End-systolic pressure-dimension relationship of in situ mouse left ventricle.

The increasing popularity of genetically engineered mice in cardiovascular research has made it important to evaluate cardiac function in small animals. We have developed a system to enable simultaneous pressure-dimension analysis of the mouse left ventricle. The chest was opened under anesthesia, and a 1.4 F micromanometer catheter was inserted into the left ventricle through the apex. A pair of sonomicrometry crystals were attached to the anterior and posterior walls using tissue adhesive. Pressure and dimension were recorded simultaneously at baseline and after isoproterenol injection (1 micro g, intraperitoneally). The ascending aorta was occluded transiently to estimate the end-systolic pressure-dimension relationship (ESPDR), which was parameterized subsequently by the quadratic equation: Pes=C2 X (Des-D0)2+E0 X (Des-D0), where Pes is end-systolic pressure, Des is end-systolic dimension, D0 is the dimension axis intercept, E0 is the local slope at D0, and C2 is the curvilinearity coefficient. The maximum and minimum external dimensions at baseline were 5.82+/-0.50 (s.d.) mm and 5.49+/-0.46 mm with fractional shortening of 0.057+/-0.014 (n=12). The ESPDR was significantly curvilinear and increased convexity after isoproterenol injection (C2, -444+/-281 to -1113+/-780 mmHg/mm2, P<0. 05; E0, 536+/-175 to 889+/-276 mmHg/mm, P<0.001), while the dimension axis intercept remained relatively constant (D0, 5.39+/-0. 46 to 5.37+/-0.52 mm). In conclusion, the combination of miniature piezo-electric crystals and a micromanometer enables continuous measurement of pressure and dimension of in situ mouse left ventricle. This technology may be useful in evaluating the cardiac phenotype of genetically engineered mice.