Active clinical trials for "Glucose Intolerance"

This study aims to determine whether the effectiveness of cinnamon spice capsules vs. placebo capsules on glucose tolerance in prediabetic subjects who are overweight or obese.

Examination of the effect of one week's unhealthy lifestyle on glucose metabolism and liver parameters in a group of young, healthy males participating in Roskilde Festival 2016.

The study will investigate the safety, feasibility, and efficacy of beta-alanine supplementation in adults with overweight or obesity. Beta-alanine is a widely used dietary supplement that can increase the amount of carnosine in skeletal muscle. Both carnosine and beta-alanine occur naturally in animal food products and previous research shows that supplementation with beta-alanine leads to an improvement in exercise performance; more recently, the present investigators have shown that increasing carnosine can also help to improve cardiometabolic health, detoxify skeletal muscle, and improve glucose (sugar) uptake into muscle cells. The investigators will recruit 30 participants (15 per arm) with overweight or obesity who meet the study criteria (this accounts for up to 20% attrition - a minimum of 12 participants per arm). Those who are eligible will be required to receive three short telephone calls and attend three laboratory sessions. Participants will be randomised to receive either beta-alanine or placebo (an inactive sugar pill) for the 3-month study period. To see whether beta-alanine supplementation is feasible in this population the investigators will measure recruitment, adherence (how well people can stick to the supplement regime), the number and nature of side effects, and blinding to the intervention. Markers of cardiac function, glycaemic control, and metabolic health will also be explored. All measurements will take place before and after a 3-month supplementation period. This will provide us with novel information of the role of beta-alanine and carnosine in cardiometabolic health; and will aid in the planning of a larger randomised controlled trial to assess the efficacy of beta-alanine supplementation as a therapeutic strategy.

Physical activity helps maintain optimal postprandial blood glucose control. However, there is a lack of clear information regarding the optimal meal-activity timing required to maximize blood glucose control. By using continuous glucose monitoring (CGM), this randomized controlled trial will determine whether implementing a bout of physical activity immediately before, or immediately after, or shortly after a meal is most optimal. This study will also independently examine the effects of three different physical activities: walking, standing, and circuit-exercises. Minimizing the changes in blood glucose following a meal not only reduces the risk of type 2 diabetes but also reduces cardiovascular-related mortality. Therefore, the data produced by this project will have very important implications for informing healthcare policy and physical activity recommendations.

The proposed research will translate research on delay discounting to the prevention of Type 2 diabetes (T2D) in persons with prediabetes. In this study, the investigators will verify target engagement (DD) by examining if EFT improves DD under conditions shown to increase discounting of the future. Prediabetics will be randomized to receive EFT/ERT in a factorial design when experiencing simulated poverty/neutral conditions, respectively. The effects will be measured on DD. The investigators predict that poverty conditions will increase discounting of the future for ERT subjects, but those receiving EFT will show levels of DD similar to levels observed for participants in the wealth condition.

Glucose-dependent insulinotropic polypeptide (GIP) is a hormone produced in the intestine. It is released immediately after meal ingestion and increases insulin release. This, in turn, helps reduce blood glucose levels. This circuit does not work properly in humans with type 2 diabetes mellitus (T2DM). We have previously shown that a peptide called xenin-25 can amplify the effects of GIP on insulin secretion in humans. However, xenin-25 no longer does this when humans develop T2DM. Thus, it is important to understand how xenin-25 works in humans without T2DM so we know why it does not work in humans with T2DM. Acetylcholine is molecule produced by specific types of nerves. The effects of acetylcholine can be blocked by a drug called atropine. We have previously shown in mice that atropine prevents the ability of xenin-25 to increase the effects of GIP on insulin release. The purpose of this clinical trial is to determine if atropine also blocks the effects of xenin-25 in humans without T2DM. If it does, then impaired acetylcholine signaling may be one of the reasons humans develop T2DM and it could be possible to develop drugs that bypass this defect and increase insulin release in humans with T2DM.

Weight loss achieved through gastric banding will be superior to treatment with metformin in preserving or restoring pancreatic beta cell function in people with prediabetes or mild type 2 diabetes.

The study will determine if increasing the highs and lows of blood glucose levels (glycemic variability) impairs insulin secretion in people with impaired glucose tolerance and/or impaired fasting glucose who are at risk for developing type 2 diabetes. Furthermore, the study will determine whether changes in beta-cell function are associated with glycemic variability and whether they are mediated by oxidative stress. To decrease or increase glycemic variability the study will provide subjects with special diets containing either low or high glycemic index foods respectively for 4 weeks. To determine if oxidative stress is a mediator, subjects on the high glycemic index diet will take either placebo or the anti-oxidant N-acetylcysteine. The study will address the hypothesis that increased glycemic variability results in increased oxidative stress and thereby exacerbates beta-cell dysfunction in individuals with impaired glucose tolerance and/or impaired fasting glucose. The findings may have important implications for the development of effective strategies aimed at the prevention and treatment of type 2 diabetes. In addition, understanding the contribution of dietary glycemic index to beta-cell dysfunction in subjects with pre-diabetes may have a significant public health impact, including changes to dietary counseling and promotion of healthier eating patterns.

