Metabolically active components of fat-free mass and resting energy expenditure in humans: recent lessons from imaging technologies.
about
Energy expenditure of genuine laughter.A musculoskeletal model of low grade connective tissue inflammation in patients with thyroid associated ophthalmopathy (TAO): the WOMED concept of lateral tension and its general implications in disease.High-intensity interval training improves performance in young and older individuals by increasing mechanical efficiency.Body composition changes with aging: the cause or the result of alterations in metabolic rate and macronutrient oxidation?Adaptive thermogenesis in human body weight regulation: more of a concept than a measurable entity?Specific metabolic rates of major organs and tissues across adulthood: evaluation by mechanistic model of resting energy expenditure.Examining variations of resting metabolic rate of adults: a public health perspectiveMetabolic adaptation following massive weight loss is related to the degree of energy imbalance and changes in circulating leptin.Energy Homeostasis and Body Weight before and after Cessation of Block and Replacement Therapy in Euthyroid Patients with Graves' Disease.Estimation of energy expenditure using prediction equations in overweight and obese adults: a systematic review.Four-compartment cellular level body composition model: comparison of two approaches.Metabolic slowing with massive weight loss despite preservation of fat-free mass.Correlation of adiposity indices with cardiovascular disease risk factors in healthy adults of Singapore: a cross-sectional studyRelationship of leptin, resting metabolic rate, and body composition in premenopausal hispanic and non-Hispanic White womenDeterminants of intra-specific variation in basal metabolic rate.Energy expenditure and protein requirements after traumatic injury.Issues in characterizing resting energy expenditure in obesity and after weight lossAdipose tissue resting energy expenditure and expression of genes involved in mitochondrial function are higher in women than in men.Fat-free mass and calf circumference as body composition indices to determine non-exercise activity thermogenesis in patients with diabetes.Body composition and energy metabolism following Roux-en-Y gastric bypass surgery.The endeavor of high maintenance homeostasis: resting metabolic rate and the legacy of longevityA viscerally driven cachexia syndrome in patients with advanced colorectal cancer: contributions of organ and tumor mass to whole-body energy demands.Development and validation of anthropometric prediction equations for estimation of lean body mass and appendicular lean soft tissue in Indian men and women.SF-1 expression in the hypothalamus is required for beneficial metabolic effects of exercise.Functional body composition: insights into the regulation of energy metabolism and some clinical applications.Cold and Spleen-Qi Deficiency Patterns in Korean Medicine Are Associated with Low Resting Metabolic Rate.Factors determining the risk of the metabolic syndrome: is there a central role for adiponectin?Adaptive thermogenesis with weight loss in humans.Lift weights to fight overweight.Assessment and definition of lean body mass deficiency in the elderly.The contribution of fat-free mass to resting energy expenditure: implications for weight loss strategies in the treatment of adolescent obesity.A role for exercise after bariatric surgery?Application of standards and models in body composition analysis.Adaptive Thermogenesis in Resistance to Obesity Therapies: Issues in Quantifying Thrifty Energy Expenditure Phenotypes in Humans.Obesity Energetics: Body Weight Regulation