Vasodilatation is obligatory for contraction-induced hyperaemia in canine skeletal muscle

doi:10.1113/jphysiol.2004.062836

Vasodilatation is obligatory for contraction-induced hyperaemia in canine skeletal muscle

Jason J. Hamann, John B. Buckwalter and Philip S. Clifford

Medical College of Wisconsin and VA Medical Center, Milwaukee, WI 53295, USA

There is a rapid increase in blood flow to active skeletal musclewith the onset of exercise, but the mechanism(s) eliciting thisincrease remains elusive. We hypothesized that the rapid increasein blood flow to active skeletal muscle with the onset of exerciseis attributable to vasodilatation as a consequence of smoothmuscle hyperpolarization. To test this hypothesis we examinedthe blood flow response to a brief tetanic contraction in whichpotassium (K⁺) was infused intra-arterially to elevate the [K⁺]_oand clamp the smooth muscle membrane potential within the skeletalmuscle vascular bed. In six anaesthetized beagle dogs controlcontractions increased hindlimb blood flow by 97 ± 14ml min^–1. During K⁺ infusion the hyperaemic response tocontraction was 8 ± 3 ml min^–1. Since the hindlimbblood flow was reduced during K⁺ infusion, a similar reductionin baseline blood flow was produced with phenylephrine infusion.During phenylephrine infusion the hyperaemic response to contractionwas preserved (89 ± 23 ml min^–1). Recovery contractionsperformed after the discontinuation of the K⁺ infusion elicitedblood flow responses similar to control (100 ± 11 mlmin^–1). In a separate experimental protocol using theisolated gastrocnemius muscle of mongrel dogs (n= 6) K⁺ infusiondid not alter force production by the skeletal muscle. Our dataindicate that in the absence of vasodilatation, there is virtuallyno change in blood flow. One implication of this finding isthat the muscle pump cannot be responsible for the initial contraction-inducedhyperaemia. We conclude that the increase in blood flow immediatelyfollowing a single muscle contraction is due to vasodilatation,presumably as a consequence of smooth muscle hyperpolarization.

(Received 16 February 2004; accepted after revision 7 April 2004; first published online 8 April 2004)
Corresponding author P. S. Clifford: VA Medical Center, Anaesthesia Research 151, 5000 W National Avenue, Milwaukee, WI 53295, USA. Email: pcliff{at}mcw.edu

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