M. A. Boegehold scite author profile

American Journal of Physiology-Heart and Circulatory Physiology

1993

This study evaluated the influence of high dietary salt intake on nitric oxide (NO) activity in the arteriolar network of rats resistant to salt-induced hypertension. The spinotrapezius muscle microvasculature was studied in inbred Dahl salt-resistant (SR/Jr) rats fed low (0.45%)- or high (7%)-salt diets for 4-5 wk. Arterial pressures were not different between groups at any time during the study. NO synthesis inhibition with NG-nitro-L-arginine-methyl ester (L-NAME) constricted arcade arterioles in low-salt SR/Jr and dilated arcade arterioles in high-salt SR/Jr. Arcade arteriole dilation to acetylcholine (ACh), but not sodium nitroprusside (SNP), was impaired in high-salt SR/Jr. In contrast, transverse and distal arteriole responses to L-NAME, ACh, and SNP were identical in high- and low-salt SR/Jr. These findings indicate that high salt intake, in the absence of increased arterial pressure, suppresses the influence of basal and evoked NO on vascular tone in arcading arterioles, but not in smaller transverse and distal arterioles. Unaltered SNP responses in high-salt SR/Jr suggest that this effect does not involve a change in arteriolar smooth muscle responsiveness to NO.

Response of arteriolar network of skeletal muscle to sympathetic nerve stimulation

American Journal of Physiology-Heart and Circulatory Physiology

Johnson

1988

The influence of vessel location on arteriolar responses to sympathetic nerve stimulation was systematically studied in a skeletal muscle arteriolar network under normal and altered tissue O2 levels. The exteriorized cat sartorius muscle was exposed to 0, 5, and 10% ambient O2 during sympathetic chain stimulation at 8 pulses/s. Under 0% O2, stimulation initially caused a 25-45% constriction that was faster and more pronounced in distal arterioles. Ninety-one percent of vessels showed a secondary dilation (sympathetic escape), which was largest in distal arterioles. Escape had little effect on calculated volume flow, which, after a large initial fall, showed a modest secondary increase. Under 5 and 10% O2, resting arteriolar diameter was reduced by 12 and 17%, respectively, and escape was reduced by 60 and 73%. Escape was not attenuated in proximal arterioles preconstricted with vasopressin, suggesting that O2 did not attenuate escape through increased vascular tone. Therefore, the arteriolar response to sympathetic stimulation depends largely on location within the network and is modulated to varying degrees by metabolic influences.

Periarteriolar and tissue PO2 during sympathetic escape in skeletal muscle

American Journal of Physiology-Heart and Circulatory Physiology

Johnson

1988

The purpose of this study was to determine whether vascular escape from sympathetic nerve stimulation in skeletal muscle is caused by a fall in the tissue O2 level. O2 microelectrodes were used to measure PO2 at the wall of arterioles (periarteriolar PO2) and near the venous end of capillary networks (parenchymal tissue PO2) in the exteriorized cat sartorius muscle during sympathetic nerve stimulation. Measurements were made under a low O2 suffusate (equilibrated with 5% CO2-95% N2) and under a high O2 suffusate (10% O2-5% CO2-85% N2). During sympathetic stimulation under low O2, mean diameter of proximal (second-order) arterioles decreased from 55 to 32 micron before returning to 37 micron (sympathetic escape). Mean periarteriolar PO2 fell from 50 to 25 mmHg with no secondary increase. Distal (fifth-order) arterioles initially constricted from 7 to 4 micron before relaxing to 6 micron. Periarteriolar PO2 of these vessels fell from 40 to 13 mmHg with no secondary increase. During stimulation under high O2, periarteriolar PO2 levels of both proximal and distal arterioles were similar to those under low O2, yet escape was substantially reduced. The lack of relationship between periarteriolar PO2 and vascular escape argues against a role of vascular wall PO2 in this behavior. Parenchymal tissue PO2 fell to 9 mmHg during stimulation under low O2 but did not fall below 22 mmHg during stimulation under high O2. The attenuation of escape under conditions where tissue PO2 did not fall is consistent with the hypothesis that sympathetic escape in skeletal muscle is mediated through a fall in parenchymal cell PO2.

Nitric oxide modulates arteriolar responses to increased sympathetic nerve activity

Nase

American Journal of Physiology-Heart and Circulatory Physiology

1996

The purpose of this study was to determine whether arteriolar responses to increased sympathetic nerve activity are limited by the actions of endogenous nitric oxide. Intravital microscopy was used to examine diameter responses of small feed arteries (SFA), first-order arterioles (1A) and second-order arterioles (2A) to perivascular sympathetic nerve stimulation in the superfused rat small intestine. Stimulation induced a frequency-dependent constriction in all vessel types that was completely abolished by the alpha-adrenoceptor antagonist phentolamine (10(-6) M). In SFA and 1A, the magnitude of sympathetic constriction was increased significantly in the presence of the nitric oxide synthase inhibitor NG-monomethyl-L-arginine(L-NMMA, 10(-4) M). In SFA (n = 7), stimulation at 3, 8, and 16 Hz induced constrictions of 11 +/- 1, 28 +/- 4, and 42 +/- 3%, respectively, under the normal superfusate vs. 28 +/- 3, 46 +/- 5, and 76 +/- 3% in the presence of L-NMMA. For 1A (n = 7), stimulation induced constrictions of 10 +/- 1, 27 +/- 4, and 37 +/- 3% under the normal superfusate vs. 24 +/- 2, 47 +/- 3, and 72 +/- 4% in the presence of L-NMMA. The effect of L-NMMA on sympathetic constriction in SFA (n = 7) was completely reversed by the additional presence of 5 x 10(-3) M L-arginine in the superfusate. These results suggest that endogenous nitric oxide activity can attenuate sympathetic neurogenic constriction in the intestinal microvasculature.

Importance of dietary chloride for salt sensitivity of blood pressure.

1991

Hypertension