Protective Effect of HOE642, a Selective Blocker of Na⁺‐H⁺ Exchange, Against the Development of Rigor Contracture in Rat Ventricular Myocytes

Abstract: The objective of this study was to investigate the effect of Na+‐H+ exchange (NHE) and HCO3−‐Na+ symport inhibition on the development of rigor contracture. Freshly isolated adult rat cardiomyocytes were subjected to 60 min metabolic inhibition (MI) and 5 min re‐energization (Rx). The effects of perfusion of HCO3− or HCO3−‐free buffer with or without the NHE inhibitor HOE642 (7 μM) were investigated during MI and Rx. In HCO3−‐free conditions, HOE642 reduced the percentage of cells developing rigor during MI fr… Show more

“…Slowed ATP depletion during ischemic conditions. The present observations in cultured cardiomyocytes exposed to simulated ischemia and in intact myocardium submitted to zero-flow ischemia are in agreement with previous studies showing that NHE inhibition slows-down the rate of ATP depletion during ischemia and delays the onset of rigor contracture (6,11,25). Moreover, in the present study, modulation of the rate of ATP depletion during ischemia by modifying myocardial temperature within the physiological range (35.5-38.5°C) allowed us to evaluate the contribution of the effect of cariporide on ATP content to its protective effect against ischemia-reperfusion injury.…”

“…In a recent study (31), pretreatment with the selective NHE inhibitor SM-20550 was associated with attenuated Ca 2ϩ overload in mitochondria obtained from rat hearts submitted to 40 min of ischemia and 20 min of reperfusion, a result in agreement with the protective effect of NHE inhibition against cell necrosis secondary to ischemia-reperfusion, but [Ca 2ϩ ] m during ischemia was not measured. Our observation that cariporide, at concentrations that have been consistently found cardioprotective in isolated cells (25,27) and intact myocardium in vivo (6,16), enhanced mitochondrial Ca 2ϩ accumulation during simulated ischemia may appear surprising. Although increased [Ca 2ϩ ] m has been shown to have detrimental effects (4), there is a lack of information on the consequences of mitochondrial Ca 2ϩ overload during ischemia.…”

“…Although with some discrepancies (10), studies in different models have shown that to be effective, NHE inhibition must act during coronary occlusion (6,16) or cardioplegia (28), whereas its application at the time of reperfusion affords little, if any, protection against cell death. Recent reports (6,18,25) indicate that NHE inhibition delays the progression of ischemic injury as manifested by ATP depletion or development of rigor contracture. It has been suggested that NHE1 is markedly inhibited during severe ischemia (23).…”

Cariporide preserves mitochondrial proton gradient and delays ATP depletion in cardiomyocytes during ischemic conditions

“…Slowed ATP depletion during ischemic conditions. The present observations in cultured cardiomyocytes exposed to simulated ischemia and in intact myocardium submitted to zero-flow ischemia are in agreement with previous studies showing that NHE inhibition slows-down the rate of ATP depletion during ischemia and delays the onset of rigor contracture (6,11,25). Moreover, in the present study, modulation of the rate of ATP depletion during ischemia by modifying myocardial temperature within the physiological range (35.5-38.5°C) allowed us to evaluate the contribution of the effect of cariporide on ATP content to its protective effect against ischemia-reperfusion injury.…”

“…In a recent study (31), pretreatment with the selective NHE inhibitor SM-20550 was associated with attenuated Ca 2ϩ overload in mitochondria obtained from rat hearts submitted to 40 min of ischemia and 20 min of reperfusion, a result in agreement with the protective effect of NHE inhibition against cell necrosis secondary to ischemia-reperfusion, but [Ca 2ϩ ] m during ischemia was not measured. Our observation that cariporide, at concentrations that have been consistently found cardioprotective in isolated cells (25,27) and intact myocardium in vivo (6,16), enhanced mitochondrial Ca 2ϩ accumulation during simulated ischemia may appear surprising. Although increased [Ca 2ϩ ] m has been shown to have detrimental effects (4), there is a lack of information on the consequences of mitochondrial Ca 2ϩ overload during ischemia.…”

“…Although with some discrepancies (10), studies in different models have shown that to be effective, NHE inhibition must act during coronary occlusion (6,16) or cardioplegia (28), whereas its application at the time of reperfusion affords little, if any, protection against cell death. Recent reports (6,18,25) indicate that NHE inhibition delays the progression of ischemic injury as manifested by ATP depletion or development of rigor contracture. It has been suggested that NHE1 is markedly inhibited during severe ischemia (23).…”

Cariporide preserves mitochondrial proton gradient and delays ATP depletion in cardiomyocytes during ischemic conditions

“…The effectiveness of both interventions has been solidly established. Several studies have shown that extracellular acidosis delays ATP depletion (21,29,38). However, because acidosis markedly decreases conductivity of both gap junctions and hemichannels (membrane pores formed by connexins) (1,34), the question can be raised regarding whether the changes in sarcolemmal permeability and tissue electrical resistance observed late during prolonged ischemia reflect a fast opening of hemichannels, and the protective effect of acidosis is due to interference with this phenomenon.…”

“…The time course of cell death in hypoxic hearts was determined by monitoring LDH release in the coronary effluent. The studies were also performed under conditions that are known to modify the progression of hypoxic injury as acidification of the hypoxic buffer (21,29,38) or addition of glycine (12,20). The effects of these interventions on sarcolemmal rupture during energy depletion were confirmed in a cell line derived from murine cardiac myocytes (HL-1).…”

Effect of sarcolemmal rupture on myocardial electrical impedance during oxygen deprivation

Practical guidelines for rigor and reproducibility in preclinical and clinical studies on cardioprotection