Effects of mild hypothermia on hemodynamics in cardiac arrest survivors and isolated failing human myocardium.

Post-cardiac arrest myocardial dysfunction is a common phenomenon after return of spontaneous circulation (ROSC) and contributes to hemodynamic instability and low survival rates after cardiac arrest. Mild hypothermia for 24 h after ROSC has been shown to significantly improve neurologic recovery and survival rates. In the present study we investigate the influence of therapeutic hypothermia on hemodynamic parameters in resuscitated patients and on contractility in failing human myocardium. We analyzed hemodynamic data from 200 cardiac arrest survivors during the hypothermia period. The initial LVEF was 32.6 +/- 1.2% indicating a significantly impaired LV function. During hypothermia induction, the infusion rate of epinephrine could be significantly reduced from 9.1 +/- 1.3 microg/min [arrival intensive care unit (ICU) 35.4 degrees C] to 4.6 +/- 1.0 microg/min (34 degrees C) and 2.8 +/- 0.5 microg/min (33 degrees C). The dobutamine and norepinephrine application rates were not changed significantly. The mean arterial blood pressure remained stable. The mean heart rate significantly decreased from 91.8 +/- 1.7 bpm (arrival ICU) to 77.3 +/- 1.5 bpm (34 degrees C) and 70.3 +/- 1.4 bpm (33 degrees C). In vitro we investigated the effect of hypothermia on isolated ventricular muscle strips from explanted failing human hearts. With decreasing temperature, the contractility increased to a maximum of 168 +/- 23% at 27 degrees C (n = 16, P < 0.05). Positive inotropic response to hypothermia was accompanied by moderately increased rapid cooling contractures as a measure of sarcoplasmic reticulum (SR) Ca(2+) content, but can be elicited even when the SR Ca(2+) release is blocked in the presence of ryanodine. Contraction and relaxation kinetics are prolonged with hypothermia, indicating increased Ca(2+) sensitivity as the main mechanism responsible for inotropy. In conclusion, mild hypothermia stabilizes hemodynamics in cardiac arrest survivors which might contribute to improved survival rates in these patients. Mechanistically, we demonstrate that hypothermia improves contractility in failing human myocardium most likely by increasing Ca(2+)-sensitivity.

Increased SR Ca2+ cycling contributes to improved contractile performance in SERCA2a-overexpressing transgenic rats.

OBJECTIVE: Heart failure is associated with reduced function of sarcoplasmic reticulum (SR) Ca2+-ATPase (SERCA2a) but increased function of sarcolemmal Na+/Ca2+ exchanger (NCX), leading to decreased SR Ca2+ content and loss of frequency-potentiation of contractile force. We reported that SERCA2a-overexpression in transgenic rat hearts (TG) results in improved contractility. However, it was not clear whether TG have improved contractility due to frequency-dependent improved SR Ca2+ handling. METHODS: Therefore, we characterized TG (n=35) vs. wild-type (WT) control rats (n=39) under physiological conditions (37 degrees C, stimulation rate <8 Hz). Twitch force, intracellular Ca2+ transients ([Ca2+]i), and SR Ca2+ content were measured in isolated muscles. The contribution of transsarcolemmal Ca2+ influx (I(Ca)) through L-type Ca2+ channels (LTCC) and reverse mode NCX (I(Na/Ca)) to Ca2+ cycling were studied in isolated myocytes. RESULTS: With increasing frequency, force increased in TG muscles by 168+/-35% (8 Hz; P<0.05) and SR Ca2+ content increased by maximally 118+/-31% (4 Hz; P<0.05). In WT, there was a flat force-frequency response without changes in SR Ca2+ content. Relaxation parameters of force and [Ca2+]i decay were accelerated at each frequency in TG vs. WT by approximately 10%. At prolonged rest intervals (<240 s), force and SR Ca2+ content increased significantly more in TG. Consequently, absolute SR Ca2+ content measured in myocytes was increased approximately 2-fold in TG. Transsarcolemmal Ca2+ fluxes estimated by I(Ca) (at 0 mV -10.2+/-1.1 vs. -16.9+/-1.3 pA/pF) and I(Na/Ca) (0.17+/-0.02 vs. 0.46+/-0.05 pA/pF) were decreased in TG vs. WT (P<0.05), whereas NCX and LTCC protein expression was only slightly reduced (P=n.s.). CONCLUSION: In summary, SERCA2a-overexpression improved contractility in a frequency-dependent way due to increased SR Ca2+ loading whereas transsarcolemmal Ca2+ fluxes were decreased.

The role of SR Ca(2+)-content in blunted inotropic responsiveness of failing human myocardium.

The effects of inotropic agents are blunted in end-stage failing human myocardium. This has been related to a number of subcellular alterations including desensitization of the beta -adrenergic system. However, it is unknown whether alterations in SR Ca(2+)-handling contribute to blunted inotropic responsiveness of failing myocardium. We tested the hypothesis that the reduced effectiveness of Ca(2+)-dependent inotropic interventions results from the inability of the SR to sufficiently increase its Ca(2+)-content in failing human myocardium. Experiments were performed in ventricular muscle preparations from a total of four non-failing and 18 end-stage failing hearts. Isometric twitch force and SR Ca(2+)-content (using rapid cooling contractures; RCCs) were assessed under basal experimental conditions (1 Hz, 37 degrees C, [Ca(2+)](o) 2.5 mmol/l), and at increasing [Ca(2+)](o) (1.25-15 mmol/l), increasing concentrations of the beta -adrenergic agonist isoproterenol (ISO; 0.01-10 micromol/l), or the glycolytic substrate pyruvate (5-15 mmol/l). In addition, paired RCCs were evoked in a subset of experiments to investigate the relative contribution of SR Ca(2+)-uptake v Na(+)/Ca(2+)-exchange to cytosolic Ca(2+)-elimination. In non-failing human myocardium, Ca(2+), ISO, and pyruvate exerted significant positive inotropic effects (increase in twitch force by maximally 396%, 437%, and 82%, respectively). The inotropic effects were associated with increasing RCCs (by 147%, 193%, and 51%, respectively). In failing myocardium, the inotropic effects of Ca(2+) and ISO were significantly less pronounced (with maximal increases in twitch force by 226% and 138%, respectively), associated with blunted effects on RCCs (increase by 33% and 79%, respectively). In contrast, the inotropic effect of pyruvate was unchanged in failing myocardium (increase by 66%), while the corresponding RCCs increased only by 30%. We conclude that the inotropic effects of Ca(2+), ISO, and pyruvate are associated with a significant increase in SR Ca(2+)-content in non-failing human myocardium. In end-stage failing myocardium, the reduced inotropic response to Ca(2+) and ISO is associated with the inability of the SR to appropriately increase its Ca(2+)-content, possibly related to decreased SR Ca(2+)-ATPase and increased Na(+)/Ca(2+)-exchanger expression. In contrast, the maintained inotropic response to pyruvate despite reduced SR Ca(2+)-loading points to additional subcellular effects such as enhanced myofilament Ca(2+)-responsiveness.