Echocardiographic measurement of left ventricular mass and volume in normotensive and hypertensive rats. Necropsy validation.

Although rats are commonly used to study left ventricular (LV) hypertrophy, measurement of LV mass and dimensions has required killing the rat. To determine the accuracy of echocardiography in rats, blinded crossectional area (CSA) and LV mass measurements using either the cube function (LVM) or an elliptical model (LVMel) from high resolution M-mode echocardiograms were compared to necropsy LV weight (0.28 to 1.5 g), in 41 normotensive (body weight 116 to 762 g) and 17 hypertensive rats (350 to 560 g). Postmortem chamber volumes in 28 normal rats (0.02 to 0.19 mL) were also compared to echocardiographic volumes derived from the elliptical model. Correlation with LV weight was r = 0.87 for LVM, 0.90 for CSA and 0.93 for LVMel (all P less than .00001). Comparison of hypertensive and body-weight-matched normotensive rats revealed the upper normal limit for both LVMel and CSA to have 89% sensitivity and 100% specificity for detection of post mortem LV hypertrophy. Necropsy LV volumes were more closely related to systolic echocardiographic volumes than to diastolic volumes (r = 0.78 v 0.71, both P less than .00001), compatible with the effects of post mortem contracture. Stroke volume determined invasively in 5 Wistar rats by thermodilution was similar to that obtained using elliptical model echo volumes in 5 rats of the same body size (0.35 +/- 0.05 v 0.30 +/- 0.06 mL/beat). Echocardiography can be used to evaluate LV structure and function in rats and to detect in vivo LV anatomic differences induced by hypertension

Influence of sodium intake on in vivo left ventricular anatomy in experimental renovascular hypertension.

The effect of different dietary salt contents (0.0035, 0.4, and 4%) on in vivo left ventricular (LV) geometry was studied by necropsy-validated echocardiographic methods in groups of 30 two-kidney, one-clip (2K, 1C) and one-kidney, one-clip (1K, 1C) male Wistar rats and two-kidney (2K) and one-kidney (1K) shams 9 wk after surgery. The salt-deficient diet was associated with lower body weight, higher plasma renin activity in both 2K,1C and 2K shams (P < 0.004) and higher hematocrit in 2K,1C (P < 0.02). Blood pressure was increased by high-salt diet in experimental groups but not in shams (P < 0.01). Increase in dietary sodium content was associated with increased cross-sectional area index (CSAI) and LV mass index in 2K rats independently of renal artery stenosis (P < 0.0007) and also in 1K shams (P < 0.01). LV end-diastolic dimension was greater in 1K,1C and 1K shams than in 2K,1C and 2K shams at every level of sodium intake and was directly related to atrial natriuretic factor levels in both 1K,1C (r = 0.68) and 2K,1C (r = 0.59). LV hypertrophy was independently predicted by blood pressure (P < 0.0006) and high-sodium diet (P < 0.05) in 1K rats (multiple r = 0.57, P < 0.001) and by high-sodium diet (P < 0.0001) and low hematocrit (P < 0.05) in 2K rats (multiple r = 0.76, P < 0.0001). Thus provision of normal or high sodium content in the diet was a more consistent stimulus to LV hypertrophy than the level of blood pressure.(ABSTRACT TRUNCATED AT 250 WORDS

Relation of left ventricular hypertrophy, afterload, and contractility to left ventricular performance in Goldblatt hypertension.

To analyze the determinants of left ventricular (LV) performance (myocardial afterload, chamber size, mass, and contractility) in Goldblatt hypertension, 19 anesthetized one-kidney, one-clip (1K1C) and 28 two-kidney, one-clip (2K1C) male Wistar rats were studied 58 to 62 days after clipping, together with 19 sham-operated and 13 normal rats (controls), by M-mode echocardiography using necropsy-validated methods of measurement. The LV fractional shortening was inversely related to end-systolic stress in all groups (r = -0.89 to -0.95, all P less than .00001): 7 2K1C (25%) and 9 1K1C (47%) had fractional shortening above the upper confidence limit in control animals. Both 1K1C and 2K1C with high LV performance had severe hypertension, inadequate LV hypertrophy, with resultant high wall stress (both P less than .005), increased LV chamber dimension (P less than .005 and P less than .05, respectively) and high afterload-corrected fractional shortening (both P less than .001); 2K1C also had high plasma renin activity and atrial natriuretic factor levels (both P less than .01). Rats with normal LV performance exhibited mild hypertension, adequate LV hypertrophy (normalizing wall stress), and normal LV chamber size and afterload-corrected fractional shortening. Thus, 8 1/2 weeks after clipping, adequate LV hypertrophy allows maintenance of normal LV function by normalizing myocardial afterload in a majority of rats with Goldblatt hypertension, whereas increased LV contractility (and possibly use of preload reserve in 1K1C) maintains normal LV function in the presence of inadequate LV hypertrophy and elevated wall stress, in a substantial minority of rats that developed more severe Goldblatt hypertension

In vivo left ventricular anatomy in rats with two-kidney, one clip and one-kidney, one clip renovascular hypertension.

To evaluate differences in left ventricular structural changes related to different hemodynamic patterns. DESIGN: One-kidney, one clip (1K1C; volume-dependent hypertension) rats were two-kidney, one clip (2K1C; high-resistance hypertension) to determine whether these two types of Goldblatt rats showed different types of left ventricular adaptation. METHODS: M-mode echocardiography was used to study 28 2K1C and 19 1K1C Wistar rats 8 weeks after surgery and 55 age-matched control animals. RESULTS: Systolic blood pressure was equally high in the two models; the 1K1C rats had a larger left ventricular chamber and normal plasma renin activity (PRA), whereas in the 2K1C rats PRA was increased and the left ventricular chamber was normal. The atrial natriuretic factor was significantly increased only in the 2K1C rats and was related to PRA. The left ventricular mass index was increased in both models, but more in the 1K1C than the 2K1C rats. CONCLUSIONS: In both models the degree of left ventricular hypertrophy was associated with the interacting effects of the hemodynamic component superimposed on the primary hemodynamic pattern (i.e. blood pressure as an expression of pressure overload in the primarily volume-dependent 1K1C rats and the left ventricular chamber size as an expression of volume overload in the high-resistance 2K1C rats). The interaction between pressure and volume increased the left ventricular wall thickness in both models, with additional chamber enlargement in the 1K1C rats. In these rats, the increase in left ventricular mass was more pronounced due to the greater volume load on the heart