View clinical trials related to Insulin Resistance.
Filter by:The study aims to evaluate the efficacy and tolerability of a food supplement based on D-chiro-inositol in overweight or obese women with insulin resistance, who are approaching a hypocaloric diet
Animal and observational research in humans suggest that specific types of non-nutritive sweeteners (NNS) may impair glycemic control. However, whether NNS consumption impacts glucose homeostasis in middle-aged/older adults with prediabetes is unknown, and potential mechanisms by which this could occur have yet to be identified. The overall objective of this R21 proposal is to establish proof-of-concept for alterations in glucose homeostasis following intake of sucralose, but not aspartame, in middle-aged/older adults with prediabetes compared to a eucaloric diet with no NNS.
miRNAs are small non-coding RNAs of approximately 22 nucleotides in length, which have the function of regulating gene expression at the post-transcriptional level through base complementation of protein-coding transcripts, this interaction leading to translational repression by destabilizing the messenger RNA. Evidence demonstrates an association between differences in miRNA expression and the development of various pathologies, including obesity, type 2 diabetes, cardiovascular disease, neurodegenerative disorders and cancer. Other factors that could also modulate miRNA expression include nutritional status, diet and even exercise. The aim of this study is to identify exosome microRNAs that modify their expression in plasma from patients with insulin resistance fed different dietary protein sources. A randomized controlled clinical trial will be performed where the selected participants will be assigned by lottery to a dietary intervention of usual diet with protein of plant or animal origin for 4 weeks. The study will consist of 3 visits where anthropometric parameters, body composition, systolic and diastolic blood pressure, dietary compliance through 24-hour recall and food logs, biochemical tests (insulin, glucose, triglycerides, total cholesterol, HDL, LDL), the relative expression of plasma exosome miRNAs and markers of oxidative stress will be evaluated. Participants will receive a weekly food pantry during the first two visits in order to improve compliance to the dietary intervention.
In this observational cohort study the investigators will determine the activity rhythm of the suprachiasmatic nucleus in humans with progressive stages of insulin resistance, using advanced functional brain imaging (7 Tesla functional MRI).
Muscle mass loss is a common adverse effect of cancer. Muscle mass loss occurs with or without reduction in body weight. Cancer cachexia (CC) is the involuntary loss of body weight of >5% within 6 months and it occurs in 50-80% of patients with metastatic cancer. It is estimated that CC is a direct cause of up to 30% of all cancer-related deaths. No treatment currently is available to prevent CC, likely because the chemical reactions that causes of this devastating phenomenon in unknown. No treatment currently is available to prevent muscle mass loss in patients with cancer but is urgently needed as the reduced muscle mass and function is associated with impaired physical function, reduced tolerance to anticancer therapy, poor quality of life (QoL), and reduced survival. There is evidence of an interdependence between informal caregiver (e.g. spouse) and patient QoL. Thus, identifying caregiver distress and needs can potentially benefit QoL for patients with cancer cachexia. Despite the enormous impact on disease outcomes, it is not known why the loss of muscle mass and function occurs and very few studies have investigated the underlying molecular causes in humans. In particular, there is a severe lack of studies that have obtained human skeletal muscle and adipose tissue sample material. Such reference sample materials will be invaluable to obtaining in-depth molecular information about the underlying molecular causes of the involuntary but common muscle mass and fat mass loss in cancer. At a whole body level, cancer cachexia is associated with reduced sensitivity to the hormone insulin, high levels of lipids in the blood, and inflammation. Within the skeletal muscle, the muscle mass loss is associated with elevated protein breakdown and reduced protein build-up while emerging, yet, limited data also suggest malfunction of the power plants of the cells called mitochondrions. The role of malnutrition and how it contributes to weight loss is understood only to the extent of the observed loss of appetite and the reduced food intake because of pain, nausea, candidiasis of the mouth, and breathlessness. Evidence is increasing that the environment of the intestinal system could be implicated in cancer cachexia, yet, the possible effect of cancer and the cancer treatment on the intestinal environment is not understood. Thus, large and as yet poorly understood details of this syndrome precede a later weight loss. Exercise training could help restore muscle function and how the chemical reactions works in cancer. In healthy people, and patients with diabetes, cardiovascular disease, and obesity exercise potently improves health. Exercise has been thought to slow down the unwanted effects of cancer cachexia by changing the reactions mentioned above. Thus, there is a tremendous gap in our knowledge of how and if exercise can restore the cells power plants function, muscle mass, strength, and hormone sensitivity in human cachexic skeletal muscle. Tackling that problem and examining potential mechanisms, will enable us to harness the benefits of exercise for optimizing the treatment of patients with cancer. The data will provide novel clinical knowledge on cachexia in cancer and therefore addressing a fundamental societal problem. Three specific aims will be addressed in corresponding work packages (WPs): - investigate the involvement of hormone sensitivity of insulin and measure the chemical reactions between the cells in patients with lung cancer (NSCLC) and describe the physical performance and measure amount of e.g. muscles and adipose tissue across the 1st type of cancer treatment and understand how that is related to the disease and how patients and informal caregiver feel (WP1). - find changes in the chemical reactions in skeletal muscle, adipose tissue (AT), and blood samples in these patients, to understand how to predict how the disease will develop (WP2). - measure changes of skeletal muscle tissue in response to exercise and see if it might reverse the hormone insensitivity and improve muscle signaling and function (WP3). The investigators believe that: - the majority of patients with advanced lung cancer, at the time of diagnosis already are in a cachectic state, where they lose appetite, and have hormonal changes, and an overall altered chemical actions between the cells affecting both muscle mass and AT. The investigators propose that all this can predict how the disease will progress, and how patient- and informal caregiver fell and how they rate their quality of life. - lung cancer and the treatment thereof is linked with changes in the blood, the muscle tissues, and the adipose tissues, especially in patients experiencing cachexia, that could be targeted to develop new treatment. - exercise can restore the muscles and improve insulin sensitivity and improve the function of the cells power plants in patients with lung cancer-associated muscle problems.
