View clinical trials related to Metabolic Disturbance.
Filter by:The number of people with diabetes is rising. One of the major causes of premature death in diabetes is heart failure (HF). This is when the heart cannot pump blood effectively, and this may be related to abnormalities in energy production in the heart muscle. In healthy people, the heart muscle cells show flexibility and can use both sugar and fat molecules for energy production. Although burning fat provides more energy, this process requires more oxygen than burning sugars. As a result, fat is a less efficient fuel for the heart compared to sugars, especially in situations where the energy and oxygen needs are higher, such as during exercise. The investigators propose that the heart muscle in patients with type 2 diabetes relies heavily on fat for energy provision, and fails to burn more sugar molecules for energy provision during exercise to more efficiently use oxygen. Fat and sugar uptake by the heart can be detected by the difference between the blood sugar and fat levels delivered to the heart and returning from the heart, both at rest and also when the heart is working faster during Dobutamine infusion. Dobutamine is a drug frequently used to mimic exercise, and get the heart running faster during medical tests. To test the hypothesis, the investigators will assess fat and sugar uptake by the heart at rest and when the heart is running faster, in patients with type 2 diabetes undergoing investigations to rule out coronary disease. Heart function, and blood supply to heart muscle, at rest and during Dobutamine infusion, will also be measured using MRI scanning. The same tests will be performed in people without diabetes for comparison. It will help understand diabetic heart disease and which aspects may be targeted with new treatments.
This study aims to measure skeletal muscle metabolism in vivo during exercise using the non-invasive Magnetic Resonance Spectroscopy (MRS) technique. Specifically, phosphocreatine (PCr) kinetic and Acetylcarnitine levels will be determined at resting, during exercise and during the recovery post exercise. The target population is adult healthy men, with a wide range of maximal physical capacity.
The Cyprus International Institute for Environmental and Public Health of the Cyprus University of Technology is planning a pilot study of health indicators in relation to spatially varying climatic conditions ranging from the city to the mountainous environment. The purpose of the project is to understand the effect of fluctuations in external climatic conditions on the human body temperature and metabolic biomarkers or stress hormones. Climate change phenomena such as protracted heat waves that create areas with even higher temperatures, especially in urban centers, may have a negative impact on human health. The effects may be acute for an individual with the appearance of discomfort and headaches, while chronic exposures to high air temperatures for the general population have been linked with premature mortality and cardiovascular diseases. Due to climate change that is hitting hard the Mediterranean, these temperature changes have been more and more common in Cyprus in recent years. One of the usual ways of dealing with high temperatures is the use of air conditioners. With sudden and frequent temperature changes during the day, the human body is subject to thermal shock for varying duration and number of times, having wear and tear consequences for the human physiology. The investigators hypothesized that the number, duration and frequency of human exposures to wide gradient (> 8 ° C) of air temperature changes may be related to potential health problems. An intervention potentially reducing the health risk associated with extended exposure to high temperatures in the summer for Cypriots may be the temporary (for a few days or hours) stay in the villages of mountainous area. Most of the mountain communities in Cyprus have consistently lower mean ambient air temperatures of about 10 degrees Celsius than those in the cities, so the investigators anticipate not observing the metabolic hormone alterations induced while being in the city environment.
Usage of osmotic agents is a standard practice in neuroanesthesia since cerebral edema is a very common situation for patients with pathology in the brain. Cerebral edema is defined as the accumulation of fluid in the intracellular or extracellular compartments of the brain. Among other situations that have nothing to do with the brain, a supratentorial pathology such as a tumor, traumatic injury or an aneurysm, will lead to disruption of blood-brain barrier, and energy crisis of the cells that will cause mainly vasogenic and cytotoxic cerebral edema. The most common monitoring method for "measuring" cerebral edema is ICP (intracranial pressure) in which normal values are (with differences in the bibliography) 10-15 mmHg. The osmotic agents used most in neuroanesthesia are mannitol 20% and hypertonic NaCl 7.5% or 3%. Their brain relaxation effectiveness is supposed to be quite the same between the two different agents. Their main difference is that mannitol induces diuresis. Also, electrolyte disorders are another possibility after mannitol infusion. On the other hand, NaCl 7.5% causes vasodilation, does not induce diuresis and hemodynamically, even though it reduces SBP, it raises CO because of its excessive vasodilation. But both reduce cerebral edema due to the change of osmotic pressure in the vessels, that leads to extracting water from brain cells. A supratentorial craniotomy is de facto worsening the oxygenation and metabolism condition of the surgical site, adding to the problem the intracranial pathology causes in the first place. So if oxygen provided is low and the metabolic rate is high, the rate of anaerobic metabolism will raise. Measuring the oxygen in the jugular bulb is the most reliable monitoring method of cerebral oxygenation and metabolism. It becomes evident that optimization of cerebral oxygenation during a craniotomy will possibly affect the outcome of a patient, by improving it. So, if any superiority of one osmotic agent over the other could be demonstrated this will be very helpful in the decision making in routine clinical practice.
