Abstract

The long term objective of this proposal is to develop a quantitative basis for action of antiarrhythmic drugs in cardiac muscle. The increase in number and modes of action (sodium channel, calcium channel blockers) of drugs has created expanded opportunities for pharmacologic management of a number of cardiac arrhythmias. There has been little progress in describing a quantitatively accurate process depicting drug-channel interaction and the associated effect on the cardiac conduction system. The modulated receptor hypothesis for cardiac tissue postulates a variable affinity receptor and interaction between channel gates and drug complexed channels. We have suggested a considerably simpler process based on gated control of the diffusion path between drug pool and channel binding site. An """"""""apparent"""""""" variable affinity receptor arises as a natural consequence of this approach. Further, an """"""""apparent"""""""" modification of gate kinetics arises naturally. This work will focus on extending this description of channel blocking agents to a propagating system; evaluate the potential effect of blocking agents on current, voltage and conductance relationships in a propagating and voltage clamped setting; and investigate the potential role of blocking agent mediated changes in propagation velocity. We expect our studies of propagated action potentials in the presence of channel blocking agents to illuminate the relationship between ionic currents, voltage and conductance, and thus aid in the design of appropriate experimental protocols focused on minimizing confounding effects.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL032994-02
Application #
3344592
Study Section
(SSS)
Project Start
1984-08-01
Project End
1987-07-31
Budget Start
1985-08-01
Budget End
1986-07-31
Support Year
2
Fiscal Year
1985
Total Cost
Indirect Cost

  Institution

Name
Duke University
Department
Type
Schools of Medicine
DUNS #
071723621
City
Durham
State
NC
Country
United States
Zip Code
27705

  Publications

Starmer, C F (1997) The cardiac vulnerable period and reentrant arrhythmias: targets of anti- and proarrhythmic processes. Pacing Clin Electrophysiol 20:445-54
Liu, L; Krinsky, V I; Grant, A O et al. (1996) Cardiac transient outward potassium current: a pulse chemistry model of frequency-dependent properties. Am J Physiol 270:H386-97
Starobin, J M; Zilberter, Y I; Rusnak, E M et al. (1996) Wavelet formation in excitable cardiac tissue: the role of wavefront-obstacle interactions in initiating high-frequency fibrillatory-like arrhythmias. Biophys J 70:581-94
Spach, M S; Starmer, C F (1995) Altering the topology of gap junctions a major therapeutic target for atrial fibrillation. Cardiovasc Res 30:337-44
Starmer, C F; Romashko, D N; Reddy, R S et al. (1995) Proarrhythmic response to potassium channel blockade. Numerical studies of polymorphic tachyarrhythmias. Circulation 92:595-605
Zilberter, Y I; Starmer, C F; Grant, A O (1994) Open Na+ channel blockade: multiple rest states revealed by channel interactions with disopyramide and quinidine. Am J Physiol 266:H2007-17
Starmer, C F; Reddy, M R; Namasivayam, A et al. (1994) Potassium channel blockade amplifies cardiac instability numerical studies of torsades de pointes. Indian J Physiol Pharmacol 38:259-66
Whalley, D W; Wendt, D J; Starmer, C F et al. (1994) Voltage-independent effects of extracellular K+ on the Na+ current and phase 0 of the action potential in isolated cardiac myocytes. Circ Res 75:491-502
Zilberter YuI; Starmer, C F; Starobin, J et al. (1994) Late Na channels in cardiac cells: the physiological role of background Na channels. Biophys J 67:153-60
Grant, A O; Wendt, D J; Zilberter, Y et al. (1993) Kinetics of interaction of disopyramide with the cardiac sodium channel: fast dissociation from open channels at normal rest potentials. J Membr Biol 136:199-214

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