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Results: 1-25/50
Authors:
Olsson, SB
Yuan, SW
Citation: Sb. Olsson et Sw. Yuan, Theory underlying the suction electrode method end early use in clinical research, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 3-17
Authors:
Franz, MR
Citation: Mr. Franz, Monophasic action potentials recorded by contact electrode method: Genesis, measurements, and interpretations, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 19-45
Authors:
Trayanova, N
Malden, L
Atkinson, E
Citation: N. Trayanova et al., Computer model of monophasic action potential genesis, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 47-69
Authors:
Fenici, R
Fenici, P
Citation: R. Fenici et P. Fenici, Multiple monophasic action potential recording with a single magnetocardiographically localizable amagnetic catheter, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 71-89
Authors:
Franz, MR
Citation: Mr. Franz, The monophasic action potential-pacing combination catheter: Assessing therelationship between repolarization and excitability in vivo, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 91-104
Authors:
Karasik, PE
Chavez, ME
Fletcher, RD
Franz, MR
Citation: Pe. Karasik et al., The monophasic action potential as a guide and clinical teaching tool during routine clinical electrophysiology studies, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 105-120
Authors:
Sager, PT
Citation: Pt. Sager, How to record high-quality monophasic action potential tracings, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 121-134
Authors:
Knollman, BC
Citation: Bc. Knollman, Computer-assisted real-time monophasic action potential analysis, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 135
Authors:
Costard-Jaeckle, A
Antz, M
Franz, MR
Citation: A. Costard-jaeckle et al., Activation-repolarization sequence memory in the isolated rabbit heart, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 149-156
Authors:
Satoh, T
Zipes, DP
Citation: T. Satoh et Dp. Zipes, Tachycardia superimposed on bradycardia prolongs ventricular refractoriness and facilitates arrhythmia induction, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 157-169
Authors:
Wood, MA
Citation: Ma. Wood, Cardiac memory in the atria, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 171-182
Authors:
Goyal, R
Morady, F
Citation: R. Goyal et F. Morady, Use of cardiac action potentials to investigate cardiac memory: From bedside to computer model, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 183-193
Authors:
Kurz, RW
Franz, MR
Citation: Rw. Kurz et Mr. Franz, Action potential alternans, electrical restitution, repolarization dispersion, and arrhythmia vulnerability in the isolated ischemic rabbit heart, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 195-207
Authors:
Clusin, WT
Citation: Wt. Clusin, The role of cytosolic calcium in electrical and mechanical alternans during ischemia, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 209-225
Authors:
Karagueuzian, HS
Kim, YH
Yashima, M
Wu, TJ
Chen, PS
Citation: Hs. Karagueuzian et al., Action potential duration restitution and graded response mechanisms of ventricular vulnerability to reentry and fibrillation: Role of monophasic action potential recordings, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 227-251
Authors:
Verrier, RL
Nearing, BD
Citation: Rl. Verrier et Bd. Nearing, Physiologic mechanisms underlying the link between T wave alternans and vulnerability to ventricular fibrillation, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 253-269
Authors:
Miyazaki, T
Ogawa, S
Zipes, DP
Citation: T. Miyazaki et al., Changes in monophasic action potential configuration and prevalence of ventricular fibrillation during regional ischemia and reperfusion in the intact canine heart: Effects of preconditioning ischemia and potassium channel modulators, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 271-288
Authors:
Libbus, I
Laurita, KR
Rosenbaum, DS
Citation: I. Libbus et al., High-resolution measurement of ventricular repolarization using voltage-sensitive dyes, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 291-306
Authors:
Zabel, M
Hohnloser, SH
Franz, MR
Citation: M. Zabel et al., Effects of heart rate and antiarrhythmic drugs on dispersion of ventricular repolarization measured by multiple monophasic action potential recordings, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 307-317
Authors:
Higham, DP
Campbell, RWF
Citation: Dp. Higham et Rwf. Campbell, Dispersion of ventricular repolarization and arrhythmias: Basic and clinical correlates, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 319-336
Authors:
Zabel, M
Lichtlen, PR
Haverich, A
Franz, MR
Citation: M. Zabel et al., Validation of electrocardiographic variables of dispersion of ventricular repolarization with direct myocardial repolarization measurements, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 337-350
Authors:
Gepstein, L
Hayam, G
Ben-Haim, SA
Citation: L. Gepstein et al., Mapping of the spatial correlation between the activation and repolarization properties in the normal ventricle, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 351
Authors:
Franz, MR
Bargheer, K
Citation: Mr. Franz et K. Bargheer, Abnormal relationship between activation and repolarization in human left ventricular hypertrophy, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 363-378
Authors:
Hondeghem, L
Citation: L. Hondeghem, Frequency dependence of class I and class III antiarrhythmic agents explaining their antiarrhythmic and proarrhythmic properties, MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 381
Authors:
Kirchhof, PF
Fabritz, CL
Citation: Pf. Kirchhof et Cl. Fabritz, Effect of d-sotalol on the vulnerable window of ventricular fibrillation, and a definition of the "area of vulnerability", MONOPHASIC ACTION POTENTIALS: BRIDGING CELL AND BEDSIDE, 2000, pp. 395-421