• The primary outcomes for this study are to better understand the molecular and cellular mechanisms of cholesterol metabolism and absorption. [ Time Frame: 5 yrs ] [ Designated as safety issue: No ]
  

Cholesterol absorption plays a key role in cholesterol homeostasis and understanding the lumenal events that play key roles in absorption remain poorly understood. The aims of the present study are fourfold: 1) To determine whether previously observed effects on cholesterol absorption during bile acid feeding are related to changes in pool size and intestinal transit or meal stimulated gall bladder emptying or plasma cholecystokinin levels. 2) To determine the effect of dietary sphingomyelin on cholesterol absorption, micellar solubilization and synthesis in normal adults and to assess the effects of intralumenal cholesterol solubilization, absorption and synthesis in adults with heterozygous mdr 3 deficiency (a defect leading to low biliary phospholipid content). 3) To determine the mechanism of action of a non-ionic detergent, Pluronic F-68, by evaluating its effect on cholesterol solubilization and distribution between micelles and vesicles, on cholesterol absorption and synthesis. 4) To evaluate the intralumenal solubilization and distribution within micelles and vesicles of biliary compared to dietary cholesterol in humans and assess the impact of ezetimibe treatment on absorption of endogenous or exogenous cholesterol by assessing absorption of human contents in the biliary diverted, rat lymph fistula model. For each of these aims, subjects will be studied while consuming well-controlled diets as outpatients with a combination of human and animal techniques. Techniques employed for human studies will include state-of-the art techniques utilizing stable isotopes and isotope ratio mass spectrometry, gas chromatography. Translational studies in animals will be used including novel techniques to measure fat absorption as well as the use of the lymph fistula rat model for assessment of lipid absorption and hamsters for assessment of bile acid and sterol synthesis. Integration of animal/human techniques will provide tools to characterize the role of modifications of the intralumenal environment on cholesterol solubilization and human cholesterol absorption and synthesis.