about
N-acetylcysteine reverses cardiac myocyte dysfunction in a rodent model of behavioral stressThe Role of Mitochondrial Reactive Oxygen Species in Cardiovascular Injury and Protective StrategiesMitochondrial reactive oxygen species: a double edged sword in ischemia/reperfusion vs preconditioningBang-bang model for regulation of local blood flowMitochondrial dysfunction and sarcopenia of aging: from signaling pathways to clinical trialsCardiac mitochondria and reactive oxygen species generationCorruption of coronary collateral growth in metabolic syndrome: Role of oxidative stress.The endothelium: influencing vascular smooth muscle in many ways.Redox signalling and cardioprotection: translatability and mechanismHydrogen sulfide as endothelium-derived hyperpolarizing factor sulfhydrates potassium channels.Overexpressing superoxide dismutase 2 induces a supernormal cardiac function by enhancing redox-dependent mitochondrial function and metabolic dilationRegulation of Coronary Vasomotor Function by Reactive Oxygen Species.Requisite Role of Kv1.5 Channels in Coronary Metabolic Dilation.Open-loop (feed-forward) and feedback control of coronary blood flow during exercise, cardiac pacing, and pressure changesVasomotor regulation of coronary microcirculation by oxidative stress: role of arginase.Renal medullary oxidative stress, pressure-natriuresis, and hypertension.Calcium influx-dependent differential actions of superoxide and hydrogen peroxide on microvessel permeabilityTranscriptional and phenotypic changes in aorta and aortic valve with aging and MnSOD deficiency in mice.Targeted detoxification of selected reactive oxygen species in the vascular endothelium.Resolution of mitochondrial oxidant stress improves aged-cardiovascular performance.Role of genetic polymorphisms of ion channels in the pathophysiology of coronary microvascular dysfunction and ischemic heart disease.Role of potassium channels in coronary vasodilation.Role of ion channels in coronary microcirculation: a review of the literature.Thrombospondin-1, free radicals, and the coronary microcirculation: the aging conundrum.Heteromeric complexes of aldo-keto reductase auxiliary KVβ subunits (AKR6A) regulate sarcolemmal localization of KV1.5 in coronary arterial myocytes.Kv1.3 channels facilitate the connection between metabolism and blood flow in the heart.Coronary artery spasm related to thiol oxidation and senescence marker protein-30 in aging.Senescence marker protein-30 (SMP30) deficiency impairs myocardium-induced dilation of coronary arterioles associated with reactive oxygen species.Hydrogen peroxide activates store-operated Ca(2+) entry in coronary arteries.Coronary microvascular Kv1 channels as regulatory sensors of intracellular pyridine nucleotide redox potential.Multiple mechanisms mediating carbon monoxide inhibition of the voltage-gated K+ channel Kv1.5.Antineoplastic Drug-Induced Cardiotoxicity: A Redox Perspective.Diabetes Mellitus and Ischemic Heart Disease: The Role of Ion Channels.The Coronary Microcirculation in Health and Disease
P2860
Q23912809-C85ECD31-B359-442F-9C4A-BACB27ECCD68Q26747310-EB4053E2-5FB8-4F19-AE65-8809EC5CC3C0Q26861219-DCF9CF76-1D35-4C86-AE1C-DA2221DFD222Q26998655-E3B15324-8F60-4D9F-B0E4-2778FA50F5AFQ27022354-038742A9-5A40-4EE4-973B-734D4FF82338Q33987941-9E774A82-0EEE-45AD-A19C-C6B70839ECF5Q34444798-A2EB2D60-2ED3-4D8F-A5A4-0E29A84077E8Q34638538-58BAAF45-530A-4740-B631-EA09387B51BAQ35286322-5A6F9CDF-149E-4DFA-BCFE-51CBC58277E2Q35603720-635D5F1B-E546-4BE6-9B36-FF4D28DEFE81Q36269372-3342629A-2E50-4D47-9206-A7AAF6F90301Q36737180-3D93A620-CD0E-47C1-88E4-7BF593537180Q36832399-4A4F323F-82F8-4D99-AA2B-B506650F4BCEQ37071887-8D2176DF-C053-4DDD-83A6-8930D537F9C3Q37102697-BB165105-F646-4AB5-9B8D-63F3CE9A892DQ37137810-47D7E7DF-FF0F-4FC5-AB7C-C3FB5AA77E25Q37162543-A15E94B9-B2A5-47CE-AA41-3ED7C48E0773Q37342163-31DAE839-96EF-4E12-A5B5-DA56688E3D38Q37416432-75C837F7-46EA-4258-AF2B-1C1EF9BBDACCQ37486082-5BD6B915-AC33-4700-AFA3-CB4528A4136BQ37501931-3E39FE43-979B-4C29-B048-28CB0DC67FE1Q37733981-BE4B79C8-6E6B-4715-B1F2-0024F65979A4Q38158224-FBBC01EC-A68D-47EC-84FA-5FB12072F287Q38648723-4E814894-DE34-4F28-9015-22C187FACA50Q38876479-E2B4A073-D369-4588-8E62-E347AF77941BQ39306627-7A47B0B7-4723-4EE8-95C2-EDB92468C549Q41859845-21DF0545-3B7B-4FF0-992B-6BD809E25783Q41874201-8699F80D-D27B-4DFE-8E62-E304B685C026Q42317689-7A64AD96-56A7-49CE-BC49-4674B6B5E6C1Q46230060-935211CE-1C78-4708-8887-85F658C86F8EQ46270262-56809AA9-6852-46B1-9FC7-1C51E358989EQ51760757-26EFC7A3-6D4B-44F9-8476-AD5C2FC86843Q52357267-83C1742C-7DEB-443D-8BB6-AFF6C74547C1Q58994299-245C99DC-E3E6-4140-BC9F-6EB6D15D5E18
P2860
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年学术文章
@wuu
2007年学术文章
@zh
2007年学术文章
@zh-cn
2007年学术文章
@zh-hans
2007年学术文章
@zh-my
2007年学术文章
@zh-sg
2007年學術文章
@yue
2007年學術文章
@zh-hant
name
Redox-dependent coronary metabolic dilation.
@en
Redox-dependent coronary metabolic dilation.
@nl
type
label
Redox-dependent coronary metabolic dilation.
@en
Redox-dependent coronary metabolic dilation.
@nl
prefLabel
Redox-dependent coronary metabolic dilation.
@en
Redox-dependent coronary metabolic dilation.
@nl
P2093
P2860
P1476
Redox-dependent coronary metabolic dilation.
@en
P2093
Albert Swafford
Chandrasekar Viswanathan
Cuihua Zhang
Paul A Rogers
Petra Rocic
Shu-ichi Saitoh
Takahiko Kiyooka
William M Chilian
Yoonjung Park
P2860
P304
P356
10.1152/AJPHEART.00436.2007
P577
2007-10-26T00:00:00Z