View clinical trials related to Mitochondrial Function.
Filter by:The goal of this randomized, double-blind, parallel group interventional study is to evaluate the effect of ketone bodies on healthy older adults (65-85 y) during 5 days of bed rest. The main questions it aims to answer are: Does supplementation of ketone bodies prevent the typical decline in muscle protein synthesis, muscle size, muscle function, insulin sensitivity, and muscle mitochondrial function that occurs in response to bed rest? Researchers will compare ketone supplements (KET) to an energy matched control beverage (carbohydrates and fats) to see if the ketones can rescue the decline in muscle protein synthesis rates, muscle loss, muscle function, insulin sensitivity, and mitochondrial function due to 5 days of bed rest. This may positively impact the heath of older adults subjected to bed rest.
The purpose of the proposed project is to determine if short-term dietary supplementation of magnesium will improve performance during a series of lab-based exercise tests, will favorably modify the gut-microbiota, and will augment skeletal muscle mitochondrial function.
In this study 11 healthy volunteers will perform high intensity exercise training during 4 weeks. The exercise frequency will increase progressively during the first three weeks, followed by a fourth week with lower exercise frequency. 5 skeletal muscle biopsies will be donated throughout the study and 4 oral glucose tolerance tests will be performed after each training period.
The aim of this study is to determine whether dairy or plant based fats combined with fish oils can alter skeletal muscle mitochondrial, physical, and cognitive function.
Studies have shown that cardiac function is affected immediately after heart transplantation (HTx), but seems to recover to some extent over the first year. This immediate effect is associated with lack of oxygen in the tissue and reperfusion injury causing cellular energy depletion, mitochondrial failure and cellular damage. This condition may progress into full blown primary graft failure (PGF), characterized as deterioration of the transplanted heart, which is seen in 3-30 % of HTx patients. In addition to PGF, chronic rejection owing to cardiac allograft vasculopathy (CAV) may develop. PGF and CAV remain the major heart related mortality causes, and additional assessment and treatments are therefore needed. Acute cellular rejection (ACR) is diagnosed based on endomyocardial biopsies (EMB), which are routinely performed to ensure prober immunosuppression in HTx patients. ACR occur in approximately 25% of HTx patients, and is associated with PGF and CAV. However, mitochondrial function and integrity may prove to be a more sensitive marker of allograft rejection than endomyocardial biopsies. Therefore, assessment of mitochondrial function may allow for earlier detection of allograft rejection and dysfunction. This may be of particular importance as emerging treatments are targeting both energy substrate supply for adenosine-triphosphate generation produced by the mitochondria and mitochondrial function in the failing heart. Despite the association between graft rejection and mitochondrial function, it remains unsettled whether mitochondrial function associate with PGF, ACR and CAV. Such findings may be of prognostic importance and even elucidate new treatment targets. Hence, we evaluate the mitochondrial status in HTx patients through four studies designed to assess different aspects of the interplay between cardiac function and mitochondrial integrity and function. Hypotheses: Study 1: Primary graft pump function is correlated to mitochondrial function in the first myocardial biopsy taken from the donor heart during the operation. Study 2: Cardiac mitochondrial function improves over the first 3 months after a heart transplantation. Study 3: Heart transplant patients with moderate to severe coronary graft vasculopathy has impaired mitochondrial function. Study 4: Myocardial external energy efficiency by positron-emission tomography can be used as a marker of mitochondrial function and chronic rejection in HTx patients.
This research project aims to determine whether supplementing with a mixture of the NAD+-precursors NA, NAM, and tryptophan can stimulate skeletal muscle mitochondrial function in physically compromised, elderly humans. Outcomes are related to mitochondrial function, energy metabolism, and physical function will be investigated.
Resveratrol, a compound found in red wine and dark-skinned grapes, will improve the function of mitochondria (energy producing components) within the leg muscles of moderate functioning older adults. The investigators will look at the role Resveratrol plays in improving physical function by studying the connection of changes in mitochondrial function and changes in physical function.