Glycemic Effect of Diazoxide in NAFLD
HyperinsulinemiaInsulin Resistance2 moreThe goal of this clinical trial is to compare a two-week course of diazoxide (at two different doses) and placebo in people with overweight/obesity and insulin resistance (IR) with, or at high risk for, non-alcoholic fatty liver disease (NAFLD). The main questions it aims to answer are how mitigation of compensatory hyperinsulinemia with diazoxide affects parameters of glucose and lipid metabolism (how people with IR and NAFLD respond to lowering high insulin levels so that the investigators can see what happens to how the liver handles fat and sugar). Participants will: Take 27 doses of diazoxide (at 1 mg per kg of body weight per dose [mpk] or 2 mpk) or of placebo, over 14 days Take 32 doses of heavy (deuterated) water (50 mL each) over 14 days Have blood drawn and saliva collected after an overnight fast on four mornings over the two-week study period Consume their total calculated daily caloric needs as divided into three meals per day Wear a continuous glucose monitor for the two-week study period Researchers will compare fasting blood tests at intervals during the study period in participants randomized (like the flip of a coin) to diazoxide 1 mpk, diazoxide 2 mpk, or placebo, to see how the drug treatment affects plasma glucose, serum insulin, and serum lipid parameters (triglycerides, free fatty acids, and apolipoprotein B). They will also consume heavy (deuterated) water to assess de novo lipogenesis (building of new fatty acids by the liver).
Pancreatic Clamp in NAFLD
Insulin ResistancePrediabetic State3 moreThis is a single-center, prospective, randomized, controlled (crossover) clinical study designed to investigate the specific dose-response impact of insulin infusion rate (IIR) on blood glucose levels during a pancreatic clamp study. The investigators will recruit participants with a history of overweight/obesity and prediabetic state (i.e., prediabetes or impaired fasting glucose, with fasting hyperinsulinemia), with evidence of, or clinically judged to be at high risk for, uncomplicated non-alcoholic fatty liver disease (NAFLD). Participants will undergo two pancreatic clamp procedures in which individualized basal IIR are identified, followed in one by maintenance of basal IIR (maintenance hyperinsulinemia, MH) and in the other by a stepped decline in IIR (reduction toward euinsulinemia, RE). In both clamps the investigators will closely monitor plasma glucose and various metabolic parameters. The primary outcome will be the absolute and relative changes in steady-state plasma glucose levels at each stepped decline in IIR.
Exenatide-test for Diagnosing Endogenous Hyperinsulinemic Hypoglycemia
Endogenous HyperinsulinismThis study is to evaluate the concept of the exenatide test for diagnosis of EHH (earlier induction of symptomatic hypoglycemia compared to placebo within 4 hours after injection).
Extension Trial Evaluating the Long-term Safety and Efficacy of Dasiglucagon in Children With Congenital...
Congenital HyperinsulinismThis is an open-label, multinational, multicenter, long-term safety and efficacy extension trial in patients with Congenital Hyperinsulinism (CHI) who completed either ZP4207-17103 or ZP4207-17109 (defined as lead-in trials). The primary objective is to evaluate the long-term safety of dasiglucagon administered as subcutaneous (SC) infusion in children with CHI.
Utility of 18FDOPA PET/MRI for Focal Hyperinsulinism
HyperinsulinismThe purpose of the study is to provide access to 18F-DOPA PET to patients at Washington University and assess the utility of 18F-DOPA PET/MRI as a preoperative tool to detect and localize focal lesions in the pancreas that are causing hyperinsulinism.
18FluoroLDOPA PET Imaging for the Detection and Localization of Focal Congenital Hyperinsulinism...
Congenital HyperinsulinismThe goal of this project is to determine the role of FDOPA/PET as a pre-operative diagnostic imaging procedure for differentiating focal and diffuse forms of congenital hyperinsulinism and locating focal lesions in the pancreas to guide surgical resection.
