28 Clinical Trials for Various Conditions
Background: Time restricted eating (TRE) is a form of fasting in which a person eats only during a set window of time, which is usually between 4 and 10 hours each day. Researchers want to know more about how TRE may affect health. Objective: To learn how TRE affects women with different body sizes. Eligibility: Healthy women aged 18 to 50 years. Design: Participants will have 2 visits: 1 screening visit and one 5-day stay in the clinic. Participants will fast before both visits. They will have a physical exam with blood tests. They will talk to a nutritionist about the foods they eat. They will lay under a clear hood for up to 45 minutes during a test that measures how many calories they burn while resting. Participants will keep a food diary for up to 7 days before their clinic stay. They will apply a continuous glucose monitor the day before they go to the clinic. This is a device that attaches to the skin of the stomach. They will wear this device throughout their clinic stay. All meals will be provided during the clinic stay. Participants will follow TRE on 3 days. They will answer survey questions and have tests during their stay, including: * DXA (dual energy X-ray absorptiometry) scan. Participants will lie on a padded table. Their body will be scanned to measure how much muscle, bone, fat, and other tissues they have. * Stable isotope tracer study. Small amounts of sugar and other substances will be given through a tube attached to a needle inserted into a vein in the arm. Blood samples will be collected.
This outcome of this study will elucidate how the phenotype of the individual modulates the KE metabolic effect. Most studies of KE have been in homogenous populations, usually young, male athletes. However, two striking experiments using identical, body weight adjusted KE doses in healthy and obese individuals found that BHB area under the curve (AUC) and removal was reduced by obesity and poor metabolic health. Similarly, ketone infusion experiments found that diabetes, obesity, and insulin resistance alter BHB metabolism. It is important to determine how obesity affects KE 'sensitivity' (i.e., breakdown and oxidation) because the increasing prevalence of obesity as a function of age. Age may be another important source of variation in ketone metabolism. The genes that control the ketone system are regulated by a cascade of transcription factors and hormones including PPARα and FGF21, which are themselves known to be affected by aging and dietary status, and the cellular protein sensor target of rapamycin (TOR). Aberrant hyperactivation of TOR with aging may reduce ketogenesis, while it was observed that a long-term ketogenic diet specifically up-regulated PPARα activity. Preliminary work revealed substantial changes across mouse lifespan in the expression of ketone-related genes in the liver such as Hmgcs2 (rate limiting for ketone production) and Bdh1 (rate limiting for BHB oxidation) between young, middle-aged, and old mice, with a nadir of gene expression in middle age before increasing again late in life. Substantial age differences were found in response to matched doses of oral KE in mice and in rats. These data may have important implications for treating people of different ages and for translating KE technologies into the Department of VA. Therefore, this project plans to study individual responses to KE ingestion across the lifespan, against the background of varying metabolic health
This study is designed to examine the value of infusing BHB in type 1 diabetic subjects during experimentally induced hypoglycemic episode in conjunction with testing of cognitive function. This will lay the basis for subsequent trials exploring the novel use of therapeutic doses of oral ketone formulations that are currently under commercial development, which could serve as adjunct therapies to protect the brain from hypoglycemia in type 1 diabetic subjects experiencing recurrent hypoglycemia.
The purpose of this study is to help us better understand how plasma ketones respond to a low-carb diet when combined with an SGLT2 inhibitor.
The purpose of this study is to understand how the reduction in dietary carbohydrates in a very-low carbohydrate ketogenic diet impacts the synthesis of cholesterol, fatty acid, and ketones, and the turnover rate of VLDL and chylomicron particles.
To examine the effect of an increase in plasma beta-hydroxy-butyrate (B-OH-B) levels, spanning the physiologic and pharmacologic range (+0.5, +2.0, and +5.0 mmol/L), on: (i) parameters of left ventricular (LV) systolic and diastolic function utilizing cardiac magnetic resonance imaging (MRI) and (ii) myocardial glucose uptake using positron emission tomography (PET) with 18F-fluoro-2-deoxy-D-glucose in type 2 diabetic patients with Class II-III New York Heart Association (NYHA).
Small exploratory open-label pilot study to assess supplementation of a ketone ester (Juvenescence) combined with a 'ketogenic-mimicking diet' as a potential therapy for persons with bipolar disorder.
