Background-Synchrotron radiation has been used to analyze crossbridge dynamics in isolated papillary muscle and excised perfused hearts with the use of x-ray diffraction techniques. We showed that these techniques can detect regional changes in rat left ventricle contractility and myosin lattice spacing in in situ ejecting hearts in real time. Furthermore, we examined the sensitivity of these indexes to regional ischemia. Methods and Results-The left ventricular free wall of spontaneously beating rat hearts (heart rate, 290 to 404 bpm) was directly exposed to brief high-flux, low-emittance x-ray beams provided at SPring-8. Myosin mass transfer to actin filaments was determined as the decrease in reflection intensity ratio (intensity of 1,0 plane over the 1,1 plane) between end-diastole and end-systole. The distance between 1,0 reflections was converted to a lattice spacing between myosin filaments. We found that mass transfer (mean, 1.71Ϯ0.09 SEM, nϭ13 hearts) preceded significant increases in lattice spacing (2 to 5 nm) during systole in nonischemic pericardium. Left coronary occlusion eliminated increases in lattice spacing and severely reduced mass transfer (PϽ0.01) in the ischemic region. Conclusions-Our results suggest that x-ray diffraction techniques permit real-time in situ analysis of regional crossbridge dynamics at molecular and fiber levels that might also facilitate investigations of ventricular output regulation by the Frank-Starling mechanism. Key Words: ischemia Ⅲ myocardial contraction Ⅲ myosin Ⅲ radiography D espite the history of studies on crossbridge dynamics, lower photon counts and poorer quality of diffraction patterns obtained from cardiac muscle than skeletal and insect flight muscles 1-3 have limited progress with cardiac muscle until recently. 4,5 Some of us used third-generation synchrotron radiation (SPring-8, Japan Synchrotron Radiation Research Institute) to determine x-ray diffraction patterns in excised, perfused rat hearts while moving systematically across the left ventricular (LV) equator from the epicardium through to the ventricular cavity. 6 X-ray diffraction patterns of cardiac muscle produce 2 equatorial-position reflections from the lattice-like arrangement of its protein elements. 2 Mass transfer of myosin heads to actin during contraction is inferred from a decrease in the integrated 1,0 reflection intensity (I 1,0 , lattice plane containing only thick myosin filaments) and an increase in 1,1 reflection intensity (I 1,1 , plane with thick myosin and thin actin filaments). 7 The myocardial intensity ratio (defined as I 1,0 /I 1,1 ) is minimal in the rigor state and maximal in a quiescent state. 1,2,6,8 Furthermore, the distance between 1,0 reflection peaks (d 1,0 spacing) represents the myosin lattice spacing, which is inversely related to sarcomere length in isolated fibers 5 as static myocytes maintain a constant cell volume. Whether decreases in myofilament spacing contribute to increasing Ca 2ϩ sensitivity and increased probability of crossbridge formation at longe...
