Summary
The effect of perfusion temperature and duration of calcium deprivation on the occurrence of the calcium paradox was studied in the isolated frog heart. Loss of electrical and mechanical activity, ion fluxes, creatine kinase and protein release were used to define cell damage. Perfusion was performed at 22, 27, 32, and 37°C, and calcium deprivation lasted 10, 20, 30, or 40 min. At 22°C and 27°C even a prolonged calcium-free perfusion failed to induce a calcium paradox. After 30 min of calcium-free perfusion at 37°C ventricular activity ceased and a major contraction occurred followed by an increase in resting tension. During the 15-min re-perfusion period the release of creatine kinase was 158.24±2.49 IU·g dry wt-1, and the total amount of protein lost was 70.37±0.73 mg·g dry wt−1, while lower perfusion temperatures resulted in a decreased loss of protein and creatine kinase. Ion fluxes in the perfusion effluent indicate that during re-perfusion a massive calcium influx accompanied by a potassium and a magnesium efflux, and an apparent sodium efflux, occur at a perfusion temperature of 37°C after 30 min of calcium deprivation. The results suggest that the basic principles and damaging effects of calcium overloading are common to both mammalian and frog hearts.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Baker JE, Bullock GR, Hearse DJ (1983) The temperature dependence of the calcium paradox: Enzymatic functional and morphological correlates of cellular injury. J Mol Cell Cardiol 15: 393–411
Boink ABTJ, Ruigrok TJC, De Moes D, Maas AHJ, Zimmerman ANE (1980) The effect of hypothermia on the occurence of the calcium paradox. Pflügers Arch 385: 105–109
Bradford MM (1976) A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal Biochem 72: 248–254
Bulkley BH, Nunnally RL, Hollis DP (1978) “Calcium paradox” and the effect of varied temperature on its development. A Phosphorus Nuclear Magnetic Resonance and morphologic study Lab Invest 39: 133–140
Capucci A, Jance MJ, Ruigrok TJC (1983) The calcium paradox: an electrophysiological study in the isolated rabbit heart. Eur Heart J 4H: 13–21
Cawson RMC, Hauser H (1970) Binding of calcium to phospholipids. In: Cuthbert AW (ed) A symposium on calcium and cellular function, p 22
Ganote GE, Nayler WG (1985) Contracture and the calcium paradox. J Mol Cell Cardiol 17: 733–745
Grinwald PM, Nayler WG (1981) Calcium entry in the calcium paradox. J Mol Cell Cardiol 13: 867–880
Hearse DJ, Humphrey SM, Boink ABTJ, Ruigrok TJC (1978a) The calcium paradox: metabolic, electrophysiological, contractile and ultrastructural characteristics in four species. Eur J Cardiol 7: 241–256
Hearse DJ, Humphrey SM, Bullock GR (1978b) The oxygen paradox and the calcium paradox: two facets of the same problem. J Mol Cell Cardiol 10: 641–668
Horackova M, Vassort G (1979) Sodium-calcium exchange in regulation of cardiac contractility. J Gen Physiol 73: 403–424
Lagerstrand G, Mattison A, Poupa O (1983) Studies on the calcium paradox phenomenon in cardiac muscle strips of poikilotherms. Comp Biochem Physiol 76A: 601–613
Lomsky' M, Ekroth R, Poupa O (1983) The calcium paradox and its protection by hypothermia in human myocardium. Eur Heart J 4H: 139–142
Mines GR (1913) On the functional analysis by the action of electrolytes. J Physiol 46: 188–235
Nayler WG, Perry SE, Elz JS, Daly MJ (1984) Calcium, sodium and the calcium paradox. Circ Res 55: 227–237
Paradise NF, Visscher MB (1975) K+ and Mg2+ net fluxes in relation to zero [Ca2+] perfusion and subsequent cardiac contracture (38739). Proc Soc Exp Biol & Med 149: 40–45
Rich TL, Langer GA (1982) Calcium depletion in rabbit myocardium. Calcium paradox protection by hypothermia and cation substitution. Circ Res 51: 131–141
Rosalki SB (1967) An improved procedure for serum creatine phosphokinase determination. J Lab Clin Med 69: 696–705
Rudge MF, Duncan CJ (1984a) Comparative studies on the role of calcium in triggering subcellular damage in cardiac muscle. Comp Biochem Physiol 77A: 459–468
Rudge MF, Duncan CJ (1984b) Comparative studies on the calcium paradox in cardiac muscle: the effect of temperature on the different phases. Comp Biochem Physiol 79A: 393–398
Ruigrok TJC, Slade AM, Poole-Wilson PA (1983) The calcium paradox in the isolated frog heart: Ringer revisited. Eur Heart J 4H: 57–62
Stark G, Huber U, Horer E, Tritthart HA (1987) Continuous ECG measurements of intracardiac activity from the surface of Langendorff-perfused guinea pig hearts. Basic Res Cardiol 82: 437–444
Volkmann R, Winell S, Petterson AS (1988) Slow sodium-free contractures in the frog heart mediated by the sodium-calcium exchange. Comp Biochem Physiol 89C: 71–75
Zimmerman ANE, Hulsman WC (1966) Paradoxical influence of calcium ions on the permeability of the cell membranes of the isolated rat heart. Nature 211: 646–647
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Touraki, M., Beis, I. Characterization of the calcium paradox in the isolated perfused frog heart: enzymatic, ionic, contractile and electrophysiological studies. J Comp Physiol B 160, 113–118 (1990). https://doi.org/10.1007/BF00258770
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00258770