The mechanism whereby bile acid micelles increase the rate of fatty acid and cholesterol uptake into the intestinal mucosal cell
about
A predominant role of acyl-CoA:monoacylglycerol acyltransferase-2 in dietary fat absorption implicated by tissue distribution, subcellular localization, and up-regulation by high fat dietMechanisms of lipid malabsorption in Cystic Fibrosis: the impact of essential fatty acids deficiencyNanostructured lipid carriers: An emerging platform for improving oral bioavailability of lipophilic drugsCloning and functional characterization of a mouse intestinal acyl-CoA:monoacylglycerol acyltransferase, MGAT2CD36 is important for fatty acid and cholesterol uptake by the proximal but not distal intestineTime-resolved fluorescence anisotropy of fluorescent-labeled lysophospholipid and taurodeoxycholate aggregatesCholesterol metabolism in manA whole-body mathematical model of cholesterol metabolism and its age-associated dysregulationLipid-based formulations for oral administration: opportunities for bioavailability enhancement and lipoprotein targeting of lipophilic drugs.Dietary fat selectively alters transport properties of rat jejunum.Spontaneous lipid transfer between organized lipid assembliesRegulatory effects of the saturated fatty acids 6:0 through 18:0 on hepatic low density lipoprotein receptor activity in the hamster.Impact of Inhibiting Ileal Apical versus Basolateral Bile Acid Transport on Cholesterol Metabolism and Atherosclerosis in Mice.Characteristics of lipids and their feeding value in swine diets.Nonlinear transcriptomic response to dietary fat intake in the small intestine of C57BL/6J miceApolipoprotein A-V is present in bile and its secretion increases with lipid absorption in Sprague-Dawley ratsDevelopment of supersaturatable self-emulsifying drug delivery system formulations for improving the oral absorption of poorly soluble drugs.Role of the gut in lipid homeostasisLipids and lipid-based formulations: optimizing the oral delivery of lipophilic drugs.Activation of Constitutive Androstane Receptor (CAR) in Mice Results in Maintained Biliary Excretion of Bile Acids Despite a Marked Decrease of Bile Acids in LiverEffects of dihydroxy bile acids and hydroxy fatty acids on the absorption of oleic acid in the human jejunum.The mechanisms of and the interrelationship between bile acid and chylomicron-mediated regulation of hepatic cholesterol synthesis in the liver of the ratBeta-glucan extracts inhibit the in vitro intestinal uptake of long-chain fatty acids and cholesterol and down-regulate genes involved in lipogenesis and lipid transport in rats.Influence of class B scavenger receptors on cholesterol flux across the brush border membrane and intestinal absorption.New insights into the molecular mechanism of intestinal fatty acid absorption.Enhancement of oral bioavailability of the poorly water-soluble drug silybin by sodium cholate/phospholipid-mixed micelles.Functions of lipids for enhancement of oral bioavailability of poorly water-soluble drugs.Steatosis in the liver.Infant digestion physiology and the relevance of in vitro biochemical models to test infant formula lipid digestion.The micellar hypothesis of fat absorption: must it be revisited?Uptake of fatty acids by jejunal mucosal cells is mediated by a fatty acid binding membrane protein.Permeation of long-chain fatty acids and alcohols in rat intestine.Effect of ursodeoxycholic acid on cholesterol absorption and metabolism in humans.Scavenger receptor class B type I reduces cholesterol absorption in cultured enterocyte CaCo-2 cells.Lack of the intestinal Muc1 mucin impairs cholesterol uptake and absorption but not fatty acid uptake in Muc1-/- mice.Dietary lipids modify the age-associated changes in intestinal uptake of fructose in rats.Interactions between bile salts, gut microbiota, and hepatic innate immunity.Modelling oral up-take of hydrophobic and super-hydrophobic chemicals in fish.Silybin, a Major Bioactive Component of Milk Thistle (Silybum marianum L. Gaernt.)-Chemistry, Bioavailability, and Metabolism.Experimental conditions affecting in vitro intestinal incorporation of palmitic acid: a methodological approach.
