about
Metabolic syndrome: A review of the role of vitamin D in mediating susceptibility and outcomeCross-talk between bile acids and intestinal microbiota in host metabolism and healthExploratory Metabolomics Profiling in the Kainic Acid Rat Model Reveals Depletion of 25-Hydroxyvitamin D3 during Epileptogenesis.Bile acid signaling in metabolic disease and drug therapyEmpirical Validation of a Hypothesis of the Hormetic Selective Forces Driving the Evolution of Longevity Regulation MechanismsThe Yin and Yang of bile acid action on tight junctions in a model colonic epithelium.Mechanistic Modeling Reveals the Critical Knowledge Gaps in Bile Acid-Mediated DILIProtective effects of farnesoid X receptor (FXR) on hepatic lipid accumulation are mediated by hepatic FXR and independent of intestinal FGF15 signalVitamin D modulates biliary fibrosis in ABCB4-deficient mice.Mechanisms underlying the anti-aging and anti-tumor effects of lithocholic bile acidExplanation of colon cancer pathophysiology through analyzing the disrupted homeostasis of bile acids.Insights on the human microbiome and its xenobiotic metabolism: what is known about its effects on human physiology?Inhibition of ileal bile acid transporter: An emerging therapeutic strategy for chronic idiopathic constipation.A Comprehensive Evaluation of Steroid Metabolism in Women with Intrahepatic Cholestasis of Pregnancy.A Diet-Sensitive BAF60a-Mediated Pathway Links Hepatic Bile Acid Metabolism to Cholesterol Absorption and AtherosclerosisRole of glucuronidation for hepatic detoxification and urinary elimination of toxic bile acids during biliary obstruction.Determination of 7α-OH cholesterol by LC-MS/MS: Application in assessing the activity of CYP7A1 in cholestatic minipigs.Hypothalamic-autonomic control of energy homeostasis.The Influence of Bariatric Surgery on Serum Bile Acids in Humans and Potential Metabolic and Hormonal Implications: a Systematic Review.Lithocholic acid attenuates cAMP-dependent Cl- secretion in human colonic epithelial T84 cells.The Contributing Role of Bile Acids to Metabolic Improvements After Obesity and Metabolic Surgery.The cholangiocyte primary cilium in health and disease.Therapeutic potential of Rhizoma Alismatis: a review on ethnomedicinal application, phytochemistry, pharmacology, and toxicology.The SWI/SNF chromatin-remodeling factors BAF60a, b, and c in nutrient signaling and metabolic control.Cyp3a11 is not essential for the formation of murine bile acids.Role of AMP-activated protein kinase α1 in 17α-ethinylestradiol-induced cholestasis in rats.Synthesis and quantitative structure-property relationships of side chain-modified hyodeoxycholic acid derivatives.Comparative potency of obeticholic acid and natural bile acids on FXR in hepatic and intestinal in vitro cell models.Huangqi Decoction Alleviates Alpha-Naphthylisothiocyanate Induced Intrahepatic Cholestasis by Reversing Disordered Bile Acid and Glutathione Homeostasis in Mice.Identification and characterization of a novel PPARα-regulated and 7α-hydroxyl bile acid-preferring cytosolic sulfotransferase mL-STL (Sult2a8).Essential roles of bile acid receptors FXR and TGR5 as metabolic regulators
P2860
Q26799612-147AEDE7-7359-4BB2-854D-A991A9E057B7Q27026925-AD4C4C1B-F8DC-479B-A578-232AC68772D8Q27318172-E8FF6F90-9BE9-4B29-863E-E5EF42A5582AQ28244875-C70E4DF2-76D8-4474-B04C-9816FF7D02BDQ28817899-0658EC6F-D6C2-47B3-9938-C11A2DDA9703Q33740929-97F7E1BE-324D-45BC-A96E-726749A80DF8Q33994553-5DEBFB6A-4B71-44E2-B08D-74B2DAF76743Q34098522-9A00D79E-7A1A-4EB9-B3DD-3D19243CC606Q34104332-EBB2BE00-0642-42F7-AF79-0D48AE5534FFQ34358930-770257CE-B448-4A52-8F82-903D3A4C569AQ35207180-43FDE7A1-DF1E-4955-B5DE-40B052F15D1BQ35492374-A0F20901-3DD8-4557-AC71-6420111CF3E8Q35783889-9D3E6AC5-03B3-4E92-8467-4FE2BD7C4693Q36095783-170F0B8E-0C73-4C9D-B86F-A3421F178AFFQ36327698-9047EC9C-DF0A-4D63-9A37-2C913690FC53Q37309043-83268A06-8CED-4609-92AD-D0898506CCB3Q37711000-169C6A4A-C4B4-4B64-BEBA-A71842A50481Q38531855-7FFDE6D8-8533-4336-9572-57BA0E4FA1F1Q38579826-9405DB07-80D0-4B9D-8D2D-88F9D2AA0754Q38778372-5E763B2D-CF1B-43FE-8BFA-50A6614E3589Q38913696-E5EB94AB-3F28-433E-9BBB-24AEF01E6720Q39381392-7EFFBDFE-51B4-46E2-820F-5237E611DCB4Q39405127-9EF8007C-20C5-4C2D-90D3-C65EA3C0BE5CQ39422236-7C9EDCC5-7F89-4388-8D1F-5CABEEC8443EQ41682276-DFAB2DBC-06AE-444A-ABD6-507964900BF3Q42697966-04A8CF71-050E-4BC6-A0AA-5D68DE635F5DQ44134783-0E97E52A-D5D4-41C8-9293-EF854393DB33Q47145401-CC2E0DCF-744F-4BAE-832F-58C5772A0E16Q47222024-6E679782-83FE-4472-AB5A-54A74155F871Q51035549-761FC182-DA62-4DB3-B54D-C0678FDEC376Q58147741-F2C3FC6C-3FB5-4C38-A503-A41D5999256D
P2860
description
article científic
@ca
article scientifique
@fr
articol științific
@ro
articolo scientifico
@it
artigo científico
@gl
artigo científico
@pt
artigo científico
@pt-br
artikel ilmiah
@id
artikull shkencor
@sq
artículo científico
@es
name
Nuclear receptors in bile acid metabolism
@en
type
label
Nuclear receptors in bile acid metabolism
@en
prefLabel
Nuclear receptors in bile acid metabolism
@en
P2860
P1476
Nuclear receptors in bile acid metabolism
@en
P2093
John Y L Chiang
Tiangang Li
P2860
P304
P356
10.3109/03602532.2012.740048
P407
P577
2013-02-01T00:00:00Z