Dynamic changes in fat oxidation in human primary myocytes mirror metabolic characteristics of the donor.
about
Electrical pulse stimulation of cultured human skeletal muscle cells as an in vitro model of exerciseAssay of the multiple energy-producing pathways of mammalian cellsUCP4 overexpression improves fatty acid oxidation and insulin sensitivity in L6 myocytesRegulation of skeletal muscle lipolysis and oxidative metabolism by the co-lipase CGI-58Calorie restriction increases muscle mitochondrial biogenesis in healthy humansExercise resistance across the prediabetes phenotypes: Impact on insulin sensitivity and substrate metabolism.Small molecule activators of SIRT1 replicate signaling pathways triggered by calorie restriction in vivoSkeletal muscle NAMPT is induced by exercise in humans.LMNA mutations, skeletal muscle lipid metabolism, and insulin resistanceMuscle Lipid Metabolism: Role of Lipid Droplets and PerilipinsSkeletal muscle fat oxidation: timing and flexibility are everything.Peroxisome proliferator-activated receptor-gamma coactivator-1alpha overexpression increases lipid oxidation in myocytes from extremely obese individualsRemodeling lipid metabolism and improving insulin responsiveness in human primary myotubes.Metabolic switching of human myotubes is improved by n-3 fatty acidsOxidative status of muscle is determined by p107 regulation of PGC-1alpha.Galactose enhances oxidative metabolism and reveals mitochondrial dysfunction in human primary muscle cellsIncreased FAT/CD36 cycling and lipid accumulation in myotubes derived from obese type 2 diabetic patients.Regulation of skeletal muscle oxidative capacity and insulin signaling by the mitochondrial rhomboid protease PARL.Bioactives of Artemisia dracunculus L enhance cellular insulin signaling in primary human skeletal muscle cultureChemical-genetic induction of Malonyl-CoA decarboxylase in skeletal muscle.Different adipose depots: their role in the development of metabolic syndrome and mitochondrial response to hypolipidemic agents.A high-fat diet elicits differential responses in genes coordinating oxidative metabolism in skeletal muscle of lean and obese individuals.Skeletal muscle mitochondria in insulin resistance: differences in intermyofibrillar versus subsarcolemmal subpopulations and relationship to metabolic flexibility.Remodeling of oxidative energy metabolism by galactose improves glucose handling and metabolic switching in human skeletal muscle cells.Acylcarnitines: potential implications for skeletal muscle insulin resistance.Altered skeletal muscle lipase expression and activity contribute to insulin resistance in humans.Energy substrate partitioning and efficiency in individuals with atherogenic lipoprotein phenotypeOverexpression of PGC-1α increases fatty acid oxidative capacity of human skeletal muscle cells.Myotubes from severely obese type 2 diabetic subjects accumulate less lipids and show higher lipolytic rate than myotubes from severely obese non-diabetic subjects.Intramuscular triacylglycerol and insulin resistance: guilty as charged or wrongly accused?Mechanisms underlying skeletal muscle insulin resistance induced by fatty acids: importance of the mitochondrial functionEffect of a 1-week, eucaloric, moderately high-fat diet on peripheral insulin sensitivity in healthy premenopausal womenNitrate enhances skeletal muscle fatty acid oxidation via a nitric oxide-cGMP-PPAR-mediated mechanism.Proteomic analysis reveals cellular pathways regulating carbohydrate metabolism that are modulated in primary human skeletal muscle culture due to