P2860
Q24308300-C63CAD4A-10C9-460F-8BE4-B552FAF5C4EBQ24806288-CD77B171-FCE0-4992-A82F-E1A1E21AC136Q26774831-4B7BFE62-7B9A-4439-9454-B5B3FE43605AQ28587595-9B8632AF-910F-4DA3-B1DD-1495C24ED59CQ28588690-663F2D2F-3BD3-4010-B285-A436A9E388FBQ34017434-9D91E652-5738-4C95-95B8-B5439936F973Q34051405-E22FE9FD-2111-48AA-94AA-61338371C540Q34436836-38E84F60-B033-4002-BF4C-FCE9A39A5659Q34470793-AE1D9E89-7D33-487B-985D-973444212261Q34519743-F11CA389-A384-4B71-9088-2041677D8542Q35539909-C5957166-9803-49C9-A7C8-8C8B8606E1D9Q35600330-1E74E6E5-8096-431A-9E7C-0F3647EA4026Q35737165-F4FEEA70-FEAF-4621-AF70-6E0818EFB7F1Q35881181-1E7B36B0-A0BF-49BF-B15B-F5FA7370CD3DQ35919050-E90927BC-EE77-4D3D-9C31-165674E19FD8Q36345922-61FE01A8-AB32-417F-B299-FACED3AA81FCQ36349701-7AA347C7-C20D-4A06-90C6-B6B4CCD5E292Q36660888-B5F06127-5255-4C22-88D9-11824ADBBD6FQ36748145-38E0BC5F-2864-4463-A2B4-163D006A7DC2Q36935450-C23E42CA-DEDB-4CA2-A310-6E47F1A31D9EQ37050076-EE3DFF0B-83F1-4ED9-BE5B-4C1AB4199BACQ37052668-4A0A9CDA-60FF-47B3-ABEB-B4DFA3C4C490Q37324788-64C51909-1D92-4FE5-ADB1-4B2A29211BDBQ37382146-5D645D70-856A-4297-A502-F55F02A4E93FQ37718704-D7BAA12A-7901-40F9-A8B5-148B928BE8C8Q37729227-E7FF7466-5375-4146-9EB2-2D6237B6FECAQ37965173-BD9E4223-BE00-4EC2-BAF4-0DB0317534D1Q38165140-3A533274-BD0C-463D-8CA8-FDAA200EBBE7Q38859692-112CC470-56A9-45B9-B0ED-0C2DFFB2006FQ39825904-9BA9F4C7-4BBA-428A-B8DA-89FC9DEFE3E8Q41018421-89297239-FDA1-4206-B5F2-441E0F992613Q41600850-F073BFAA-7F8E-4D4F-BBD3-3265B5DE193BQ44336596-AE64818A-AD68-45F1-981B-917CD56BA223Q44655976-2AFAE9C8-3B46-4463-8CFB-BFFB58049939Q44838177-C0110D05-34C5-4A92-9DC4-B686DF79C38EQ45129877-592FF0E7-A1BB-48A4-ABE1-3F629E7DBF05Q46314074-DD51E159-A554-400D-A885-659DEB9ED0ABQ49860455-1950A089-9E02-47F3-BFC5-7A30C2CE74B7Q50071437-946B842F-9B80-4920-B2F1-0A39E3148269Q54030291-9618ECED-EE30-4DD4-8BD6-49F8C92F01B9
P2860
The mechanism whereby bile acid micelles increase the rate of fatty acid and cholesterol uptake into the intestinal mucosal cell
description
1976 nî lūn-bûn
@nan
1976年の論文
@ja
1976年論文
@yue
1976年論文
@zh-hant
1976年論文
@zh-hk
1976年論文
@zh-mo
1976年論文
@zh-tw
1976年论文
@wuu
1976年论文
@zh
1976年论文
@zh-cn
name
The mechanism whereby bile aci ...... to the intestinal mucosal cell
@en
type
label
The mechanism whereby bile aci ...... to the intestinal mucosal cell
@en
prefLabel
The mechanism whereby bile aci ...... to the intestinal mucosal cell
@en
P2860
P356
P1476
The mechanism whereby bile aci ...... to the intestinal mucosal cell
@en
P2093
Dietschy JM
Westergaard H
P2860
P304
P356
10.1172/JCI108465
P407
P577
1976-07-01T00:00:00Z