O ver the years the management of patients in intensive care units (ICUs) after myocardial infarction (MI) has become increasingly intensive in an attempt to anticipate events and allow early intervention. These management strategies inadvertently increase noise, light, and multiple other well-established stimuli in the ICU environment. This has resulted in a generally clinically unappreciated disruption of the endogenous circadian rhythms and sleep in acutely ill patients.
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Editorial, see p 1675Maintaining normal circadian rhythms is important because these are fundamental determinants of healthy cardiac physiology (eg, the cyclic variation in heart rate, blood pressure, and sympathovagal balance of the autonomic nervous system). [3][4][5][6] Although circadian rhythms in timing of onset and tolerance to MIs are well established, 7-11 the consequences of rhythm disturbance early after MI have not been reported. The heart is relatively incapable of myocyte regeneration, and early healing after MI relies on coordinated removal of dead tissue through an early inflammatory phase, 12 followed by replacement and remodeling of the myocardium and extracellular matrix. 13 As remodeling progresses toward the maturation phase, the heart changes size, shape, and structure, and these processes can lead to ventricular dilation, dysfunction, and ultimately failure.14 Whether short-term diurnal rhythm disruption after MI would impair the critical, orderly, temporal Objective: Short-term diurnal rhythm disruption immediately after MI impairs remodeling and adversely affects long-term cardiac structure and function in a murine model.
Methods and Results: Mice were infarcted by left anterior descending coronary artery ligation (MI model) withina 3-hour time window, randomized to either a normal diurnal or disrupted environment for 5 days, and then maintained under normal diurnal conditions. Initial infarct size was identical. Short-term diurnal disruption adversely affected body metabolism and altered early innate immune responses. In the first 5 days, crucial for scar formation, there were significant differences in cardiac myeloperoxidase, cytokines, neutrophil, and macrophage infiltration. Homozygous clock mutant mice exhibited altered infiltration after MI, consistent with circadian mechanisms underlying innate immune responses crucial for scar formation. In the proliferative phase, 1 week after MI, this led to significantly less blood vessel formation in the infarct region of disrupted mice; by day 14, echocardiography showed increased left ventricular dilation and infarct expansion. These differences continued to evolve with worse cardiac structure and function by 8 weeks after MI.
Conclusions:
