Contraction-excitation feedback in myocardium. Physiological basis and clinical relevance.
about
Rabbit models of cardiac mechano-electric and mechano-mechanical couplingPostoperative atrial fibrillation in patients undergoing non-cardiac non-thoracic surgery: A practical approach for the hospitalistRestricted N-terminal truncation of cardiac troponin T: a novel mechanism for functional adaptation to energetic crisisVariability in the measurement of human ventricular refractoriness.Mechano-electric feedback in the fish heart.Monophasic action potential recordings during acute changes in ventricular loading induced by the Valsalva manoeuvreComparative electrophysiological effects of captopril or hydralazine combined with nitrate in patients with left ventricular dysfunction and inducible ventricular tachycardia.Biomechanics of cardiac electromechanical coupling and mechanoelectric feedback.Cardiac memory.Electrophysiology of Myocardial Cells in the Epicardial, Midmyocardial, and Endocardial Layers of the Ventricle.U waves in ventricular hypertrophy: possible demonstration of mechano-electrical feedbackThe epicardial electrogram: a quantitative assessment during balloon angioplasty incorporating monophasic action potential recordings.Mechanoelectrical feedback: independent role of preload and contractility in modulation of canine ventricular excitabilityA discrete electromechanical model for human cardiac tissue: effects of stretch-activated currents and stretch conditions on restitution properties and spiral wave dynamics.The range of sensors and algorithms used in rate adaptive cardiac pacing.Segmental wall motion abnormalities alter vulnerability to ventricular ectopic beats associated with acute increases in aortic pressure in patients with underlying coronary artery disease.Interaction between ventricular loading and repolarisation: relevance to arrhythmogenesisThe Association of Abnormal Ventricular Wall Motion and Increased Dispersion of Repolarization in Humans is Independent of the Presence of Myocardial InfarctionEffect of transcatheter aortic valve replacement on P-wave duration, P-wave dispersion and left atrial size.Mechano-sensitivity of cardiac pacemaker function: pathophysiological relevance, experimental implications, and conceptual integration with other mechanisms of rhythmicity.Electromechanical coupling in patients with the short QT syndrome: further insights into the mechanoelectrical hypothesis of the U wave.Cellular basis for the repolarization waves of the ECG.Increased dispersion of refractoriness in the absence of QT prolongation in patients with mitral valve prolapse and ventricular arrhythmias.Effect of exercise on cycle length in atrial flutter.The force-frequency relationship: insights from mathematical modeling.Combining wet and dry research: experience with model development for cardiac mechano-electric structure-function studies.The importance of non-uniformities in mechano-electric coupling for ventricular arrhythmias.A role for membrane shape and information processing in cardiac physiology.Modulation of the QT interval duration in hypertension with antihypertensive treatment.Cardiac contractility. A review.Is ventricular wall stress rather than left ventricular hypertrophy an important contributory factor to sudden cardiac death?QT interval dispersion and its clinical utility.Relation between cellular repolarization characteristics and critical mass for human ventricular fibrillation.Physiological changes in ventricular filling alter cardiac electrophysiology in patients with abnormal ventricular function.Cardiac defibrillation and the role of mechanoelectric feedback in postshock arrhythmogenesis.In silico investigation of the short QT syndrome, using human ventricle models incorporating electromechanical coupling.Control of refractory ventricular tachycardia with biventricular assist devices.Mechanosensitivity of GIRK channels is mediated by protein kinase C-dependent channel-phosphatidylinositol 4,5-bisphosphate interaction.Acute reduction of ventricular volume decreases QT interval dispersion in elderly subjects with and without heart failure.An integrative appraisal of mechano-electric feedback mechanisms in the heart.
