Clinical Research Directory

Effects of Ketone Supplementation on Acute Alcohol Withdrawal

The goal of this study is to study the effects of the ketone supplement Kenetik compared to placebo (an inactive beverage) on alcohol withdrawal symptoms during the 5 days of clinical alcohol withdrawal management treatment at the Caron Treatment Center.

Effects of Ketone Supplement and Alcohol on Brain Metabolism

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).

Effects of Ketones on Brain Energetics and Alcohol Consumption in Alcohol Use Disorder

This is a randomized, double-blind, crossover trial to evaluate the immediate effects of a nutritional ketone supplement, Kenotic compared to placebo on brain function and alcohol consumption in individuals with alcohol use disorder. Participants will complete 2 MRI scans, 2 FDG PET/CT scans, and 2 alcohol bar labs and will randomly receive Kenetik at one lab and the placebo at the next lab. During the bar labs participants will consume a dose of alcohol (based on weight), to bring their breath alcohol concentration to about 0.050%.

Effects of Ketone Supplementation on Alcohol Withdrawal and Brain Metabolism in Alcohol Use Disorder

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.

Strategies to Augment Ketosis: Optimization of Ketone Delivery Strategies

One important difference between KE compounds is the ketone-promoting components, which determines the circulating ratio of blood ketone bodies, BHB and AcAc, and may in turn lead to important metabolic and signaling differences. Whereas some actions of the ketone bodies BHB and AcAc are shared, R-BHB has a broad range of signaling functions that are distinct from AcAc, some of which are shared by the non-circulating, non-oxidizable enantiomer, S-BHB. AcAc also has metabolic and signaling actions that are independent of BHB and is selectively oxidized in some cells that cannot oxidize BHB. Furthermore, responses to different ketone bodies vary between tissue types. A second difference between KE arises from the balance between direct delivery of ketones compared to indirectly elevating ketone concentration via metabolism of non-classical or classical ketogenic precursors. Classical ketogenesis itself may drive adaptation and some of the functional benefits associated with ketosis. BDO is included in all of the KE compounds, but it is currently unknown how consumption of BDO alone, and its metabolism via non-classical ketogenesis acutely affects metabolism. Additionally, ketogenesis is now understood to occur in certain cells outside the liver with important local biological effects, for example ketogenesis driven by medium chain fatty acids has been reported in astrocytes in vitro. Provision of systemic BHB by a KE may elicit different biological effects in some tissues such as the brain versus promoting in situ ketogenesis in that tissue. Overall, not only are functional effects of KE incompletely defined, but also it is unknown which effects are common to all KE versus which are specific to an individual KE compound (i.e., BHB Monoester vs AcAc Diester) or which may be attributable to the BDO precursor common to all of the KE. This study will be the first comparative full crossover study of all available KE and the precursor BDO at two serving sizes. Outcomes will focus on established effects of the BHB Monoester (including the effects on ketones, glucose and acid-base balance) and compare these with the effects of the AcAc Diester, C8 Ketonef Diester and BDO.

Variations in Ketone Metabolism

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

Ketogenic Metabolic Therapy in Schizophrenia, Bipolar Disorder, Major Depressive Disorder: Deep Omic Profiling

The goal of this randomized clinical trial is to be adequately powered to evaluate the effect of ketogenic metabolic therapy on the quality of life in serious mental illness, schizophrenia, bipolar disorder, major depressive disorder.

Effects of Exogenous Ketosis on Proteinuria and Renal Function

A randomized, placebo-controlled, double-blinded crossover study will be conducted. Fourteen patients with polycystic kidney disease (PKD) and 29 patients with proteinuric kidney disease will receive ketone bodies (Ketone-IQ) and placebo in a randomized order. Each treatment period is four weeks. There will be a wash-out period of two weeks in between treatment periods. Effect variables will be measured in the last day of each treatment period.

The Impact of Different Carbohydrate Restriction After a Gastric Bypass on the Ketosis and Ketoacidosis

Background: Ketosis after bariatric surgery is a metabolic process that occurs when the body breaks down fat for energy because of not getting enough carbohydrates. Insufficient production of ketone bodies reduces the rate of weight loss, and excessive amounts of ketones can lead to ketoacidosis or liver failure in patients with nonalcoholic steatohepatitis (NASH). The investigators hypothesize that weight loss is directly related to calorie intake, and a significant reduction in carbohydrate content leads to increased ketosis and the risk of ketoacidosis. Objectives: The study aimed to compare the incidence of ketoacidosis and liver failure in patients with NASH with different intakes of carbohydrates in the early postoperative period after gastric bypass. In addition, the investigators want to find out how carbohydrate restriction will affect weight loss for up to 1 year.