View clinical trials related to Insulin Resistance.
Filter by:Diabetes is a chronic metabolic disease affecting 415 million people worldwide, 90% of cases are type 2 which is frequently associated with obesity and a sedentary lifestyle. In healthy individuals, insulin stimulates increased cell surface expression of a glucose transporter (GLUT4) in muscle and fat tissue. This prevents blood sugar levels becoming dangerously high by taking sugar into the muscle and fat cells. Loss of this response ('insulin resistance') frequently occurs before the development of type 2 diabetes. Understanding the cell biology of insulin resistance is necessary to develop more effective treatments for this condition and prevent further cases of type 2 diabetes. Previous work showed that this movement of GLUT4 is dependent on a small protein called Rab3 which is downregulated in insulin resistance. Rab3 protein levels are also sensitive to inflammation, a state that is exacerbated by obesity. In order to examine whether Rab3 is an early biomarker of insulin resistance, we aim to measure the levels of this protein and its interactors in fat and muscle samples from insulin resistant individuals. It has been shown that insulin sensitivity can be improved with an intervention as short as three weeks when net energy intake is sufficiently reduced. Therefore, by taking the same measurements before and after this three week intervention we can observe any improvements in Rab3 expression and insulin sensitivity at a cellular level. There is also evidence for an effect of the gut microbiome on insulin sensitivity so we will measure any changes that take place in the gut microbiome following this intervention, which can be determined from faecal samples taken before and after the three weeks.
The investigators want to learn more about obesity, the development of insulin resistance, and Type 2 Diabetes in children. The investigators will do this through collecting information about children's health and conducting experiments on a variety of samples.
The purpose of this study is to better understand the contribution of sympathetic vasoconstriction to impaired insulin-mediated vasodilation and subsequently insulin-mediated glucose uptake. The investigators will test the hypothesis that removal of sympathetic vasoconstriction can result in improvement in insulin-mediated vasodilation and subsequently sensitivity to insulin-mediated glucose uptake.
The purpose of this study is to investigate the extent to which diet and exercise may improve PAH through the modulation of insulin sensitivity. The central hypothesis is that dysregulated glucose metabolism elicits a response in PAH patients that can be modified by exercise and diet, thereby leading to improvements in pulmonary vascular disease.
Short-term (1-year) results of renal transplantation are now excellent (over 95%). Long-term (10-year and longer) results are, however, still disappointing. Where most research has focused on immunosuppression and infections, the investigators hypothesize that in renal transplant recipient, amongst others overweight, obesity, chronic use of immunosuppressive drugs and impaired renal function contribute to insulin resistance and chronic low-grade inflammation, which pose the renal transplant recipients at increased risk for cardiovascular disease, decline of function of the transplanted kidney and other complications, including post-transplant diabetes. This study is a biobank and cohort study which investigates this hypothesis.
Type 2 diabetes results from a combination of peripheral insulin resistance and beta-cell dysfunction, and manifests as fasting and postprandial hyperglycemia. In Singapore, despite the relatively low prevalence of overweight and obesity, the prevalence of type 2 diabetes is disproportionately high and is expected to double in the near future. This indicates that insulin resistance and beta-cell dysfunction are widely prevalent even among individuals who are not overweight or obese. Still, weight loss induced by a variety of ways (calorie restriction, exercise, surgery, etc.) is considered the cornerstone of diabetes treatment. This underscores the importance of negative energy balance in improving metabolic function. In fact, negative energy balance induced by calorie restriction can improve metabolic function acutely, i.e. within 1-2 days and before any weight loss occurs. Likewise, negative energy balance induced by a single session of aerobic exercise improves metabolic function over the next few days. However, the magnitude of negative energy balance that needs to be achieved in order to improve metabolic function, as well as possible dose-response relationships, are not known. Furthermore, the comparative efficacy of calorie restriction vs. exercise in improving metabolic function has never been directly assessed. Accordingly, a better understanding of the effects of acute negative energy balance induced by calorie restriction or aerobic exercise on insulin sensitivity and beta-cell function will have important implications for public health, by facilitating the design of effective lifestyle (diet and physical activity) interventions to prevent or treat type 2 diabetes. To test these hypotheses, whole-body insulin sensitivity, the acute insulin response to glucose, and the disposition index (i.e. beta-cell function), will be determined the morning after a single day of progressively increasing negative energy balance (equivalent to 20% or 40% of total daily energy needs for weight maintenance) induced by calorie restriction or aerobic exercise. Results from this project are expected to result in the better understanding of the effects of negative energy balance induced by diet and exercise on metabolic function. Therefore, this project may help in the design of effective lifestyle intervention programs for the prevention and treatment of type 2 diabetes.