Recently, various sodium glucose cotransporter 2 (SGLT2) inhibitors have been approved for the treatment of type 2 diabetes mellitus. Empagliflozin is a preparation of this class of substances. SGLT2 inhibitors also lead to a reduction in body weight in addition to their blood glucose lowering effect. The basis for this is probably the calorie loss by the increased glucose excretion over the urine. However, this weight-reducing effect is lost after a few weeks of treatment and the body weight subsequently stabilizes at a lower level than before. However, patients continue to lose energy via the urine. Hence, the weight stabilization could be due to an increased energy intake as a possible consequence of a changed brain setpoint for the body weight. As the main weight loss is achieved during the first 6-8 weeks of treatment, the investigators assume that the underlying central nervous mechanisms will be present after this time. Furthermore, clinical-experimental observations show that treatment with empagliflozin promotes endogenous glucose production in the liver. This presumably compensatory mechanism also occurs after only a few weeks of treatment. The common mechanism, which could be based both on energy intake and on the endogenous glucose production effect, is still unclear. The investigators suspect that regulatory circuits in the brain contribute to these observed effects. In fact, several studies in animals as well as initial clinical studies in humans show that the brain is involved in eating behavior and peripheral metabolism. In particular, effects of the hormone insulin modulate the dietary intake via the brain, thereby affecting human body weight. Many of the experiments on the insulin sensitivity of the human brain used a specific approach to the selective delivery of insulin into the brain: the application of insulin as a nasal spray. Although this application route has no therapeutic value, this technique allows the administration of insulin to the central nervous system with little effect on the circulating insulin levels. By combining nasal insulin administration with functional MRI, regional insulin sensitivity of the brain can be quantified. The investigators recently found that the insulin action of the brain (stimulated by nasal insulin) regulates both endogenous glucose production and peripheral glucose uptake during hyperinsulinemic euglycemic glucose clamps. The signals from the brain seem to reach the periphery via the autonomic nervous system in order to modulate metabolic processes. A central brain area in this regard is the hypothalamus. This brain region receives afferents over various systems such as the autonomic nervous system and various endocrine systems (including insulin). The investigators recently characterized the hypothalamus as an insulin-sensitive brain area in humans. The hypothalamus is the key area for homeostatic control throughout the body. Since the dietary intake and the endogenous glucose production are modulated by a hypothalamic insulin effect in humans, we suspect that the observed effects of SGLT2 inhibitors on both processes could be due to altered insulin activity in the brain. Since the SGLT2 inhibition by empagliflozin modulates the autonomic nervous system in the kidneys, signals from the kidney may be transmitted to the brain via the autonomic nervous system, thereby changing specific setpoints, including e.g. insulin sensitivity of the brain. In order to test this hypothesis, a precise phenotyping of prediabetic volunteers with regard to regional brain insulin sensitivity as well as the brain effect on metabolism before and after 8 weeks of treatment with empagliflozin compared to placebo is planned.

PREVENT-WIN study has three components. The work plan will have the following S&T components. Component 1: Cross-sectional Study Cross-sectional study will be of 1.5 years where 400 women from rural will be screened randomly for the vitamin D deficiency and its determinants including duration of sun exposure. Component 2: Prospective Study This open-label randomized placebo-controlled trial would be done in 150 pre-diabetic women with vitamin D deficiency. The women will be recruited from cross-sectional study, out patient department and health camps and they will be followed up for 2 years. The women will be randomized into two groups; lifestyle modification counseling along with intervention with either vitamin D or placebo. The levels of vitamin D and blood glucose will be assessed periodically (every 6 months). In those having recurrent vitamin D deficiency, the course of vitamin D will be repeated. At the end of the study, incidence of T2DM in both groups will be compared. Component 3: Information Education and Communication (IEC) Activities: There is a paucity of IEC material on vitamin D deficiency in women residing in rural areas. IEC material will be developed and IEC activities through various modes like lectures, workshops, group discussions, leaflets/booklets distribution and audio video media shows (Hindi and English) will be used for educating health professionals, Medical and paramedical workers and various village level health functionaries like, Multi purpose workers, anganwadi workers, Accredited Social Health Activist under National Rural Health Mission of Government of India (ASHA). Besides this, Self Help Groups (SHGs) and women will be told about the benefits of balance diet, dietary intake of calcium, vitamin D, benefits of sun exposure and adverse health effects of vitamin D deficiency.