Comparison between two rat sympathetic pathways activated in cold-defense

doi:10.1152/ajpregu.00850.2005

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Comparison between two rat sympathetic pathways activated in cold-defense

Youichirou Ootsuka¹ and Robin M McAllen²^*

¹ University of Melbourne, Howard Florey Institute of Experimental Physiology and Medicine, Parkville, Australia
² University of Melbourne, Howard Florey Institute of Experimental Physiology and Medicine, Parkville, Australia; Dept. of Anatomy and Cell Biology , University of Melbourne, Victoria, Australia

^* To whom correspondence should be addressed. E-mail: rmca{at}hfi.unimelb.edu.au.

In cold defense and fever, activity increases in sympatheticnerves supplying both tail vessels and interscapular brown adiposetissue (iBAT). These mediate cutaneous vasoconstrictor and thermogenicresponses, respectively, and both depend upon neurons in therostral medullary raphe. To examine the commonality of braincircuits driving these two outflows, activity was recorded simultaneouslyfrom sympathetic fibers in the ventral tail artery (tail SNA)and the nerve to iBAT (iBAT SNA) in urethane-anesthetized rats.From a warm baseline, cold-defense responses were evoked byintermittently circulating cold water through a water jacketaround the animal's shaved trunk. Repeated episodes of trunkskin cooling decreased core (rectal) temperature. The thresholdskin temperature to activate iBAT SNA was 37.3±0.5 °C(n=7), significantly lower than that to activate tail SNA (40.1±0.4°C; P<0.01, n=7). A fall in core temperature alwaysstrongly activated tail SNA (threshold 38.3±0.2 °C,n=7), but its effect on iBAT SNA was absent (2 of 7 rats) orweak (threshold 36.9±0.1 °C, n=5). The relative sensitivityto core vs skin cooling (K-ratio) was significantly greaterfor tail SNA than for iBAT SNA. Spectral analysis of pairedrecordings showed significant coherence between tail SNA andiBAT SNA only at 1.0±0.1 Hz. The coherence was due entirelyto the modulation of both signals by the ventilatory cycle becauseit disappeared when the coherence spectrum was partialized withrespect to airway pressure. These findings indicate that independentcentral pathways drive cutaneous vasoconstrictor and thermogenicsympathetic pathways during cold-defense.

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