Abstract
We investigated the effects of altering cardiac temperature on left ventricular (LV) myocardial mechanical work and energetics using the excised, cross-circulated rat heart model. We analyzed the LV end-systolic pressure–volume relationship (ESPVR) and linear relationship between myocardial oxygen consumption per beat (VO2) and systolic pressure–volume area (PVA; total mechanical energy per beat) in isovolumically contracting rat hearts during hypo- (32 °C), normo- (37 °C), and hyperthermia (42 °C) under a 300-beats per minute pacing. LV ESPVR shifted downward with increasing cardiac temperature. The VO2–PVA relationship was superimposable in these different thermal conditions; however, each data point of VO2–PVA shifted left-downward during increasing cardiac temperature on the superimposable VO2–PVA relationship line. VO2 for Ca2+ handling in excitation–contraction coupling decreased, which was associated with increasing cardiac temperature, during which sarcoplasmic reticulum Ca2+-ATPase (SERCA) activity was suppressed, due to phospholamban phosphorylation inhibition, and instead, O2 consumption for basal metabolism was increased. The O2 cost of LV contractility for Ca2+ also increased with increasing cardiac temperature. Logistic time constants evaluating LV relaxation time were significantly shortened with increasing cardiac temperature related to the acceleration of the detachment in cross-bridge (CB) cycling, indicating increased myosin ATPase activity. The results suggested that increasing cardiac temperature induced a negative inotropic action related to SERCA activity suppression in Ca2+ handling and increased myosin ATPase activity in CB cycling. We concluded that thermal intervention could modulate cardiac inotropism by changing CB cycling, Ca2+ handling, and basal metabolism in rat hearts.
Highlights
(42 °C) under a 300-beats per minute pacing
Previous studies reported that the magnitude of Ca2+ transient in cardiomyocytes increases in hypothermic intervention[1,6], it is still unclear whether the amplitude of Ca2+ transient decreases in hyperthermic intervention, or its change is really associated with inotropic action and energy metabolism in different thermal interventions
We aimed to investigate the direct effects of hypo- and hyperthermia, which are likely to be encountered in each lifetime, on left ventricular (LV) myocardial mechanoenergetics, using the excised, cross-circulated rat heart model
Summary
(42 °C) under a 300-beats per minute pacing. LV ESPVR shifted downward with increasing cardiac temperature. We concluded that thermal intervention could modulate cardiac inotropism by changing CB cycling, Ca2+ handling, and basal metabolism in rat hearts. The alteration of thermal condition affects the systemic regulation mediated by neuronal and hormonal factors to regulate the cardiac contractility and heart rate, and the enzyme activities related to CB cycling, Ca2+ handling, and basal metabolism. We used the excised, cross-circulated rat heart model to investigate the direct effects of changing temperature on left ventricular (LV) mechanical work and energetics (i.e., mechanoenergetics). Previous studies have already reported the effects of changing cardiac temperature on myocardial mechanoenergetics in the excised, cross-circulated canine heart model[3,4,5,7]. The direct effects of changing cardiac temperature on myocardial mechanoenergetics have not yet been analyzed in small animal hearts, such as rats
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