C I Spencer1, M J Lab, W A Seed. 1. Charing Cross and Westminster Medical School, London, United Kingdom.
Abstract
OBJECTIVE: The aim was to investigate alternate acceleration and retardation of mechanical restitution as a possible mechanism for mechanical alternans in isolated myocardium. METHODS: Mechanical alternans was induced in papillary muscles from the right ventricles of 11 guinea pigs (200-300 g) by rapid pacing under hypothermic conditions (T = 27 degrees C). Mechanical restitution curves were constructed by measuring the force responses to stimuli applied following variable test intervals during steady state pacing. Curves were obtained under control conditions (steady state stimulation interval 3 s), and for the beats following the large and small contractions during mechanical alternans. Monoexponentials were fitted to the restitution curves. RESULTS: The mean rate constant for restitution following the large beat in alternans was found to be slightly but significantly smaller than that following the small. Both rate constants obtained during alternans were significantly larger than the control rate constant (restitution was faster in alternans). In addition, as the alternation widened, the restitution curve of the beat following the small contraction developed a higher plateau than that following the large. CONCLUSIONS: The results confirm that the small beat in alternans is followed by faster restitution than the large. This alone is insufficient to explain the observed extent of alternans. The restitution curve for the beat following the small contraction must also rise to a higher plateau. Both the amount of calcium available for intracellular release and the rate at which it is made available vary from beat to beat.
OBJECTIVE: The aim was to investigate alternate acceleration and retardation of mechanical restitution as a possible mechanism for mechanical alternans in isolated myocardium. METHODS: Mechanical alternans was induced in papillary muscles from the right ventricles of 11 guinea pigs (200-300 g) by rapid pacing under hypothermic conditions (T = 27 degrees C). Mechanical restitution curves were constructed by measuring the force responses to stimuli applied following variable test intervals during steady state pacing. Curves were obtained under control conditions (steady state stimulation interval 3 s), and for the beats following the large and small contractions during mechanical alternans. Monoexponentials were fitted to the restitution curves. RESULTS: The mean rate constant for restitution following the large beat in alternans was found to be slightly but significantly smaller than that following the small. Both rate constants obtained during alternans were significantly larger than the control rate constant (restitution was faster in alternans). In addition, as the alternation widened, the restitution curve of the beat following the small contraction developed a higher plateau than that following the large. CONCLUSIONS: The results confirm that the small beat in alternans is followed by faster restitution than the large. This alone is insufficient to explain the observed extent of alternans. The restitution curve for the beat following the small contraction must also rise to a higher plateau. Both the amount of calcium available for intracellular release and the rate at which it is made available vary from beat to beat.
Authors: S Mohri; J Araki; T Imaoka; G Iribe; M Maesako; J Shimizu; H Matsubara; T Ohe; M Hirakawa; H Suga Journal: Heart Vessels Date: 1999 Impact factor: 2.037
Authors: Lothar A Blatter; Jens Kockskämper; Katherine A Sheehan; Aleksey V Zima; Jörg Hüser; Stephen L Lipsius Journal: J Physiol Date: 2003-01-01 Impact factor: 5.182