Regional reductions in coronary flow in dogs caused myofibrillar disruption, with aberrant perinuclear aggregates in 34% of hibernating and 68% of stunned subendocardial myocytes.
Regional reductions in coronary flow in a canine model lead to early myofibrillar disruption in both hibernating and stunned myocardium, potentially reflecting early reversible changes seen in patients requiring revascularization.
Chronically instrumented dogs underwent 2- or 5-h regional reductions in coronary flow that were followed, respectively, by balanced reductions in myocardial contraction and O(2) consumption ("hibernation") and persistently reduced contraction despite normal myocardial O(2) consumption ("stunning"). Previously unidentified myofibrillar disruption developed during flow reduction in both experimental models and persisted throughout the duration of reperfusion (2-24 h). Aberrant perinuclear aggregates that resembled thick filaments and stained positively with a monoclonal myosin antibody were present in 34 +/- 3.8% (SE) and 68 +/- 5.9% of "hibernating" and "stunned" subendocardial myocytes in areas subjected to flow reduction and in 16 +/- 2.5% and 44 +/- 7.4% of subendocardial myocytes in remote areas of the same ventricles. Areas of myofibrillar disruption also showed glycogen accretion and unusual heterochromatin clumping adjacent to the inner nuclear envelope. The degrees of flow reduction employed were sufficient to reduce regional myofibrillar creatine kinase activity by 25-35%, but troponin I degradation was not evident. The observed changes may reflect an early, possibly reversible, phase of the myofibrillar loss characteristic of hypocontractile myocardium in patients undergoing revascularization.
Sherman et al. (Sat,) conducted a other in Hypocontractile myocardium (hibernation and stunning). Regional reductions in coronary flow vs. Remote areas of the same ventricles was evaluated on Myofibrillar disruption (aberrant perinuclear aggregates). Regional reductions in coronary flow in dogs caused myofibrillar disruption, with aberrant perinuclear aggregates in 34% of hibernating and 68% of stunned subendocardial myocytes.
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