Hibernating Myocardium: A Review

doi:10.1006/jmcc.1996.0229

Journal of Molecular and Cellular Cardiology

Volume 28, Issue 12, December 1996, Pages 2359-2372

https://doi.org/10.1006/jmcc.1996.0229 Get rights and content

Abstract

Within a few seconds after a sudden reduction of coronary blood flow regional contractile dysfunction ensues. The mechanisms responsible for the rapid reduction in contractile function during acute myocardial ischemia remain unclear, but may involve a rise in inorganic phosphate. When severe ischemia, such as resulting from a sudden and complete coronary artery occlusion, is prolonged for more than 20–40 min, myocardial infarction develops, and there is irreversible loss of contractile function. When myocardial ischemia is less severe but nevertheless prolonged, the myocardium is dysfunctional but can remain viable. In such ischemic and dysfunctional myocardium, contractile function is reduced in proportion to the reduction in regional myocardial blood flow; i.e. a state of “perfusion-contraction matching” exists. The metabolic status of such myocardium improves over the first few hours, as myocardial lactate production is attenuated and creatine phosphate, after an initial reduction, returns towards control values. Ischemic myocardium, characterized by perfusion-contraction matching, metabolic recovery and lack of necrosis, has been termed “short-term hibernating myocardium”. Short-term hibernating myocardium can respond to an inotropic stimulation with increased contractile function, however, at the expense of a renewed worsening of the metabolic status. This situation of an increased regional contractile function at the expense of metabolic recovery during inotropic stimulation can be used to identify short-term hibernating myocardium. When inotropic stimulation is prolonged, the development of short-term hibernation is impaired and myocardial infarction develops. The mechanisms responsible for the development of short-term myocardial hibernation remain unclear at present; a significant involvement of adenosine and of activation of ATP-dependent potassium channels has been excluded. Whereas short-term hibernation is well characterized in animal experiments, the existence of hibernation over weeks or months (long-term hibernation) can only be inferred from clinical studies. Hibernation, as defined by Rahimtoola, is a state of chronic contractile dysfunction which is fully reversible upon reperfusion. Clinical syndromes consistent with the existence of myocardial hibernation include unstable and stable angina, acute myocardial infarction and left ventricular dysfunction and/or congestive heart failure. In long-term hibernating myocardium morphological alterations occur; the myofibrils are reduced in number and disorganized and myocardial glycogen content as well as the extracellular collagen network are increased. Thus, despite the fact that the myocardium remains viable during persistent ischemia and contractile dysfunction is reversible upon reperfusion, there are severe morphological alterations. Understandably, full functional recovery following reperfusion might therefore require weeks or even months.

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However, the BCIS-I (Balloon-Pump Assisted Coronary Intervention Study) trial (21) did demonstrate mortality benefit in those with a high jeopardy score and severe left ventricular dysfunction undergoing elective PCI. Jeopardy scores confirm that LMS intervention is associated with a very large area of myocardium at risk (21–24), and the majority of the LV is likely to be hibernating/stunned as a consequence of unprotected LMS occlusion (25). In our institutional experience of ULMSO (3,4), pulmonary edema may not be present on arrival in hospital, but it occurs shortly thereafter mandating use of mechanical hemodynamic support early during the procedure.
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Presentation with ULMSO, compared with nonocclusive LMS disease, was associated with a doubling in the likelihood of periprocedural shock (57.9% vs. 27.9%; p < 0.001) and/or intra-aortic balloon pump support (52.5% vs. 27.2%; p < 0.001). In-hospital (43.3% vs. 20.6%; p < 0.001), 1-year (52.8% vs. 32.4%; p < 0.001), and 3-year mortality (73.9% vs 52.3%, p < 0.001) rates were higher in patients with ULMSO, compared with patients presenting with a patent LMS, and were significantly influenced by the presence of cardiogenic shock. ULMSO and cardiogenic shock were independent predictors of 30-day (hazard ratio [HR]: 1.61 [95% confidence interval (CI): 1.07 to 2.41], p = 0.02, and HR: 5.43 [95% CI: 3.23 to 9.12], p<0.001, respectively) and 3-year all-cause mortality (HR: 1.52 [95% CI: 1.06 to 2.17], p = 0.02, and HR: 2.98 [95% CI: 1.99 to 4.49], p < 0.001, respectively).
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^☆: Gerd Heusch, Professor and Chairman, Department of Pathophysiology, Center of Internal Medicine and Rainer Schulz, Assistant Professor, Department of Pathophysiology, Center of Internal Medicine, University of Essen, School of Medicine, Hufelandstraße 55, 45122 Essen, Germany

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Regular PaperHibernating Myocardium: A Review☆

Abstract

Regular Paper
Hibernating Myocardium: A Review☆