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Peripherally infused somatostatin in humans reduces the acute ventilatory response to hypoxia but it is not known if it reduces basal minute ventilation, and there are conflicting results as to whether or not it reduces the acute hypercapnic ventilatory response. One explanatory mechanism for all these possible effects is that somatostatin reduces metabolic rate. We therefore tested the hypothesis that somatostatin can reduce whole-body metabolic rate (measured by gas exchange at the mouth) in a manner that (a) reduces basal minute ventilation, (b) reduces ventilatory response to acute hypoxia, and (c) reduces ventilatory response to acute hypercapnia. Seven healthy volunteers underwent two protocols, one with saline control and one with somatostatin infusion (0.5mg/h) consisting of a 15-min period of resting breathing (end-tidal [Formula: see text] held at 100Torr with background isocapnia) followed by 5min of isocapnic hypoxia (end-tidal [Formula: see text] 50Torr), and after 1min euoxic recovery, 5min of euoxic hypercapnia (end-tidal [Formula: see text] 45Torr), followed by recovery. Somatostatin modestly but significantly (p<0.05) reduced CO2 output, but not O2 uptake. However, somatostatin did not change basal minute ventilation. Acute hypoxic ventilatory response was greatly reduced by 82% and acute hypercapnic ventilatory response by 26% (p<0.05). We conclude that while somatostatin does influence metabolism, this effect is too subtle to explain the large reduction in chemoreflex activity, which is more likely due to direct effects of the drug on the carotid body.

Original publication

DOI

10.1016/B978-0-444-63274-6.00017-5

Type

Journal article

Journal

Prog Brain Res

Publication Date

2014

Volume

209

Pages

331 - 340

Keywords

chemoreflexes, gas exchange, hypercapnia, hypoxia, metabolism, neuropeptides, somatostatin, ventilation, ventilatory control, Adult, Basal Metabolism, Female, Hormones, Humans, Hypoxia, Male, Reflex, Respiration, Somatostatin, Young Adult