In perfused rat hearts, an increase in cytosolic free calcium precedes lethal myocardial ischemic injury and may accelerate cellular ATP depletion.
In a perfused rat heart model, an increase in cytosolic free calcium precedes and likely contributes to lethal myocardial ischemic injury.
The relations between ATP depletion, increased cytosolic free calcium concentration ( Cai), contracture development, and lethal myocardial ischemic injury, as evaluated by enzyme release, were examined using 19F nuclear magnetic resonance to measure Cai in 1,2-bis(2-amino-5-fluorophenoxy)ethane-N,N,N',N'-tetraacetic acid (5F-BAPTA)-loaded perfused rat hearts. Total ischemia at 37 degrees C was induced in beating hearts, potassium-arrested hearts, magnesium-arrested hearts, and hearts pretreated with 0.9 microM diltiazem to reduce but not abolish contractility. In the beating hearts, time-averaged Cai, which is intermediate between the systolic and the basal Cai, was 544 +/- 74 nM. In contrast, in the potassium- and magnesium-arrested hearts, the time-averaged values are lower than in beating hearts (352 +/- 88 nM for potassium arrest, 143 +/- 22 nM for magnesium arrest). During ischemia, ATP depletion, contracture, and a rise in Cai are delayed by cardiac arrest, but all occur more rapidly in the potassium-arrested hearts than in the magnesium-arrested hearts. The diltiazem-treated hearts were generally similar to the magnesium-arrested hearts in their response to ischemia. Under all conditions, contracture development was initiated after tissue ATP had fallen to less than 50% of control; invariably, there was a progressive rise in Cai during and following contracture development. Reperfusion with oxygenated perfusate shortly after peak contracture development resulted in a return of Cai to its preischemic level, resynthesis of creatine phosphate, no significant enzyme release, and no substantial loss of 5F-BAPTA from the heart. The data demonstrate that an increase in Cai precedes lethal myocardial ischemic injury. This rise in Cai may accelerate the depletion of cellular ATP and may directly contribute to the development of lethal ischemic cell injury.
Steenbergen et al. (Mon,) conducted a other in Myocardial ischemia. Cardiac arrest (potassium or magnesium) or diltiazem pretreatment vs. Beating hearts was evaluated on Cytosolic free calcium concentration, ATP depletion, contracture development, and lethal myocardial ischemic injury. In perfused rat hearts, an increase in cytosolic free calcium precedes lethal myocardial ischemic injury and may accelerate cellular ATP depletion.
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