Adaptive Response of Brain Tissue Oxygenation to Environmental Hypoxia in Non-sedated, Non-anesthetized Arctic Ground Squirrels

Overview

Journal Comp Biochem Physiol A Mol Integr Physiol

Specialties Molecular Biology
Physiology

Date 2009 Jun 30

PMID 19559806

Citations 4

Authors

Yilong Ma

Shufen Wu

Brian Rasley

Lawrence Duffy

Affiliations

Soon will be listed here.

Abstract

The present study examined the physiological mechanisms of the responses of brain tissue oxygen partial pressure (P(t)O(2)), brain temperature (T(brain)), global oxygen consumption (V(O2)), and respiratory frequency (f(R)) to hypoxia in non-sedated and non-anesthetized arctic ground squirrels (Spermophilus parryii, AGS) and rats. We found that (1) in contrast to oxygen partial pressure in blood (P(a)O(2)), the baseline value of P(t)O(2) in summer euthermic AGS is significantly higher than in rats; (2) both P(t)O(2) and P(a)O(2) are dramatically reduced by inspired 8% O(2) in AGS and rats, but AGS have a greater capacity in P(t)O(2) to cope with environmental hypoxia; (3) metabolic rate before, during, and after hypoxic exposure is consistently lower in AGS than in rats; (4) the respiratory responding patterns to hypoxia in the two species differ in that f(R) decreases in AGS but increases in rats. These results suggest that (1) AGS have special mechanisms to maintain higher P(t)O(2) and lower P(a)O(2,) and these levels in AGS represent a typical pattern of adaptation of heterothermic species to and a brain protection from hypoxia; (2) AGS brain responds to hypoxia through greater decreases in P(t)O(2) and decreased f(R) and ventilation. In contrast, rat brain responds to hypoxia by less reduction in P(t)O(2) and increased f(R) and ventilation.

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