View clinical trials related to Insulin Resistance.
Filter by:The study aims at the identification and the quantification of urinary branched-chain amino acids (BCAAs) by mass spectometry in healthy subjects and patients with insulin resistance and correlating urinary BCAAs with HOMA index. Blood and urine levels of BCAAs will be correlated with HOMA index to assess and quantify insulin resistance. Identification and quantification of urine BCAAs by an innovative method based on synthetic biology will also be performed. Correlations between mass spectometry and the innovative detection method of BCAAs will be searched.
This study will investigate the safety and efficacy of the investigational use of the HydraSolve T2D™ System in improving blood glucose control and insulin resistance in patients with obesity (Class 1, BMI 30-39.9 kg/m2) and type 2 diabetes who have not achieved targeted levels of blood glucose control using oral diabetes medications. The previously FDA-cleared (for liposuction and fat transfer) HydraSolve T2D™ System will be used to perform a novel, minimally invasive laparoscopic and mini-laparotomy procedure to selectively remove excess intra-abdominal fat from the mesentery (Mesenteric Visceral Lipectomy (MVL)), while not affecting surrounding tissues. The study will include several weeks of screening for eligibility before the intervention, and 12-months of follow-up post-surgery.
Once written consent is obtained, the participant will be provided with an accelerometer to be worn for 7 days to assess current physical activity levels. Subjects will be provided with a standardized diet (55/15/30% CHO/PRO/FAT) prior to collection of pre-intervention data of insulin sensitivity. Individuals will then participate in an 8-week electrical stimulation intervention (30min/day, 3x/week) and randomized into placebo/control, NMES, resistance training combined with NMES (RT +NMES), or resistance training (RT) group (n=15 per group), followed by collection of post-intervention data. The control group will receive electrical stimulation up to sensory level, the NMES group will receive stimulation up to tolerable intensity to induce visible muscle contraction, the RT+ NMES will receive stimulation up to tolerable intensity during resistance training, and the RT group will only receive exercise training. Pre-and post-intervention data includes measurements for body composition, resting metabolic rate, VO2max, insulin sensitivity, and comprehensive blood work.
Inositol in involved in the insulin pathway. In literature it has been demonstrated to improve insulin sensitivity and ovarian function in women affected by PCOS. In a preliminary study conducted on obese children between 7 and 15 years, the investigators have demonstrated that Inositol administration (Myo-inositol 1100 mg + D-Chiro-inositol 27,6 mg + Folic Acid 400 μg) before a Glucose Oral Tolerance Test reduces the increase of insulin levels, particularly in subjects with basal insulin ≥ 15 uU/ml. So the aim of this study is to evaluate the potential therapeutic effect of inositol, as non-pharmacologic agent, in preventing tipe II diabetes in children.
With this study the investigators want to understand the physiological differences for people developing pre-diabetes and diabetes. The investigators hypothesize that different individuals go through different paths in the development of the disease. By understanding the personal mechanism for developing disease, the investigators will find a personalized approach to prevent that development. The investigators are also hoping to be able to find a biomarker that will pinpoint to the particular defect and thus, diagnose the problem at an earlier stage and have the information to give personalized diet recommendations to prevent the development of diabetes more effectively.
This study evaluates the effects of oral supplementation with curcumin on the insulin sensitivity in subjects with prediabetes. The half of participants will receive curcumin and bioperine in combination, while the other half receive placebo.
The overarching aim of the study is to determine the role of insulin signaling on the neurobiological substrates subserving anhedonia within individuals with mood disorders (i.e., Bipolar Disorder (BD) and Major Depressive Disorder (MDD)). Specific aims include: 1. Molecular: Assessment of components of the insulin cascade, as well as of anhedonia and reward-related processes, using a proteomics and gene expression approach; 2. Physiology: Measurement of peripheral sensitivity to insulin and metabolic correlates, including body mass index and dyslipidemia; 3. Neural Circuits: Evaluation of the insulin sensitivity of prefrontal (e.g. prefrontal cortex) and striatal (e.g. nucleus accumbens, ventral tegmental area) networks in the resting-state and during an effort-based decision making test, using acutely administered intranasal insulin and functional magnetic resonance imaging (fMRI); 4. Behavioral: Measurement of willingness to make effort for rewards, as well as of other components of reward response and anhedonia, using validated behavioral tasks and clinical scales (e.g. Snaith-Hamilton Pleasure Scale - SHPS). This initiative represents a proof-of-concept study that insulin is important to anhedonia, neurocognitive functioning, and behavioural deficits in MDD, representing a novel and safe therapeutic avenue.
The effect of N-acetylcysteine supplementation on carbohydrate metabolism disorder and homocysteine concentrations in obese women will be analysed.
Obesity is an independent risk factor for type 2 diabetes and cardiovascular disease. The increased prevalence of obesity worldwide is a major concern among the scientific and medical communities. Insulin resistance is a common factor associated with obesity, metabolic syndrome, hypertension, and type 2 diabetes. Individuals affected by these conditions often experience endothelial dysfunction as well. Insulin resistance provides a key link between metabolic syndrome risk factors and vascular disease. Development of strategies aimed at preventing vascular dysfunction and future disease caused by metabolic disturbances is needed. Although the relationship between obesity and various diseases is well known, the acute effects of insulin on vascular function in obese individuals have yet to be fully determined. Additionally, the effects of acute exercise on insulin-stimulated endothelial function are unknown. Exercise may be an effective and potent treatment that protects against endothelial dysfunction, insulin resistance, and future cardiometabolic disease commonly present with obesity. However, less attention has been placed on vascular insulin sensitivity. The purpose of this study is to test the hypothesis that a single bout of exercise increases insulin-stimulated blood flow at the macro- and micro-vasculature level in obese individuals with metabolic syndrome to similar levels as healthy obese control. Our laboratory has available non-invasive methods to quantify vascular function and the gold-standard technique for assessing insulin sensitivity (euglycemic-hyperinsulinemic clamp). The investigators will assess vascular function (flow-mediated dilation, post-ischemic flow velocity and contrast-enhanced ultrasound) as well as arterial stiffness (augmentation index and pulse wave velocity) before and at the end of the clamp protocol performed the morning following a bout of exercise and a control (no-exercise) condition in 1) metabolic syndrome and 2) obese adults. If our hypothesis is sustained, it will suggest that a key role of the vasculature exists in regulating insulin following exercise and will provide insight into the link between the vasculature, obesity, metabolic syndrome and cardiovascular disease and may confer decreased risk for cardiometabolic disease.
The primary objective of this study is to examine whether exercise training alone, liraglutide treatment alone or exercise training plus liraglutide treatment increases cardiac and muscle capillary blood volume, improves vascular function in the larger conduit vessels, and enhances insulin's metabolic action in humans with Type 2 diabetes. Subjects will be randomized to one of the three groups: exercise training, liraglutide treatment, and exercise + liraglutide. They will be studied at the baseline and then after 16 weeks of intervention.