P2860
Q26747152-883A8825-AE33-4314-A9B7-3E92E65AEA7BQ26785568-6FB66FF7-A7CA-43A2-8650-8E43E4712B02Q28283976-2F11165C-7139-415C-BFDE-58AE6F599234Q33154621-594AC943-9BB6-4DDD-94ED-2562A11603DAQ33580171-330E1041-09B9-4633-BDD2-CA8C508479EEQ33611750-086C4CF1-AE6B-49CE-8F76-C2B3EDD0E2EAQ33611946-876ADD72-C364-4F2F-9D74-B8D71F7EBC02Q33622487-BE9887DE-DC3F-4219-9C40-8822DBA08980Q33794886-0B1E4B00-937B-4944-81CD-D3942C846E86Q33843397-B0514C1C-BDD7-4A7C-91F6-EB9D25278A89Q33999095-75659B23-4233-4489-9150-94F3315CD8DCQ34016599-FC03F9DD-4594-43B1-9E9D-4592CC7CEB18Q34564607-FB05639D-5273-4A8C-B045-FB327B828686Q34634990-5953DC33-0E3D-4E1A-ACA3-4B2ECB87ECA4Q35334423-A81B4090-3053-44FE-966B-EB1669E9242CQ35367111-53C85761-C264-436A-A2AB-D32C30618602Q35951205-17727940-6267-4055-ACA5-9761F1ACD8A7Q36072559-00C59756-A35B-4A62-BCA2-E6F9A1D703C8Q36460910-BE03491E-467B-4D70-8A78-5D1DA572170EQ36479252-738E4D21-4E63-442D-89DB-6ECF1E4D25B0Q36631322-216D91F4-BAB3-4397-8F17-374E3409A080Q36667338-1E47761E-CA92-4C13-A4B9-96E93BFC0858Q36815306-632AD747-BB1A-4D40-8A8F-153FC3E6683FQ36817182-F471C874-5086-4AD4-971B-0F42D0B7BB4BQ37180938-BF7241CD-682A-45EF-85BA-35A444082E93Q38075412-F7D4CA3B-F7BB-4826-924E-6E99DBF6021AQ38171344-6F201E24-EE8D-4608-B06C-7D07F3364323Q38240412-F2FF3824-CCB0-4769-978C-038035A9FCC6Q38383090-8AB031AB-DD52-48A2-914D-FC74810D44F4Q39705258-97E15EF7-87ED-4829-ADC4-41E1DDAD01D6Q40508528-A8C2C37E-6C5C-49A2-BB47-01D99B0C69C5Q41633711-55CE215E-0A23-467F-B1B5-555D6311EA32Q41687568-456D29A3-41C4-4989-A5E8-9A60EEA5E067Q41822967-D7C56A0C-1C8D-4270-A972-DEE79F82885EQ41992908-5B99FB24-006F-4DE3-8793-FDFA4864304DQ43105783-F523BC30-CC74-49B6-97AA-352FAF8A2D90Q44541915-53694483-E773-4FD6-9CED-2653CEAACF1DQ44683530-05BCCA5B-4C6C-4D18-8AEB-7EA7D7DF6127Q45207412-703244D2-9F96-45B3-9A0B-AD14314CDC6CQ46123974-D95B85F1-A979-4041-B318-4E7028991B06
P2860
Contraction-excitation feedback in myocardium. Physiological basis and clinical relevance.
description
1982 nî lūn-bûn
@nan
1982年の論文
@ja
1982年論文
@yue
1982年論文
@zh-hant
1982年論文
@zh-hk
1982年論文
@zh-mo
1982年論文
@zh-tw
1982年论文
@wuu
1982年论文
@zh
1982年论文
@zh-cn
name
Contraction-excitation feedbac ...... basis and clinical relevance.
@en
type
label
Contraction-excitation feedbac ...... basis and clinical relevance.
@en
prefLabel
Contraction-excitation feedbac ...... basis and clinical relevance.
@en
P356
P1433
P1476
Contraction-excitation feedbac ...... basis and clinical relevance.
@en
P2093
P304
P356
10.1161/01.RES.50.6.757
P577
1982-06-01T00:00:00Z