Small exploratory open-label pilot study to assess supplementation of a ketone ester (KetoneAid) as a potential therapy for persons with Parkinson disease (PD), Parkinson Disease Dementia/Lewy Body Dementia (PDD/LBD), and healthy controls.
The research study is being conducted to better understand the effects of ketones and alcohol on brain functioning and brain metabolism. Participants will be asked to undergo three identical MRI visits after three single-dose interventions: (1) drink a ketone supplement drink, (2) drink an alcoholic beverage, (3) no intervention. These interventions will be randomly assigned (meaning everyone receives all 3 interventions, but in different orders).
The goal of this clinical trial is to learn the effects of ketone supplement compared to placebo on alcohol withdrawal symptoms during a 4 day alcohol withdrawal management treatment in adults with moderate to severe alcohol use disorder at the Hospital of the University of Pennsylvania, Cedar Detox Center.
Background: In Alzheimer s disease (AD) the brain cannot use glucose as a fuel. The brain can use ketones as a fuel instead of glucose. Researchers want to test a supplement, Ketone Ester (KE). It may improve brain metabolic function and cognition in normal people and, perhaps, down the road, in patients with AD. Objective: To study the change in brain ketone levels in people after 28 days of taking KE compared with baseline and placebo. Also, to study changes in cognitive performance. Eligibility: People 55 years old or older with metabolic syndrome and no cognitive impairment Design: Participants will have 4 visits. Participants will be screened at Visit 1 with: Medical history Physical exam Blood and urine tests Cognitive testing Participants will be randomly assigned to receive either the study supplement or a placebo with same amount of calories. Neither they nor the researchers will know which they receive. Visit 2 will include repeats of some screening tests. It will also include: Stool sample (brought from home) MRI/MRS: Participants will lie on a table that slides in and out of a scanner. A coil will be placed over their head. They may be asked to perform leg exercises. First dose of study supplement or placebo About 2 weeks after Visit 2, Visit 3 will include blood and urine tests and a questionnaire. About 2 weeks after Visit 3, Visit 4 will include repeats of the Visit 2 tests. Participants will drink the study supplement or placebo 3 times per day during the study. They will keep a daily log of each dose. They will bring the log to Visits 3 and 4. Participants will by contacted by phone once per week during the study to see how they are doing.
This project will be a three-group controlled 6-wk feeding study where all meals are prepared and provided to obese participants. All participants will be fed a 25% energy-restricted diet. Two diets will be very low in carbohydrate (i.e., ketogenic diets) designed to induce nutritional ketosis and fat loss. Another diet will be low in fat and saturated fat but contain the same total calories. Participants will be randomly assigned to a Ketone Supplement group who are provided an exogenous pre-formed source of beta-hydroxybutyrate (BOHB) or a Control group that only receives the standard ketogenic diet. Randomization will be stratified based on insulin resistance, sex, and body composition to ensure balanced group assignment. Because of timing of recruitment (i.e., after most of the ketogenic groups have already completed the study), the low-fat group will not be randomized. Outcome measurements will be made at various intervals over the 6-wk intervention.
The purpose of this study is to understand the effects of a ketone drink on exercise capacity and other cardiovascular parameters in patients with heart failure. In heart failure, patients are limited in their ability to do all the things they want to do, and exercise as much as they would like, due to becoming tired and short of breath early. There may be several reasons why these symptoms occur. This study is assessing whether the ketone drink can improve these symptoms. This drink has been given status by Food and Drug Administration as "generally regarded as safe". The use of DeltaG in this study is experimental. DeltaG has not been approved by the Food and Drug Administration (FDA) for the use being evaluated in this study.
This study is being done to evaluate how a ketone ester (KE) beverage affects heart function and health in people with heart failure compared to a placebo beverage (a beverage made with standard food ingredients that do not contain ketone esters).
The research study is being conducted in health controls to better understand the effects of ketosis on brain functioning after 3 different, randomly assigned, 3-day dietary interventions and the acute effects of alcohol after consuming about 4-5 alcohol beverages. The labs visits will use magnetic resonance imaging (MRI) scans to study the brain, measuring levels of nicotinamide adenine dinucleotide (NAD), lactate, neurotransmitters glutamate, and Gamma-aminobutyric acid (GABA).
