View clinical trials related to Ketosis.
Filter by:Ketone ester supplementation has become increasingly popular as an athletic supplement. However, the metabolic effects of these supplements on exercise performance are controversial. One potential reason for lack of an ergogenic benefit could be the effects of ketone bodies on other bodily systems, such as the sympathetic nervous system. During exercise and stress the body increases the activity of the sympathetic nervous system. This causes blood vessels to constrict (get smaller) and can increase blood pressure. Studies have shown that ketone bodies can suppress the sympathetic nervous system in mice. Additionally, ketone ester supplementation can reduce blood pressure in healthy adults. In humans, direct measures of sympathetic activity are usually made from sympathetic outflow to muscle, also called muscle sympathetic nerve activity (MSNA). Using a ketone ester supplement, the investigators plan to measure blood pressure and sympathetic outflow to muscle at rest and during handgrip exercise and a mathematical task stress test to investigate the effect of ketones on neuro-cardiovascular stress responses.
Autophagy, which involves the degradation of aged or damaged cellular components, has been shown to extend healthspan and lifespan in multiple organisms, including flies, worms, and mice. Research has also demonstrated that autophagy declines with age in these simpler experimental models. However, human studies are lacking. Our study seeks to determine whether fasting, a robust stimulus of autophagy, upregulates autophagy in humans, and whether autophagy is reduced in healthy older people compared to healthy younger individuals.
A study to evaluate the prevalence of Acute Kidney Injury (AKI) in patients with Diabetic Ketoacidosis (DKA) and sepsis using data collected prospectively to a patient registry. The primary objective is to compare the prevalence of AKI in sepsis and DKA in different age groups in children and investigate the difference in the prevalence of hyperchloremia in the two groups.Secondary objectives are Compare the prevalence of AKI in sepsis and DKA in different age groups in children and investigate the difference in the prevalence of hyperchloremia in the two groups.
The primary aim of the study is to prospectively monitor the risk of diabetic ketoacidosis (DKA) during treatment with sodium-glucose cotransporter 2 (SGLT2) inhibitors in type 1 diabetes after the treatment has become available as an adjunct therapy for people with type 1 diabetes.
Objective 1: Assess feasibility and acceptability of all protocol components of a pilot trial testing a 6-week telehealth Mediterranean ketogenic nutrition adherence (KNA) program using motivational interviewing and cognitive behavioral strategies (MI-CBT) compared to a KN information only group for older adults with mild cognitive impairment (MCI) to prepare for a full-scale trial. Specifically, the investigators will examine the feasibility of the recruitment, retention, assessment, and intervention delivery methods. The investigators hypothesize that: 1. The study protocol will result in high patient retention (90%) and patient attendance of intervention sessions (80%), and 2. A centralized MI-CBT telehealth delivery approach will be associated with high intervention acceptability ratings from patients. Objective 2: Assess signal of initial effect of the KNA program on important clinical outcomes and adherence relative to a KN information-only condition. The investigators hypothesize that patients in the KNA condition, relative to the KN-only condition, will show: 1. higher rates of clinically significant improvements on the RBANS total scale scores, improvements in daily functioning (FSQ), and decreases in patient CAIDE risk score( (Cardiovascular Risk Factors, Aging, and Incidence of Dementia), and 2. improved adherence to KN, as evidenced by higher levels of measurable urine ketones in the KNA condition compared to the KN-only condition.
Because of these anabolic properties of ketone bodies and the fact that ketone bodies prevent muscle protein breakdown for gluconeogenesis during energetic stress, ketone bodies can be a promising strategy to prevent or treat skeletal muscle wasting. Therefore, our aim is to investigate the effect of 3HHB intake on muscle wasting and its adverse consequences during a period of caloric restriction in lean females. In addition, we compare the effects of 3HHB intake with a high protein diet, which is currently considered as the best strategy to minimize lean loss during hypo-energetic periods. To end, we aim to investigate the synergistic effects of the intake of 3HHB in combination with a high protein diet.
The objective of this randomized crossover study is to examine the influence of consuming a ketone ester plus carbohydrate (KE+CHO) supplement on substrate oxidation and physical performance in 15 healthy adults. Following a 48-hr muscle glycogen normalization period, volunteers will consume either an isocaloric KE+CHO (KE: 573 mg KE/kg body mass, CHO: 110 g) or isocaloric CHO drink and complete 90-min of metabolically-matched, load carriage (~30% body mass) steady-state aerobic (~60 ± 5 % of VO2peak) exercise on a treadmill. Glucose tracers will be used to assess glucose turnover, and contribution to exogenous and plasma glucose oxidation. Serial blood draws will be collected during each trial to assess endocrine and circulating substrate responses. After steady-state exercise volunteers will complete a time to exhaustion (TTE) physical performance tests at 85% VO2peak on a treadmill. Volunteers will then be provided with food for the remainder of the day. Following a 10-hr overnight fast, volunteers will return to the laboratory and consume the same supplement (KE+CHO or CHO) as they did the previous day. Volunteers will then perform a 4-mile load carriage time trial on a treadmill. Following a minimum 7-day washout period, volunteers will return to the laboratory to complete the second arm of the study. The primary risks associated with this study include those associated with exercise, blood draws, and gastrointestinal discomfort from the KE+CHO supplement.
Ketones, 3-hydroxybutyrate (3-OHB), have shown to have beneficial hemodynamics effect in patients with hearth failure with reduced ejection fraction. The mechanisms behind these marked hemodynamic effects are currently unknown, but could involve prostaglandin-release. 3-OHB is the endogenous ligand for the G protein-coupled receptor hydroxy-carboxylic acid 2 (HCA2) receptor. This receptor has proven downstream effects on cAMP and systemic effects via release of prostaglandins. In this present study we will investigate the cardiovascular effects of HCA2-receptor stimulation in heart failure patients.
This study will evaluate whether supplementation of exogenous ketones in patients with severe left ventricular dysfunction and acutely decompensated heart failure requiring inotropic therapy would improve the patient's hemodynamics and symptoms.
The main objective of this clinical trial is to study the metabolic effects of intravenous infusion of the ketone body, 3-hydroxybutyrate (3-OHB), in patients with type 1 diabetes and healthy control subjects. Moreover, the investigators plan to examine regulatory mechanisms of 3-OHB that may be related to diabetic ketoacidosis. The hypotheses are: 1. 3-OHB related inhibition of lipolysis is impaired in patients with type 1 diabetes. 2. Intravenous infusion of 3-OHB affects signaling pathways involved in the metabolic regulation in patients with type 1 diabetes and healthy controls. 3. 3-OHB infusion improves cardiac function in patients with type 1 diabetes and healthy controls. The effects of 3-OHB will be investigated by isotopic tracers examinations, fat and muscle biopsies and blood samples. To evaluate effects on cardiac function echocardiography will be performed.