Characteristic dysfunction of stunned myocardium induced by 2,3-butanedione monoxime without ischaemia.

1. In the present study, we tested the hypothesis that, even in the absence of prior ischaemia, 2,3-butanedione monoxime (BDM), an inhibitor of contraction at the actin-myosin level, could produce the postischaemic dysfunction characteristic of stunned myocardium. 2,3-Butanedione monoxime was injected directly into the left anterior descending coronary artery (LAD) before and again after myocardial stunning produced by 15 min occlusion of the LAD followed by 30 min reperfusion. 2. Regional myocardial force, segment shortening and regional work were measured in both the LAD-perfused area and the area perfused by the circumflex coronary artery, which served as a control area. Regional dysfunction produced by BDM injection or ischaemia-reperfusion was assessed quantitatively by five parameters: end-diastolic length (EDL), shortening onset delay (delay), systolic bulge (bulge), end-shortening time delay (EST) and tail work ratio (TWR). 3. It was found that injection of BDM into the LAD caused dyskinesis similar to that caused by occlusion-reperfusion. Both displayed elevated EDL and marked increases in delay, bulge, EST and TWR; these parameters were significantly higher in the dyskinesis caused by BDM injection. Despite dysfunctional fibre shortening, intracoronary BDM injection did not reduce regional force. 4. Thus, BDM can elicit changes similar to those characteristic of postischaemic dysfunction. Because contractility was not impaired, dysfunction was apparently caused by disrupting the association between contractile force and muscle motion.

Hemodynamic simulation of vascular prosthesis altering pulse wave propagation.

Potential clinical application of a computer model of the aorta was investigated to study the influence on pulse wave morphology of vascular prosthesis. Ascending aorta, aortic arch and abdominal aorta were replaced with synthetic graft materials and profiles. Geometric and compliance mismatch of the synthetic graft sections replacing part of the natural vessel resulted in alterations of the pulse waveform. These changes in pressure and flow waveforms were compared to investigate their effects on the vascular system for both the uniform and tapered vessel models.