The purpose of this study is to investigating the effect of Umbilical Cord Mesenchymal Stem Cell (UC-MSCs) and secretomes to insulin resistance in Polycystic Ovary Syndrome (PCOS) patients. This study has 4 arms namely UC-MSCs treatment, secretomes treatment, UC-MSCs and secretomes treatment, and control.
Investigators propose to study youth across the spectrum of body mass index (BMI) and dysglycemia. This approach will allow investigators to disentangle the relationship of key features of type 2 diabetes (T2D) risk (e.g. obesity) with intermediary physiologic changes (e.g. insulin resistance, inflammation, β-cell dysfunction and dysglycemia) that pose a risk for the brain. Investigators will determine which of these factors are most associated with differences in brain structure and function among groups, over time, and how these effects differ from normal neurodevelopment.
Androgen excess is the cardinal biochemical feature of polycystic ovary syndrome (PCOS). Serum testosterone correlates with insulin resistance in PCOS, however, there is an urgent need to improve our understanding of the association between androgens and the risk of type 2 diabetes. 11-oxygenated steroids are the predominant androgens in PCOS and correlate closely with markers of insulin resistance. The bioactive 11-oxygenated androgen 11-ketotestosterone (11KT) binds and activates the androgen receptor with equal affinity to testosterone, yet nothing is known about its impact on metabolism or glucose homeostasis Crucially, there are no data linking androgen excess with muscle glucose metabolism and the differential contribution of 11-oxygenated androgens to diabetes risk through these processes remains unknown. The investigators hypothesise the following: 1. Oral androgen exposure in women with PCOS results in distinct changes in tissue-specific insulin sensitivity and muscle energy biogenesis 2. 11-oxygenated androgen exposure exerts differential changes on the above parameters in comparison to classic androgen exposure The study has the following aims: 1. To examine the impact of oral androgen exposure on skeletal muscle insulin sensitivity and glucose disposal in women with PCOS. 2. To delineate the impact of androgen exposure on muscle mitochondrial function ex vivo in women with PCOS 3. To compare the differential impact of 11-oxygenated androgen compared to classic androgens on glucose disposal and muscle mitochondrial function The two arms will run in parallel and all participants will undergo identical investigations before and after 7 days of either DHEA or 11KA4. Investigations will include baseline arthrometric measurements muscle biopsy, two-step hyperinsulinaemic euglycaemic clamp, breath sampling. This interventional metabolic phenotyping study will probe the role of classic and 11-oxygenated androgens in metabolic dysfunction in PCOS using gold-standard in vivo metabolic phenotyping techniques. Delineating the distinct contribution of 11-oxygenated androgens, through effects on skeletal muscle biology, to the risk of T2DM is an important step in the process of determining risk of type 2 diabetes in this vulnerable cohort.
The study investigates the role of mTOR in mediating enhancement of muscle insulin sensitivity following a single bout of exercise. This will be investigated in young healthy male subjects by administering the pharmacological mTOR inhibitor Rapamycin in a crossover blinded experimental setup known to enhance muscle insulin sensitivity following one-legged knee-extensor exercise.
this is an observertional study aimed at Study the association between Insulin resistance estimated by HOMA and Angiographic Severity of Coronary Artery Disease in Non Diabetic & Non Obese Patients.