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Force-interval relationship in heart muscle of mammals. A calcium compartment model

A mathematical model was derived that describes peak force of contraction as a function of stimulus interval and stimulus number in terms of Ca2+ transport between three hypothetical Ca2+ compartments. It includes the conventional uptake and release compartments and recirculation of a fraction r of...

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Published in:	Biophysical journal 1987, Vol.51 (1), p.13-26
Main Authors:	Schouten, V.J., van Deen, J.K., de Tombe, P., Verveen, A.A.
Format:	Article
Language:	English
Subjects:	Action Potentials - drug effects Animals Biological and medical sciences Calcium - metabolism Fundamental and applied biological sciences. Psychology Heart Heart - physiology Mathematics Models, Biological Myocardial Contraction Nifedipine - pharmacology Vertebrates: cardiovascular system
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container_start_page	13
container_title	Biophysical journal
container_volume	51
creator	Schouten, V.J. van Deen, J.K. de Tombe, P. Verveen, A.A.
description	A mathematical model was derived that describes peak force of contraction as a function of stimulus interval and stimulus number in terms of Ca2+ transport between three hypothetical Ca2+ compartments. It includes the conventional uptake and release compartments and recirculation of a fraction r of the activator Ca2+. Peak force is assumed to be proportional to the amount of activator Ca2+ released from the release compartment into the sarcoplasm. A new extension is a slow exchange of Ca2+ with the extracellular space via an exchange compartment. Six independent parameters were necessary to reproduce the different effects of postextrasystolic potentiation, frequency potentiation, and post-rest potentiation in isolated heart muscle from the rat. The normalized steady state peak force (F/Fmax) under standard conditions varied by a factor of ten between preparations from rat heart. Analysis with the model indicated that most of this variation was caused by two variables: the Ca2+ influx per excitation and the recirculating fraction of activator Ca2+. The influence of the Ca2+ antagonist nifedipine of the force-interval relationship was reproduced by the model. It is concluded that the model may serve to analyze the variability of contractile force and the mode of actions of drugs in heart muscle.
doi_str_mv	10.1016/S0006-3495(87)83307-6
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Six independent parameters were necessary to reproduce the different effects of postextrasystolic potentiation, frequency potentiation, and post-rest potentiation in isolated heart muscle from the rat. The normalized steady state peak force (F/Fmax) under standard conditions varied by a factor of ten between preparations from rat heart. Analysis with the model indicated that most of this variation was caused by two variables: the Ca2+ influx per excitation and the recirculating fraction of activator Ca2+. The influence of the Ca2+ antagonist nifedipine of the force-interval relationship was reproduced by the model. 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A calcium compartment model</title><title>Biophysical journal</title><addtitle>Biophys J</addtitle><description>A mathematical model was derived that describes peak force of contraction as a function of stimulus interval and stimulus number in terms of Ca2+ transport between three hypothetical Ca2+ compartments. It includes the conventional uptake and release compartments and recirculation of a fraction r of the activator Ca2+. Peak force is assumed to be proportional to the amount of activator Ca2+ released from the release compartment into the sarcoplasm. A new extension is a slow exchange of Ca2+ with the extracellular space via an exchange compartment. Six independent parameters were necessary to reproduce the different effects of postextrasystolic potentiation, frequency potentiation, and post-rest potentiation in isolated heart muscle from the rat. The normalized steady state peak force (F/Fmax) under standard conditions varied by a factor of ten between preparations from rat heart. Analysis with the model indicated that most of this variation was caused by two variables: the Ca2+ influx per excitation and the recirculating fraction of activator Ca2+. The influence of the Ca2+ antagonist nifedipine of the force-interval relationship was reproduced by the model. It is concluded that the model may serve to analyze the variability of contractile force and the mode of actions of drugs in heart muscle.</description><subject>Action Potentials - drug effects</subject><subject>Animals</subject><subject>Biological and medical sciences</subject><subject>Calcium - metabolism</subject><subject>Fundamental and applied biological sciences. 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subjects	Action Potentials - drug effects Animals Biological and medical sciences Calcium - metabolism Fundamental and applied biological sciences. Psychology Heart Heart - physiology Mathematics Models, Biological Myocardial Contraction Nifedipine - pharmacology Vertebrates: cardiovascular system
title	Force-interval relationship in heart muscle of mammals. A calcium compartment model
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