Increasing Insulin Resistance as a Predictor of Impending Bacteremia
Acquired ICU BacteremiaInsulin resistance is defined as a decrease in the ability of insulin to lower blood glucose levels. Various pathological conditions can cause an increase in insulin resistance, such as sepsis, administration of certain medications, various stressful situations, surgery or significant injuries, etc. Sepsis can cause extreme stress, which causes significant changes in metabolism, disruption of blood glucose regulation and increased insulin resistance. In sepsis there is an extreme activation of inflammatory mediators and of counter-regulatory hormones, such as cortisol, glucagon and catecholamines, which increase hepatic gluconeogenesis on the one hand, and increase the peripheral resistance to insulin on the other hand. Disorder in the regulation of blood glucose level causes increased mortality and morbidity among intensive care unit patients with sepsis, as well as an increase in the duration of hospitalization and its financial expenses. There are a number of parameters used in the intensive care unit to diagnose the development of sepsis within the unit, such as an increase or decrease in body temperature, an increase in CRP level, white blood cell count, pro-calcitonin level, etc It is possible that an increase in insulin resistance can also be used as a predictor of sepsis. It should be noted that almost all patients hospitalized in the intensive care unit are treated with a continuous infusion of insulin to balance their blood glucose level, including patients who are not diagnosed with diabetes prior to their hospitalization in the unit. This is in light of the increase in insulin resistance for the reasons listed above among patients in critical condition, and also due to the need to maintain blood glucose values in the range of 140-180 mg/dl, since high blood glucose values among patients hospitalized in the intensive care unit are associated with increased morbidity and mortality. We would therefore like to investigate whether an increase in insulin resistance, as expressed in an increase in the patient's insulin intake, can predict the development of sepsis secondary to bacteremia in the intensive care unit.
Assessment of Pancreatic Beta Cell Mass and Function by Positron Emission Tomography Imaging in...
type1diabetesType2diabetes2 moreThe goals of this project are to build an experimental tool to dissect out in vivo pancreatic beta cell mass (BCM) and beta cell function (BCF) and to assess for the first time these two determinants of beta cell functional mass (BCFxM) in obesity and in various stages of type 1 and type 2 diabetes mellitus.
Exercise Type That Faster Reduces Postprandial Glycemia.
GlucoseHigh Blood1 moreIt is well established that a bout of 50 min of continuous moderate intensity exercise, improves insulin sensitivity up to 48 hours after the bout. However, it is less well known, what is the exercise type more efficient to buffer the elevations in blood glucose elicited by carbohydrate ingestion. The purpose of this study is to elucidate if intervalic exercise is superior to continous on improving postprandial glycemic control.
Developing a Physiological Understanding of High Duration Activity
Sedentary LifestyleHyperinsulinemia8 moreWhen muscles are not contracting, the local energy demand by muscle and use of specific fuels used to produce energy by oxidative metabolism are minimal. The time people spend sitting inactive (sedentary time) typically comprises more than half of the day. This sedentary behavior is associated with elevated risk of diabetes, cardiovascular diseases, some cancers, and multiple conditions leading to poor aging. From a progressive series of experiments, the driving goal is to develop a physiological method for sustaining contractile activity via oxidative metabolism over more time than is possible by traditional exercise (hours, not minutes per day). Developing a physiological method suitable of prolonged muscular activity for ordinary people (who are often unfit) requires gaining fundamental insights about muscle biology and biomechanics. This also entails a careful appreciation of the ability to isolate specific muscles in the leg during controlled movements, such as the soleus muscle during isolated plantarflexion. This includes quantifying specific biological processes that are directly responsive to elevated skeletal muscle recruitment. The investigators will focus on movement that is safe and practical for ordinary people to do given their high amount of daily sitting time. This includes developing methods to optimally raise muscle contractile activity, in a way that is not limited by fatigue, and is feasible throughout as many minutes of the day as possible safely. This also requires development of methodologies to quantify specific muscular activity, rather than generalized body movement. There is a need to learn how much people can increase muscle metabolism by physical activity that is perceived to them as being light effort. It is important to learn if this impacts systemic metabolic processes under experimental conditions over a short term time span in order to avoid confounding influences of changes in body weight or other factors.