View clinical trials related to Lipid Metabolism.
Filter by:The purpose of this study is to investigate the effects of egg intake on markers of HDL function and immune inflammation in healthy adults.
There are numerous factors known to determine the relative rate of lipid metabolism at rest between and within individuals, including: biological sex, endogenous carbohydrate availability, training status and, in particular, feeding. Recent focus has been placed on the potential of alternative nutrients, nutritional supplements and pharmacological agents to modify substrate selection in favour of greater lipid oxidation (e.g. caffeine, carnitine, green tea) and/or to alter lipid absorption (e.g. caffeine, carnitine, orlistat, green tea preparations). Polyphenol-rich tea extract can have effects on lipase activity in the pancreas causing reduced fat absorption. The present study is to assess the potential for tea extract alone to be as effective at the liquid product in a western population.
Raised blood cholesterol (also referred to as blood LDL-cholesterol) is a major risk factor for developing heart disease. Dietary saturated fat is recognised as the main dietary component responsible for raising blood LDL-cholesterol, and reducing its intake has been the mainstay of dietary guidelines for the prevention of heart disease for over 30 years. However, there is very little evidence for a direct link between the intake of saturated fat and risk of dying from heart disease. One explanation for this, is that the link between saturated fat intake and heart disease is not a direct one, but relies heavily on the ability of saturated fat to raise blood LDL-cholesterol levels. This LDL cholesterol-raising effect of saturated fat is complex, and highly variable between individuals because of differences in the metabolism of dietary fat and cholesterol between people. The main aim of this study is to measure the amount of variation in blood LDL-cholesterol in healthy volunteers at the Universities of Surrey and Reading in response to lowering the amount of saturated fat in the diet to the level recommended by the government for the prevention of heart disease. This collaborative project between the Universities of Reading, Surrey and Imperial ('RISSCI-1' Blood Cholesterol Response Study') will permit identification of two subgroups of men who show either a high or low LDL-cholesterol response to a reduction in dietary saturated intake. These two groups of participants will be provided with an opportunity to participate in a similar follow-up study ('RISSCI-2') that will also take place at the University of Surrey and Reading. In this follow-up study, the participants will be asked to repeat a similar study protocol as for RISSCI-1, but undergo more detailed measurements to investigate the metabolic and genetic origins of how saturated fat is metabolised in the body and influences blood LDL-cholesterol (LDL-C).
The ability to upregulate fat oxidation at appropriate times such as during fasting, low to moderate intensity exercise and after a high fat meal, is popularly advocated. This is presumably due to the perception that a high capacity to utilise fat may improve (ultra) endurance performance and help in the regulation of body fat and metabolic diseases. In accordance, impaired fat use at rest has been associated with obesity and insulin resistance (Kelley et al., 1999). However, there is inconclusive and / or a lack of systematic evidence, especially in a large diverse range of adults, exploring: 1) Whether whole body fat use during exercise is altered in individuals with overweight or obesity compared to lean individuals 3) The intra-individual variability in whole-body fat use at rest and during exercise 4) Physiological, metabolic, lifestyle and genetic characteristics that are associated with whole-body fat use at rest and during exercise Therefore, the objectives of this study are three-fold: 1. To explore whether whole body fat use is associated with body composition 2. To explore associations between whole-body fat use and physiological, metabolic, lifestyle and genetic variables 3. To assess the intra-individual variability of whole-body fat use. This study is an observational, exploratory cross-sectional study. A wide range of 'healthy' and 'at-risk of metabolic disease' adults will be recruited. Participants will be asked to visit a laboratory at the University of Bath four times. Visit 1 is a screening and study familiarisation visit. Visits 2 and 3 are to be completed within 7-14 days and involve lifestyle monitoring (dietary and physical activity), a one-off urine and blood sample, assessment of fuel use at rest and during exercise (the latter through an incremental graded cycling exercise test to exhaustion). Visit 4 is to assess body composition via a dual-energy x-ray absorptiometry (DEXA) scan in addition to an optional skeletal muscle and / or fat tissue biopsy.
This is a pilot study to determine the optimum time and dose to draw blood samples using a tracer for HDL kinetics.
The main goal of the present study was to provide a technical basis for future studies assessing the role of cardiac lipids. More specifically, non-invasive MR-Spectroscopy (MRS) techniques will be used in this study to: 1. assess the methodological reproducibility of MRS-measurements of cardiac lipids in humans 2. investigate physiological variations of cardiac lipids by measuring day-to-day changes under identical conditions 3. determining diurnal variations of cardiac lipids in humans
A high-calcium intake can accelerate fat loss under energy-restricted diets. Part of this may be due to a shift in substrate metabolism where there is an increase in the rate of fat oxidation. However, whether high-calcium intake can influence substrate metabolism during exercise is not known. Accordingly, we aim to investigate the effect of 2 weeks of high-calcium intake on substrate metabolism during exercise.
Background: - Glucocorticoids are primary stress response hormones released from the adrenal gland when an individual is under stress. Chronic or ongoing elevation of these hormones due to prolonged stress or medical treatments can have numerous harmful effects. Researchers are interested in learning more about how these hormones affect cell growth, development, and death. To study glucocorticoid hormones, researchers plan to use the medication dexamethasone, which affects the parts of cells that respond to glucocorticoid hormones. Objectives: - To study glucocorticoid stress hormones in healthy individuals before and after receiving dexamethasone. Eligibility: - Healthy individuals at least 18 years of age. - Participants must not be using certain medications that may affect the dexamethasone test, including hormonal contraception, steroid-based drugs, and some antidepressants. Design: - This study will require an initial screening visit and a second study visit. The visits are estimated to require about 1 to 2 hours of participation over a period of up to 14 days. - Participants will be screened at visit 1 with a full physical examination and medical history, and an initial blood sample for testing. - For visit 2, participants will be asked to abstain from all food and drinks except for water for 12 hours before the appointment, and will take one tablet of dexamethasone 9 hours before the appointment. - Participants will have a second blood sample taken during visit 2, and will receive a snack after the blood is drawn.
EDUFIT is a group-Randomized Controlled Trial specifically designed to enhance physical fitness and other health-related factors in a school setting in adolescents.
The purpose of this study is to determine the partitioning of exogenous lipids in the postprandial period while a study of overfeeding. The method is based on the incorporation of a stable isotopic tracer (d31_palmitic acid, d31_C16) in lipoprotein triglycerides (TG-CHYLOMICRON and TG-VLDL) and in free fatty acids (FFA).