Avoidance behavior and genetic predisposition to hypertension

Voluntary blood pressure control by biofeedback: relationship to psychological characteristics

1. Psychological characteristics were studied in 25 hypertensives (mean and standard deviation of blood pressure 150/95 +/- 12/5 mmHg), who received blood pressure (BP) biofeedback (BFB). Personality factors and success in BFB-BP modifying ability were correlated and the predictive value of psychological factors was estimated. 2. Questionnaires consisted of a Locus of Control of Behaviour (LCB) scale, the Spielberger state trait anxiety inventory and the Framingham Type A personality inventory. 3. BP was monitored continuously from the finger by volume clamp plethysmography during eight BFB sessions, each with three trials of raising, ignoring and lowering systolic blood pressure (SP). 4. SP was raised/lowered by 12 +/- 11/6 +/- 9 mmHg and heart rate (HR) increased by 10 +/- 3.9/+ 1 +/- 6.1. Ten subjects were able to lower SP by greater than or equal to 5 mmHg (15 +/- 7.5) and raise it by 17 +/- 11. The others achieved no decrease in SP and were also less successful at raising (8 mmHg, P = 0.04). 5. Changes in LCB and trait anxiety correlated with DP rise, whereas type A and pre-study state anxiety correlated with rising HR. Lowering of SP correlated weakly with change in LCB (r = 0.47, P = 0.06). 6. Combinations of psychological factors had independent predictive value for BP and HR change: trait anxiety (P = 0.03) and change in LCB (P = 0.009) with rise in diastolic blood pressure (DP); type A (P = 0.009), pre-study LCB (P = 0.02) and pre-study state anxiety (P = 0.01) with HR rise.(ABSTRACT TRUNCATED AT 250 WORDS)

Exploration, fear and maze learning in spontaneously hypertensive and normotensive rats

In this study the performance of normotensive (WKY) rats was compared with that of hypertensive (SHR) rats on a Novel Object Test, a standardized Fear Test, and the Hebb-William's maze. We found no strain differences for exploration; however, WKY rear and ambulate more than SHR near the walls of the apparatus. There were no strain differences apparent in the Fear Test. WKY showed markedly different behavior compared with SHR on the Hebb-William's maze; WKY showed a high level of stereotyped displacement behaviors and failed to improve their performance over successive trials. Overall, WKY appear to be more reactive to environmental conditions than SHR. The behavior of both strains is highly context dependent.

Alveolar permeability to protein in rats differentially susceptible to ozone

Sprague-Dawley rats susceptible (DS) to NaCl-induced hypertension suffer higher mortality when exposed daily to 2.0 ppm ozone than do hypertension-resistant (DR) rats, independent of salt in the diet or systemic blood pressure. To investigate one possible contribution to this differential sensitivity to ozone, alveolar permeabilities to serum albumin were measured both in ozone-exposed and in control DS and DR rats. Female rats aged 5-7 weeks maintained on a low-salt (0.4% NaCl) diet were injected intravenously with 125I-bovine serum albumin and were then exposed to either 2.0 ppm ozone or air for 5 h. After pentobarbital anesthesia, the rats were exsanguinated and their lungs were lavaged in situ with saline. Lavage fluids and blood samples were measured for radioactivity using a NaI-well gamma counter. The results indicated that while DS and DR control rats have similar pulmonary permeabilities to 125I-albumin, the lungs of the ozone-exposed DS animals were 63% (p less than 0.02) more permeable than those of DR rats exposed to ozone. Sloughing of epithelial tissue, mucous formation and an accumulation of macrophages in the end-airways were more pronounced among ozone-exposed DS animals than in DR-ozone-exposed rats. This increased damage among DS rats correlated well with the increased protein permeability levels. In similar studies, Sprague-Dawley (D) rats were more variable in their response to ozone than either inbred strain. However, the results appeared generally more like those of the DS animals, suggesting that the trait selected by inbreeding may have been resistance rather than sensitivity to ozone-induced lung injury.

Is the hypertensive rat really hyperreactive?

This study investigated the behavior of hypertensive-prone and nonhypertensive-prone rat strains to see whether there are differences in behavioral reactivity to environmental stimulation. Of primary interest was general activity, because investigators have assumed it to be an index of reactivity to environmental stimulation and to be correlated with the elevation of blood pressure in spontaneously hypertensive rats (SHR) but not in normotensive Wistar-Kyoto (WKY) rats. Therefore, general activity was assessed in SHRs and WKYs as a function of walking and rearing in an open field (Experiments 1 and 2) and crossings in a shuttlebox test (Experiments 3, 4, and 5). Activity was assessed under a constant level of environmental stimulation in the open field (Experiment 1) and shuttlebox (Experiment 3) or under varying degrees of stimulation in the open field (Experiment 2) and shuttlebox (Experiments 4 and 5). In the open field and the shuttlebox, SHR activity was above WKY activity when the degree of environmental stimulation was constant. However, when stimulation was manipulated, the SHR activity level was similar for all intensity levels, while the WKY activity was inversely related to stimulus intensity. These results suggest that while the SHRs may generally be more active than WKYs, WKYs display a greater behavioral reactivity to environmental stimulation than SHRs.

Genetic predisposition to hypertension, elevated blood pressure and pain sensitivity: a functional analysis

Pain sensitivity was examined in Dahl hypertension-sensitive (DS) and Dahl hypertension-resistant (DR) rats. The results indicated that hypertensive DS rats had a reduced sensitivity to painful stimulation compared to normotensive DS rats or compared to DR rats. Furthermore, the lower pain sensitivity of even normotensive DS vis-a-vis normotensive DR rats was not due to genetic factors but due to slight variations in blood pressure between lines. These results provide additional experimental support for the contention that elevations in blood pressure result in decreased pain sensitivity.