Despite exercise training decrease blood fasting glicaemy in 'average' terms, there is a wide inter-individual variability after exercise training explored mainly in adults but not in adults with prediabetes comorbidities. Thus, is yet unknown the effects and influence of the concurrent training (CT) eliciting responders (R) and non-responders (NR) cases (i.e., percentage of subjects who experienced a non-change/worsened response after training in some metabolic outcomes).
The PURPOSE of this study is to investigate the combined influence of 2-weeks blueberry ingestion and banana ingestion (during exercise) on performance and in mitigating metabolic perturbation, immune dysfunction, and increase in inflammation following a 75-km cycling time trial. We hypothesize that the combination of 2-weeks ingestion of blueberries (versus placebo) and acute ingestion of bananas (versus water alone) during 75-km cycling will: 1. Enhance performance. 2. Attenuate the magnitude of metabolic perturbation due to exercise (using a targeted panel of metabolites) which may be associated with increased plasma levels of beneficial gut-derived phenolics. 3. Attenuate post-exercise inflammation (as measured with cytokines, muscle damage markers, regulatory lipid mediators, ex-vivo monocyte cell cultures, and targeted immune proteins including S100A8 and S100A12). 4. Counter post-exercise downturns in innate immune function (natural killer cell lytic activity), and viral defense (using an ex-vivo cell culture with Hela cells).
In this study, we aim to determine whether the combination of Ascorbic Acid (Vitamin C), Thiamine (Vitamin B1), and Corticosteroids improves the trajectory of organ failure and reduces mortality in patients with sepsis and septic shock as compared to placebo.
This experiment consists on a 20-day reduction in daily step in free-living active individuals to induce physical inactivity. This will be used to test the efficacy of the anti-oxidant cocktail we aim to test as a new countermeasure in 2016 during the 60-d bed rest planed by ESA/CNES. The objective of this study is to investigate whether the cocktail of natural antioxidants XXS-2A comprising vitamin E and coupled with omega-3 helps to prevent and / or reduce the glucose intolerance and improve oxidative defenses induced by 20 days of physical inactivity through daily step reduction Although physical inactivity is reported to affect glucose tolerance within days of inactivity, we selected a period of 20 days for the effect of the cocktail to take place and assess secondary molecular mechanisms. The effect of this short period of inactivity on metabolism will moreover be boosted during the last 10 days by taking fructose, a sugar found in abundance in fruits, honey and juices, which is known to quickly trigger metabolic deregulation.
This study is a randomized crossover trial to compare the effectiveness of interrupting SB on glucose homeostasis in the lab and free-living settings. All participants (N=56) will complete one screening visit to determine eligibility, complete at fitness test, and body composition analysis by bioelectrical impedance. After 7-21 days, all participants will complete two 3-hour in-lab oral glucose tolerance tests (spaced 7-21 days apart). Prior to the in-lab OGTT visits, participants will wear an activity monitor for 7 days on the right thigh. The experimental conditions for the OGTTs will be: 1) 3-hour OGTT of continuous sitting; and 2) 3-hour OGTT with sitting interrupted every 30 minutes with 3-minutes of moderate intensity walking on a treadmill. There will be a 7-21 day washout period between the OGTT visits. In addition, a subset of participants (N=12) who meet inclusion criteria and who successfully complete both OGTT visits will complete a second randomized crossover trial in the free-living environment. The experimental conditions for the free-living components will be: 1) 4 days of habitual sedentary behaviors; and 2) 4 days of prompted short exercise breaks during times in which sedentary behaviors have exceeded 30 minutes. Participants in the free-living trial will wear an activity monitor and a continuous glucose monitor.
Nicotinamide riboside (NR) has been available over the counter as a nutraceutical (Niagen®, ChromaDex, Inc.) since the summer of 2013. However, classical pharmacokinetic (PK) data for NR have not been reported in humans. This study will use a recently-developed, whole blood assay for NR to assess the pharmacokinetics of NR at a maximum dose of 1000 mg twice daily, and will collect history, physical examination and laboratory data to determine the safety and tolerability of NR in eight, healthy volunteers. In addition, whole blood nicotinamide adenine dinucleotide (NAD) levels will be measured at each time point, to determine whether this NR dose significantly raises whole blood NAD levels.