this study, insulin sensitivity measured using the standard clamp will be compared with a clamp in which the same total amount of insulin as the standard clamp is infused every five minutes instead of continuously.