The goal of this single-blind randomized placebo-controlled trial is to test the effects of an oral ketone supplement on appetite, cognition, metabolism, and cardiovascular function in individuals with obesity and insulin resistance. The main question\[s\] it aims to answer are: * Does taking the ketone supplement reduce appetite and improve cognition? * How does the ketone supplement alter metabolism and cardiovascular function? Participants will be asked to consume a randomly assigned ketone ester supplement or a placebo and testing will be done to see how the supplement affects the following compared to a placebo: * appetite, * cognition, * metabolism * cardiovascular function Researchers will compare individuals with obesity and insulin resistance to individuals with normal weight and no insulin resistance to see if the ketone supplement affects groups differently.
The primary focus of this study is to evaluate the role of Continuous Glucose Monitoring (CGM) with Levels Health software as a tool to provide feedback and accountability necessary to create sustainable behavioral changes in nutrition associated with improved metabolic health and resilience against chronic and infectious diseases.
In this study, we investigate the impact of insulin resistance on the acceleration of brain aging, and test whether increased neuron insulin resistance can be counteracted by utilization of alternate metabolic pathways (e.g., ketones rather than glucose). This study has three Arms, which together provide synergistic data. For all three Arms, subjects are tested in a within-subjects design that consists of 2-3 testing sessions, 1-14 days apart, and counter-balanced for order. During each session we measure the impact of fuel (glucose in one session, ketones in the other) on brain metabolism and associated functioning. For Arms 1-2, our primary experimental measure is functional magnetic resonance imaging (fMRI), which we will use to trace the self-organization of functional networks following changes in energy supply and demand. Arm 1 tests the impact of endogenous ketones produced by switching to a low carbohydrate diet, while Arm 2 tests the impact of exogenous ketones consumed as a nutritional supplement. For Arm 3, we use simultaneous magnetic resonance spectroscopy/positron-emission tomography (MR/PET) to quantify the impact of exogenous ketones on production of glutamate and GABA, key neurotransmitters. Subjects will be given the option to participate in more than one of the Arms, but doing so is not expected nor required. Prior to scans, subjects will receive a clinician-administered History and Physical (H\&P), which includes vital signs, an oral glucose tolerance test (OGTT), and the comprehensive metabolic blood panel. These will be used to assess diabetes, kidney disease, and electrolytes. If subjects pass screening, they will be provided the option to participate in one or more Arms, which include neuroimaging. To provide a quantitative measure of time-varying metabolic activity throughout the scan, based upon quantitative models of glucose and ketone regulation, as well as to be able to implement safety stopping rules (see below), we will obtain pin-prick blood samples three times: prior to the scan, following consumption of the glucose or ketone drink, and following completion of the scan. To assess effects of increased metabolic demand, we measure brain response to cognitive load, transitioning from resting-state to spatial reasoning through a Tetris task. To assess effects of increased metabolic supply, we measure brain response to glucose or ketone bolus.
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.
The purpose of this study is to investigate the effect of engaging in time restricted eating schedule on body weight, blood glucose, and ketones (breath acetone) in individuals with obesity.
The investigators are studying the impact of insulin resistance on the acceleration of brain aging and testing whether increased neuron insulin resistance can be counteracted by utilization of alternate metabolic pathways (e.g., ketones rather than glucose). This study has three Arms, which together provide synergistic data. For all three Arms, subjects are tested in a within-subjects design that consists of 2-3 testing sessions, 1-14 days apart, and counter-balanced for order. Impact of fuel (glucose in one session, ketones in the other) on brain metabolism and associated functioning is measured during each session. For Arms 1-2, the primary experimental measure is functional magnetic resonance imaging (fMRI), which is used to trace the self-organization of functional networks following changes in energy supply and demand. Arm 1 tests the impact of endogenous ketones produced by switching to a low carbohydrate diet, while Arm 2 tests the impact of exogenous ketones consumed as a nutritional supplement. For Arm 3, simultaneous magnetic resonance spectroscopy/positron-emission tomography (MR/PET) is used to quantify the impact of exogenous ketones on production of glutamate and GABA, key neurotransmitters. Subjects will be given the option to participate in more than one of the Arms, but doing so is not expected nor required. Prior to scans, subjects will receive a clinician-administered History and Physical (H\&P), which includes vital signs, an oral glucose tolerance test (OGTT), and the comprehensive metabolic blood panel. These will be used to assess diabetes, kidney disease, and electrolytes. If subjects pass screening, they will be provided the option to participate in one or more Arms, which include neuroimaging. To provide a quantitative measure of time-varying metabolic activity throughout the scan, based upon quantitative models of glucose and ketone regulation, as well as to be able to implement safety stopping rules (see below), the investigators will obtain pin-prick blood samples three times: prior to the scan, following consumption of the glucose or ketone drink, and following completion of the scan. To assess effects of increased metabolic demand, the investigators measure brain response to cognitive load, transitioning from resting-state to spatial reasoning through a spatial navigation video task. To assess effects of increased metabolic supply, the investigators measure brain response to glucose or ketone bolus.
