Comparison of exogenous adenosine and voluntary exercise on human skeletal muscle perfusion and perfusion heterogeneity.
about
The Circulatory and Metabolic Responses to Hypoxia in Humans - With Special Reference to Adipose Tissue Physiology and ObesityCirculatory model of vascular and interstitial distribution kinetics of rocuronium: a population analysis in patients.Greater glucose uptake heterogeneity in knee muscles of old compared to young men during isometric contractions detected by [(18)F]-FDG PET/CT.Non-invasive physiological monitoring of exercise and fitness.Local heating, but not indirect whole body heating, increases human skeletal muscle blood flowOrgan-specific physiological responses to acute physical exercise and long-term training in humans.Increasing exercise intensity reduces heterogeneity of glucose uptake in human skeletal musclesMyocardial perfusion reserve compared with peripheral perfusion reserve: a [13N]ammonia PET studyControl of muscle blood flow during exercise: local factors and integrative mechanismsMechanical effects of muscle contraction increase intravascular ATP draining quiescent and active skeletal muscle in humansEffect of nitric oxide synthase inhibition on the exchange of glucose and fatty acids in human skeletal muscle.Mechanisms for the control of local tissue blood flow during thermal interventions: influence of temperature-dependent ATP release from human blood and endothelial cells.Skeletal muscle vasodilatation during maximal exercise in health and disease.Peripheral circulation.The association of cardiorespiratory fitness with endothelial or smooth muscle vasodilator function.[18F]-FDG positron emission tomography--an established clinical tool opening a new window into exercise physiology.Simultaneous measurement of macro- and microvascular blood flow and oxygen saturation for quantification of muscle oxygen consumption.Regulation of human skeletal muscle perfusion and its heterogeneity during exercise in moderate hypoxia.Inhibition of α-adrenergic tone disturbs the distribution of blood flow in the exercising human limb.Evaluation of pharmacokinetic models for perfusion imaging with dynamic contrast-enhanced magnetic resonance imaging in porcine skeletal muscle using low-molecular-weight contrast agents.Effect of adipose tissue thickness, muscle site, and sex on near-infrared spectroscopy derived total-[hemoglobin + myoglobin].Rest-Stress Limb Perfusion Imaging in Humans with Contrast Ultrasound Using Intermediate-Power Imaging and Microbubbles Resistant to Inertial Cavitation.The effect of nitric oxide synthase inhibition with and without inhibition of prostaglandins on blood flow in different human skeletal muscles.Regulation of subcutaneous adipose tissue blood flow during exercise in humans.Effects of adenosine, exercise, and moderate acute hypoxia on energy substrate utilization of human skeletal muscle.Skeletal muscle blood flow and oxygen uptake at rest and during exercise in humans: a pet study with nitric oxide and cyclooxygenase inhibition.Positron emission tomography detects greater blood flow and less blood flow heterogeneity in the exercising skeletal muscles of old compared with young men during fatiguing contractions.The effect of acute exercise with increasing workloads on inactive muscle blood flow and its heterogeneity in humansPlasma Nucleotide Dynamics during Exercise and Recovery in Highly Trained Athletes and Recreationally Active Individuals
P2860
Q28076823-50EEA302-ACCB-4477-A5E2-02EA3821EEE1Q30318525-2EB9693E-85F5-40D6-97AD-EB693E64B629Q33672032-60171C71-6346-42C7-BBFD-02CAC2C05537Q33786361-70925A73-BA1A-4486-B012-88520109D7C3Q33934973-FEE2942E-BEC3-4621-AFC7-0921FE854516Q34445824-90FB382C-EE22-4485-88C2-8D52339586E4Q34533282-02C69AD9-32A3-467E-B4ED-FC76C0DB73C0Q34751315-F2B6813D-48EC-4885-B698-17F0E111EFD7Q35170190-1257B2ED-E71D-4866-9873-B813DE9EF138Q36787416-90509F29-23E3-44DF-93BB-935675019797Q36940489-1A011DD6-F910-4F43-A966-63A5DAB630E3Q37718039-14B74B62-274A-41D5-830C-7DB396F1B56DQ38048737-76BB2AF4-18AD-4773-A8D1-2541BE8C3DF3Q38111280-59246942-B107-4542-B3AE-622FBF3062CCQ38258729-405E4CD1-7A6B-43B1-A280-8F597CD17DF1Q38376248-143F90C9-3C0F-415A-82AA-ED1273D534A2Q38790015-7B7F9E81-73D8-42F2-B0C3-861C2DC92272Q43081547-0D896348-7D84-4A79-B66C-54229777E642Q44187589-D54084C3-35EB-4CA4-97C0-DB94B38EA2F2Q47178339-9695EF9D-8870-40D8-8DEF-1BF0A9BFBD4BQ47945507-F8B35D8C-0F85-4229-A544-C2341B9E7D63Q47958985-38AE6283-2C41-4548-8005-BAA6705DA8D0Q48246450-9452A78A-4EB9-41E7-8E0F-AFE9FB6CC617Q53181844-712C0293-F955-4BC5-A116-B961B8FB95B2Q53188313-7C52360D-A51D-465B-9603-F4179E381898Q53248550-2CB260BE-E41B-4D01-AEC3-4EDDB8B45557Q54576774-4790752B-3B4C-4637-BD0D-A1D47D7A650CQ57622162-C6487298-4845-4C7D-9F7A-61DAEAE3130DQ58577734-42E03647-8068-4DBD-B44C-E4A2FC622A99
P2860
Comparison of exogenous adenosine and voluntary exercise on human skeletal muscle perfusion and perfusion heterogeneity.
description
2009 nî lūn-bûn
@nan
2009年の論文
@ja
2009年学术文章
@wuu
2009年学术文章
@zh
2009年学术文章
@zh-cn
2009年学术文章
@zh-hans
2009年学术文章
@zh-my
2009年学术文章
@zh-sg
2009年學術文章
@yue
2009年學術文章
@zh-hant
name
Comparison of exogenous adenos ...... n and perfusion heterogeneity.
@en
Comparison of exogenous adenos ...... n and perfusion heterogeneity.
@nl
type
label
Comparison of exogenous adenos ...... n and perfusion heterogeneity.
@en
Comparison of exogenous adenos ...... n and perfusion heterogeneity.
@nl
prefLabel
Comparison of exogenous adenos ...... n and perfusion heterogeneity.
@en
Comparison of exogenous adenos ...... n and perfusion heterogeneity.
@nl
P2093
P2860
P50
P1476
Comparison of exogenous adenos ...... n and perfusion heterogeneity.
@en
P2093
Ilkka Heinonen
Juha E Peltonen
Jukka Kemppainen
Kimmo Kaskinoro
Markus M Lindroos
Pirjo Nuutila
Robert Boushel
P2860
P304
P356
10.1152/JAPPLPHYSIOL.00745.2009
P407
P577
2009-11-25T00:00:00Z