Muscle atrophy and insulin resistance are common after bed rest in healthy older adults. Metformin treatment has been shown to improve insulin sensitivity and attenuate muscle loss in insulin resistance adults though the mechanisms are not fully known. Metformin used as a preventive strategy to maintain muscle and metabolic health in bed ridden older adults has not been investigated.
Hormonal and metabolic changes because of postmenopause increase body weight, central abdominal fat, alter lipid profile and insulin resistance, those factors increase the risk up to 60% to develop metabolic syndrome, diabetes and cardiovascular diseases. Because there is no efficient antioxidant therapy in postmenopausal women, this study proposes a therapy with resveratrol and vitamin C to increase the total antioxidant capacity; as well as to decrease insulin resistance and in consequence decreased the risk of diabetes, metabolic syndrome and cardiovascular disease
Pre diabetes (PD) is a term that refers to alterations in glucose homeostasis, including impaired fasting glucose (IFG), Imparied glucose tolerance (IGT) or both, involving a higher risk to develop type 2 diabetes mellitus (T2DM) in 10 years. The efficacy of pharmacotherapy in the prevention of diabetes in adults with prediabetes has been demonstrated, the first line of pharmacology treatment is metformin, on the other hand, the traditional Chinese and Ayurverica medicine offer potential active substances for the treatment of hyperglucemia like berberine. Berberine is an extract with hypoglycemic effects in animal models as well as in clinical trials in type 2 diabetes mellitus even compared to metformin, for this reason comparing it's activity against metformin in prediabetes would provide impact information on a new alternative treatment and compare with the standard pharmacological treatment. The aim of the study evaluate the effect of administration of berberine versus metaformine on glycemic control, insulin secretion and insulin sensitivity in patients with pre diabetes. The investigators hypothesis is that the administration of berberine versus metformin modifies glycemic control, insulin sensitivity and insulin secretion in patients with prediabetes.
Insulin promotes the clearance of sugars from the blood into skeletal muscle and fat cells for use as energy; it also promotes storage of excess nutrients as fat. Type 2 diabetes occurs when the cells of the body become resistant to the effects of insulin, and this causes high blood sugar and contributes to a build-up of fat in muscle, pancreas, liver, and the heart. Understanding how insulin resistance occurs will pave the way for new therapies aimed at preventing and treating type 2 diabetes. Mitochondria are cellular structures that are responsible for turning nutrients from food, into the energy that our cells run on. As a result, mitochondria are known as "the powerhouse of the cell." Mitochondria are dynamic organelles that can move within a cell to the areas where they are needed, and can fuse together to form large, string-like, tubular networks or divide into small spherical structures. The name of this process is "mitochondrial dynamics" and the process keeps the cells healthy. However, when more food is consumed compared to the amount of energy burned, mitochondria may become overloaded and dysfunctional resulting in a leak of partially metabolized nutrients that can interfere with the ability of insulin to communicate within the cell. This may be a way for the cells to prevent further uptake of nutrients until the current supply has been exhausted. However, long term overload of the mitochondria may cause blood sugar levels to rise and lead to the development of type 2 diabetes. This study will provide information about the relationship between mitochondrial dynamics, insulin resistance and type 2 diabetes.