View clinical trials related to Fatty Acid Metabolism.
Filter by:Hypotension with potentially serious consequences for organ perfusion is a common complication in extracorporeal procedures such as hemodialysis / hemofiltration. The exact reasons for this are still insufficiently clarified. Probably periinterventional vasorelaxant released substances play a crucial role in these procedures. These substances could be due to contact of blood cells with the Membrane in the dialyzer / hemofilter arise. In this project the hypothesis will be checked, if EETs / DHETs are released by Erythrocytes during hemodialysis and thus act as potential candidate products for the result of hypotonic phases in the Dialysis. We will determine differences in RBC fatty acids profiling in hemodialysis patients before and after dialysis intervention. Furthermore a matched control group of healthy individuals will be profiled. RBC fatty acids profiling will be achieved by using targeted HPLC-MS mass spectrometry. It is believed that during hemodialysis / HLM / CVVH there is an increase in EETs / DHETs in the serum and in the erythrocytes. It is believed that shear forces play an important role in the release of erythrocyte EETs / DHETs.
Obstructive sleep apnea syndrome (OSA) is a disease affecting 5-15% of population and 50-80% of type 2 diabetes mellitus (T2DM) and obese subjects. OSA causally contributes to the development of glucose intolerance and T2DM. The project is targeting the gap in providing effective treatment of metabolic impairments associated with OSA, particularly T2DM. In contrast to proved benefits of OSA treatment with CPAP (continuous positive airway pressure) on cardiovascular morbidity/mortality, studies on the impact of CPAP on diabetes control are disappointing. In fact, OSA-induced metabolic impairments might not be reversible with CPAP treatment, as investigators suggested recently. Clearly, the search for additional treatments, probably pharmacological, is warranted. Investigators hypothesize that elevated levels of free fatty acids (FFA), as detected in OSA patients, are linking OSA with the T2DM development. The aim of the study is to target adipose tissue and muscle dysfunction leading to elevated FFA and develop thus novel pharmacological treatments based on lipolysis inhibition and stimulation of FFA oxidation.
We will test the following hypotheses: 1. The activity of the desaturating/elongating enzymes assessed by the in vivo conversion of deuterated a-linolenic and linoleic acids to DHA and AA, respectively, will be related to the duration of gestation and to postnatal age. 2. Dietary w-3 and w-6 LCPUFAs in human milk or DHA and AA supplemented formula will inhibit the desaturation/elongation of deuterated a-linolenic and linoleic acids demonstrating in vivo inhibition of the metabolic pathway by respective products. Present evidence suggests that the parent essential fatty acids (EFA), linoleic acid (18:2 w-6) and a-linolenic acids (18:3 w-3) are insufficient to fully satisfy EFA nutrition during early life in the human. A possible need for long chain (LC, longer than 18 C chain length) EFAs in the human is suggested by the accretion rates of elongated and desaturated products in the developing fetus; the altered plasma and red cell fatty acid patterns, and the abnormal visual function observed in infants receiving solely the parent EFAs; and by the relatively high concentration of LC EFAs in human milk. Most milk formula, as compared to human milk, are lower in oleic acid, higher in linoleic, have little a-linolenic acid and virtually no LC w-3 or w-6 polyunsaturated FA (LC PUFA). This study will evaluate the capacity of human infants to form w-3 and w-6 LCPUFAs from the parent EFAs as affected by developmental stage and dietary EFA supply. The precursors will be labeled with deuterium and the products analyzed by gas chromatography / mass spectrometry GC/MS. The main products of the desaturation / elongation pathway are docosahexaenoic (DHA) and arachidonic (AA) acids for the w-3 and w-6 series, respectively. Infants will be fed human milk or formulas with or without supplemental LCPUFAs as part of a study to evaluate the effect of EFAs on CNS functional development. Infants included in this study of the effect of developmental stage on EFA desaturation/elongation will be 2-5 days of age (before any fat is administered enterally or parenterally) and 28, 32, 36 or 40 weeks gestation. In addition, infants born at 28 and 40 weeks gestation will be studied 2 and 6 weeks postnatally after dietary fat has been provided for at least 7 days and energy intake is sufficient to assure growth. To evaluate the effect of dietary EFA on DHA and AA formation we will assess elongation/ desaturation in infants receiving 3 diets: human milk (which contains w-3 and w-6 LCPUFAs); cow milk based formula providing 18:2 w-6 and 18:3 w-3 but no LCPUFAs; or formula supplemented with added LCPUFAs (DHA and AA). This study should provide new information on the effects of developmental stage and w-3 and w-6 LCPUFA supply in determining the activity of EFA elongation/desaturation in the human. This knowledge may help in improving early neonatal nutritional practices to assure meeting the EFA needs of the developing CNS.