Background: The drug empagliflozin treats diabetes. It lowers blood sugar by increasing glucose the kidneys excrete. This increases levels of ketones formed in the blood. The body makes ketones when it does not have enough glucose for fuel. The brains of many people with age-related diseases like Alzheimer's do not use glucose well. Brain use of ketones might improve mental ability. We investigated how empagliflozin affects ketone levels, which could lead to ways to improve brain health as people age. Objectives: To study how taking empagliflozin affects systemic and brain metabolism including ketone levels in people without diabetes. Eligibility: Adults at least 55 years old without diabetes Design: After a screening Visit, eligible participants were admitted to the NIA Clinical Unit during Visits 1 (baseline), 2 (first dose) and 3 (last/14th dose). On each Visit, blood draws were performed and circulating metabolites and hormones were repeatedly measured over 34-hour periods. Using plasma from fasting state only, we isolated total and neuronal-origin extracellular vesicles to measure proteins of the IGF-1 and insulin signaling cascades. Furthermore, on each Visit, we performed magnetic resonance spectroscopy (MRS) to measure concentrations of a plethora of metabolites in the brain. Between Visits 2 and 3, participants were taking the drug at home. A continuous glucose monitoring device was placed to detect potential glucose fluctuations while at home. The study was concluded for participants after the end of Visit 3.
Exogenous ketone supplements in the form of beta-hydroxybutyrate can be utilized as an alternate energy source (in place of glucose) for all cells except red blood cells. Exogenous ketone administration has been shown to be beneficial in terms of reducing oxidative stress, improving neuronal energy supplies, and maintaining normal blood glucose levels. The purpose of this study is to determine the effects and safety of supplementing with exogenous ketones for 6-weeks in healthy college-aged males and females. The results of this proposed study will determine whether exogenous ketone supplementation can be useful in promoting better body composition, energy levels, and blood cholesterol, glucose, and insulin levels.
The goal of this clinical research study is to test what effects a ketone drink will have in people with heart failure with preserved ejection fraction (HFpEF), including on exercise and heart function. Patients with HFpEF often have difficulty exercising, and our goal is to understand whether a ketone drink changes much patients can exercise. The study has three visits, including a baseline visit to assess for study eligibility, and two visits (one after 8 weeks of a ketone drink or a placebo drink, and another one after 8 weeks of whichever drink the participant did not receive the first time).
Determine to what extent three distinct dietary approaches improve asthma control and lung function.
This study will test the effect of diet on asthma in individuals with obesity.
The scientific goal of this study is to examine the effects of a ketogenic diet on hypoglycemia tolerance and brain function in people with type 1 diabetes mellitus (T1D) and to clarify the mechanistic role of ketones in this process. Glycemic management of T1D is typified by alternating periods of hyper- and hypo-glycemia. Because brain metabolism under usual conditions depends on glucose, acute hypoglycemia leads to immediate complications including impaired cognitive function and a counter-regulatory hormone response. Recurrent hypoglycemia is associated with functional and structural changes in the brain and contributes to the cognitive decline observed in individuals with diabetes. The state of nutritional ketosis (as it occurs during fasting or when following a ketogenic \[very low carbohydrate\] diet) may protect against these acute and chronic complications. As the body relies on fat metabolism, ketone bodies build up and provide an alternative fuel for the brain. Studies during hypoglycemia have shown better cognitive function and less hypoglycemia symptoms in the setting of nutritional ketosis or with ketone administration. This physiological benefit may have special relevance for people with T1D who experience hypoglycemia frequently. To date, no mechanistic studies have examined brain effects of nutritional ketosis in T1D; nor have any trials explored the potential relevance of this for diabetes care.
The purpose of this study is to evaluate the safety, tolerability and effectiveness of tricaprilin administered once a day for ninety days in subjects with mild to moderate, probable Alzheimer's disease.