and the Effects of Diet Composition.The influence of physical characteristics on the resting energy expenditure of youth: A meta-analysis.Usefulness of standardized uptake value normalized by individual CT-based lean body mass in application of PET response criteria in solid tumors (PERCIST).Exercise Preserves Lean Mass and Performance during Severe Energy Deficit: The Role of Exercise Volume and Dietary Protein Content.Recruited brown adipose tissue as an antiobesity agent in humansLean Body Mass Harbors Sensing Mechanisms that Allow Safeguarding of Methionine Homeostasis
P2860
Q30459955-37BECBA0-4DAD-454D-ADE1-EBA8C06F8DB2Q30830185-CCF696A5-2A63-4AA1-BF75-F90C98E5FB2AQ33567511-5458BDF3-E82F-4C60-B535-DCAD0A94B6A2Q33892068-B3469D51-8E44-4E03-9233-DBEC4550A3A6Q34034159-5B11E71D-3A47-49C8-B856-8ED73EB1FE84Q34308079-09D768F5-FF5A-4B1F-B301-0F6C9815C486Q34389479-342ED83E-1A7F-44AC-AEDC-65A059D4F731Q34536253-92888E7F-28D8-4906-B1D5-B3BF6E20C37CQ35606466-F78CBA91-E1E7-4A00-BC8C-BC6C72C94452Q35938911-B3590FC0-F460-4EF4-AEC0-1633C50CE397Q36012732-58E5E7DD-E72E-492A-A227-A82884B2B719Q36069800-870298B8-4C4C-429D-95EE-0DB12E6BF20DQ36072404-AEBE4BCF-0179-43EE-A89C-00B57B4EC598Q36255686-A585375A-2182-46FA-A8E9-BE2073FF1995Q36508499-79A9EDAF-BE97-4BF3-A8C2-462E960B9FA4Q36602386-F08570F2-8930-445B-B1E4-9C35774E5C4CQ36712862-6C6BF010-86F9-44C5-95A3-D0C2270AC78CQ36788572-8348FB87-A50A-4F52-BBEE-EFB6933AF8E2Q36843892-5680F631-3653-483C-8FFF-DC5F5F3FC112Q37091196-814B09A0-F171-4C5C-8E06-E72627280208Q37104245-034A10DB-51E5-44C0-9ACE-63142B0098BCQ37154729-A8F5DA94-1C38-44BE-9300-997007186236Q37235061-5C7FDE2C-4B47-49B2-A977-F8DCF000303FQ37429747-EB321E54-A378-4EA5-8A9E-A4EF5695FEE7Q37558167-53CDCF89-6321-4DCC-B396-CDBB2BB85407Q37711727-21329413-F138-4F34-B9C4-AD844B0A1D28Q38077655-0E4F347F-4ED0-4488-ACEC-2DD32B6CFAF0Q38081139-6F70E979-8946-46C2-83A8-DBE0D3420385Q38194629-8F8ACF1E-31DE-4DEE-A83D-06E0CFA974D8Q38241477-3DA4AE49-0241-4CD1-9729-2189CC315E82Q38282383-E71F749E-ED04-43EB-BC74-8DE4ED920FD6Q38558026-F65DE042-B2B2-4765-8089-82C0FD45CCC5Q38626276-89568AD4-A5BA-468F-8F3A-5D9BE7B87ADFQ38655865-486AEEBA-CF92-4A0A-A669-F615121EFA4CQ38963486-232EC113-24D6-450D-9C06-8AB9DAB12A58Q39024414-CC717336-9DEB-4A77-A8CE-870C52F771D5Q40000275-374BCAB3-03A0-4691-AD31-04BCFC84CBDEQ41097150-BDD3B935-1615-4515-BD4E-AB0604AE60D0Q41890383-91A3956D-3EE9-47A5-A90C-BC424BBB0A40Q42368268-AB1985FE-82D7-42C8-B366-6FCD6ADFCFE8
P2860
Metabolically active components of fat-free mass and resting energy expenditure in humans: recent lessons from imaging technologies.
description
2002 nî lūn-bûn
@nan
2002 թուականի Մայիսին հրատարակուած գիտական յօդուած
@hyw
2002 թվականի մայիսին հրատարակված գիտական հոդված
@hy
2002年の論文
@ja
2002年論文
@yue
2002年論文
@zh-hant
2002年論文
@zh-hk
2002年論文
@zh-mo
2002年論文
@zh-tw
2002年论文
@wuu
name
Metabolically active component ...... ons from imaging technologies.
@ast
Metabolically active component ...... ons from imaging technologies.
@en
Metabolically active component ...... ons from imaging technologies.
@nl
type
label
Metabolically active component ...... ons from imaging technologies.
@ast
Metabolically active component ...... ons from imaging technologies.
@en
Metabolically active component ...... ons from imaging technologies.
@nl
prefLabel
Metabolically active component ...... ons from imaging technologies.
@ast
Metabolically active component ...... ons from imaging technologies.
@en
Metabolically active component ...... ons from imaging technologies.
@nl
P2093
P2860
P1433
P1476
Metabolically active component ...... ons from imaging technologies.
@en
P2093
Bosy-Westphal A
P2860
P304
P356
10.1046/J.1467-789X.2002.00057.X
P577
2002-05-01T00:00:00Z