Attenuation of Neurogenic Vasoconstriction by Nitric Oxide in Hindlimb Microvascular Beds of the Rat In Vivo

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Hypertension. 1997;30:957-961

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NITRIC OXIDE

Attenuation of Neurogenic Vasoconstriction by Nitric Oxide in Hindlimb Microvascular Beds of the Rat In Vivo

Heinz-Joachim Häbler; Gunnar Wasner; ; Wilfrid Jänig

From the Physiologisches Institut, Christian-Albrechts-Universität, Kiel, Germany.

Correspondence to Dr H.-J. Häbler, Physiologisches Institut, Christian-Albrechts-Universität, Olshausenstrasse 40, 24098 Kiel, FRG. E-mail j.haebler{at}physiologie.uni-kiel.de

Abstract There is evidence that sympathetic nerve activity leadsto endothelium-derived nitric oxide release, which in turn attenuatesneurogenic vasoconstriction. Here we tested in vivo (1) whetherthe magnitude of the vasoconstriction induced by N^G-nitro-L-argininemethyl ester given systemically is altered when ongoing sympatheticactivity is abolished by sectioning the lumbar sympathetic trunk,and (2) whether hindlimb sympathetic vasoconstriction elicitedby electrical stimulation of the lumbar sympathetic trunk isenhanced after inhibition of nitric oxide synthesis. Blood flowin the microvascular beds of hairless skin and skeletal muscleof the rat hindlimb was measured with laser Doppler flowmetry.Sectioning the lumbar sympathetic trunk resulted in an increaseof blood flow in both tissues, indicating that tonic neurogenicvasoconstriction was abolished. Inhibition of nitric oxide synthesisresulted in vasoconstriction in both vascular beds. This vasoconstrictionwas more pronounced after abolition of sympathetic activitythan with intact sympathetic supply in skin but was smallerin skeletal muscle. The vasoconstriction elicited by gradedelectrical stimulation of the centrally sectioned lumbar sympathetictrunk with frequencies less than 5 Hz was significantly enhancedafter blockade of nitric oxide in skeletal muscle but not inskin microvasculature. These findings suggest that under physiologicalconditions, sympathetic nerve impulses directly promote therelease of nitric oxide in skeletal muscle but not in cutaneousblood vessels. Therefore, basal nitric oxide release is probablyin part dependent on sympathetic activity in skeletal muscle,whereas it appears to be mainly due to flow-dependent shearstress in hairless skin microvasculature.

Key Words: nitric oxide • L-NAME • sympathetic nervous system • vasoconstriction • microcirculation • hindlimb

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