The effects of changes in muscle length during diastole on the calcium transient in ferret ventricular muscle.

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The effects of changes in muscle length during diastole on the calcium transient in ferret ventricular muscle.

D G Allen, C G Nichols and G L Smith

Department of Physiology, University College London.

1. Ferret papillary muscles were isolated and injected withaequorin to measure intracellular Ca2+ concentration [( Ca2+]i).Developed tension and [Ca2+]i were measured in response to lengthchanges. 2. A maintained reduction in muscle length producedan immediate decrease in developed tension followed by slowdecline over 10-20 min. This slow decline in tension was accompaniedby a slow decline in the amplitude of the systolic [Ca2+]i rise(the Ca2+ transient). The immediate decrease in tension wasaccompanied by a prolongation of the Ca2+ transient and an abbreviationof the twitch. 3. Repeated reductions in muscle length timedto occur only during the period of contraction (systolic shortening)produced an immediate decrease of developed tension but thesubsequent slow decline was substantially smaller. The slowdecline in the amplitude of the Ca2+ transients was also smaller.The prolongation of the Ca2+ transient and abbreviation of thetwitch were similar to those observed with a maintained reductionof length. 4. Repeated reductions in muscle length during theperiod between contractions (diastolic shortening) did not producethe immediate decrease of tension but the slow decline of tensionwas present. The slow decline in the amplitude of the Ca2+ transientswas also present. However no change in the duration of the Ca2+transient or the twitch was present under these conditions.5. These results suggest that diastolic muscle length can influencethe amplitude of the Ca2+ transients achieved during systole.This conclusion was confirmed by experiments in which the recoveryof tension and Ca2+ transients was observed after periods ofrest. Both developed tension and Ca2+ transients on recoveryfrom a rest were reduced when the rest occurred at a short lengthin comparison with a long length. 6. We suggest that musclelength influences resting [Ca2+]i and this in turn affects theCa2+ transients and developed tension.

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