treatment with bioactives from Artemisia dracunculus L.Perilipin 3 Differentially Regulates Skeletal Muscle Lipid Oxidation in Active, Sedentary, and Type 2 Diabetic MalesAdipose tissue lipin-1 expression is correlated with peroxisome proliferator-activated receptor alpha gene expression and insulin sensitivity in healthy young men.Fasting substrate oxidation in relation to habitual dietary fat intake and insulin resistance in non-diabetic women: a case for metabolic flexibility?Intramuscular lipid oxidation and obesity.Nine months of combined training improves ex vivo skeletal muscle metabolism in individuals with type 2 diabetes.Dietary sugars stimulate fatty acid synthesis in adults
P2860
Q27307073-378A9402-C51C-4CCF-AD86-D843E471456DQ27349316-A58D3C03-CFD4-49B6-9AB2-468235B3EDAFQ28576358-CA7E9662-F4F2-416C-ADE2-7D592A3BE052Q28592284-2527EBB4-FEC6-4313-B7B8-F132DE2B755AQ28763406-CB00881E-B910-499B-9A0A-87B40E157217Q30276925-79D3152B-63A1-444D-8C76-B83B2B1D2B1FQ33417863-81FAF0AA-DCEA-4A71-94D5-94C533D0B1D0Q33589034-93B37855-7CEC-4B38-85D9-331F4B32CFCEQ33786875-D1DFFE43-BA83-41D6-8793-83D343C58C5CQ33813770-513F19F2-B541-4529-ACAF-2571B1CA21D0Q33865959-479EC9DB-E50D-4D79-8D32-6C881535D02AQ33869768-DA9E642E-9FAB-4824-BE14-3EE2EB9AE549Q33961423-00110B2E-A50E-47C7-AB58-8E6CCD1C3348Q33993155-D91E97FF-B5A0-40FD-BB14-ECE4CBE88CB0Q34083134-685F0D4A-A070-4D27-9E09-7837B89671C3Q34110088-A41595B2-531F-46BD-9A27-F979D423DE0EQ34110605-134A1C1E-2239-4258-9DCE-76632428CB86Q34113727-F8D59F0E-442F-4240-B4E0-F2BCC1ABB0BCQ34308464-0C154A2D-917B-4354-8A5D-41F963372A9FQ34538203-1DDDA49D-C5EE-44FA-9F07-AF06FE62E1E6Q34591044-78F10EBA-52E3-4EAA-B6B2-2FF97A0AE3D5Q34617125-7C16E618-4A49-4BD7-BDD1-B83B1AC2EBE8Q34622538-66EAFBC8-25F6-4A26-A8EF-94630D1EC5E7Q34656257-BE6F30E1-2FE1-406B-AFA5-87E9B28476B8Q34847808-02C9F474-2425-412D-A597-BBC055314EE2Q35043414-FEB8DCC5-83DA-41D2-9CF4-550CCC12773CQ35072019-AD1C541A-0023-4D58-A790-A49F46420864Q35195606-9159DE14-BE21-4CC7-8C6D-F0C87C469AD0Q35195718-CD10F590-8FC5-4EB0-AADE-60082F742FC1Q35596985-D498F474-A80F-45CB-A387-DF0B8811146FQ35854385-D5B56DE3-D005-44FB-AB09-17001979C51DQ35860378-C1FC1CD6-13CB-406E-AF95-2E973261933FQ35875662-0EC76FBB-5DDF-42A0-850D-022612FF0603Q36007826-AB4853E9-A81F-4A1C-ACDE-CD6AB654E331Q36129873-3DAC843F-DE5A-460C-88A7-D7EEE3FB459BQ36360767-9129955D-0978-4CB1-AF51-54E3910B8C37Q36578878-76146A90-0C78-42D4-A09F-66200B18E6AFQ36632211-C3DA10C6-3C75-4DD7-8E79-4060AD39312FQ36736473-9609B14D-C09C-4C0E-8BED-5878D6FC7E22Q36898127-22821DE4-3D99-431E-AFC7-F6A450337903
P2860
Dynamic changes in fat oxidation in human primary myocytes mirror metabolic characteristics of the donor.
description
2005 nî lūn-bûn
@nan
2005 թուականի Յուլիսին հրատարակուած գիտական յօդուած
@hyw
2005 թվականի հուլիսին հրատարակված գիտական հոդված
@hy
2005年の論文
@ja
2005年論文
@yue
2005年論文
@zh-hant
2005年論文
@zh-hk
2005年論文
@zh-mo
2005年論文
@zh-tw
2005年论文
@wuu
name
Dynamic changes in fat oxidati ...... characteristics of the donor.
@ast
Dynamic changes in fat oxidati ...... characteristics of the donor.
@en
type
label
Dynamic changes in fat oxidati ...... characteristics of the donor.
@ast
Dynamic changes in fat oxidati ...... characteristics of the donor.
@en
prefLabel
Dynamic changes in fat oxidati ...... characteristics of the donor.
@ast
Dynamic changes in fat oxidati ...... characteristics of the donor.
@en
P2093
P2860
P356
P1476
Dynamic changes in fat oxidati ...... characteristics of the donor.
@en
P2093
Barbara Ukropcova
Lilian de Jonge
Michele McNeil
Olga Sereda
Steven R Smith
P2860
P304
P356
10.1172/JCI24332
P407
P577
2005-07-01T00:00:00Z