Variability in Orthostatic Tolerance During Heat Stress: Cerebrovascular Reactivity to Arterial Carbon Dioxide
Lee JF, Christmas KM, Harrison ML, Hurr C, Kim K, Brothers RM. Variability in orthostatic tolerance during heat stress: cerebrovascular reactivity to arterial carbon dioxide. Aviat Space Environ Med 2014; 85:624–30.
Introduction: A high degree of interindividual variability exists in the magnitude of heat stress (HS)-induced reductions in orthostatic tolerance relative to normothermia (NT). This variability may be associated with HS-mediated reductions in cerebral perfusion (indexed as middle cerebral artery blood velocity; MCAVmean) and altered cerebrovascular regulation. Methods: We tested the hypothesis that cerebrovascular reactivity to hypocapnia would be positively correlated with differences in tolerance to lower body negative pressure (LBNP) [assessed with a cumulative stress index (CSI)] between HS and NT (CSIdiff). Subjects (N = 13) underwent LBNP twice (NT and HS) separated by > 72 h to assess CSI. On a third day, cerebrovascular reactivity [changes in cerebral vascular conductance (CVCi) during hyperventilation-induced hypocapnia (indexed by end tidal carbon dioxide; PETco2)] was assessed during NT, HS, and HS+LBNP (−20 mmHg; HSLBNP). Results: Tolerance to LBNP was reduced after a 1.5 ± 0.1°C increase in internal temperature and a high degree of variability was observed for CSIdiff (range: 122 to 1826 mmHg · min−1). The magnitude of reduction in CVCi during voluntary hyperventilation-induced hypocapnia (−16 ± 5 Torr) was attenuated during HS and HSLBNP vs. NT (NT: −0.20 ± 0.09 cm · s−1 · mmHg−1; HS: −0.12 ± 0.09 cm · s−1 · mmHg−1; HSLBNP: −0.11 ± 0.11 cm · s−1 · mmHg−1); however, no relationship existed between ΔCVCi/ PETco2 and CSIdiff in any condition. Conclusions: Cerebrovascular reactivity to hyperventilation-induced hypocapnia is attenuated when internal temperature is elevated, perhaps as a protective mechanism to protect against further reductions in the already diminished cerebral perfusion in this thermal state. However, individual differences in these responses do not appear to predict orthostatic tolerance during HS.
Introduction: A high degree of interindividual variability exists in the magnitude of heat stress (HS)-induced reductions in orthostatic tolerance relative to normothermia (NT). This variability may be associated with HS-mediated reductions in cerebral perfusion (indexed as middle cerebral artery blood velocity; MCAVmean) and altered cerebrovascular regulation. Methods: We tested the hypothesis that cerebrovascular reactivity to hypocapnia would be positively correlated with differences in tolerance to lower body negative pressure (LBNP) [assessed with a cumulative stress index (CSI)] between HS and NT (CSIdiff). Subjects (N = 13) underwent LBNP twice (NT and HS) separated by > 72 h to assess CSI. On a third day, cerebrovascular reactivity [changes in cerebral vascular conductance (CVCi) during hyperventilation-induced hypocapnia (indexed by end tidal carbon dioxide; PETco2)] was assessed during NT, HS, and HS+LBNP (−20 mmHg; HSLBNP). Results: Tolerance to LBNP was reduced after a 1.5 ± 0.1°C increase in internal temperature and a high degree of variability was observed for CSIdiff (range: 122 to 1826 mmHg · min−1). The magnitude of reduction in CVCi during voluntary hyperventilation-induced hypocapnia (−16 ± 5 Torr) was attenuated during HS and HSLBNP vs. NT (NT: −0.20 ± 0.09 cm · s−1 · mmHg−1; HS: −0.12 ± 0.09 cm · s−1 · mmHg−1; HSLBNP: −0.11 ± 0.11 cm · s−1 · mmHg−1); however, no relationship existed between ΔCVCi/ PETco2 and CSIdiff in any condition. Conclusions: Cerebrovascular reactivity to hyperventilation-induced hypocapnia is attenuated when internal temperature is elevated, perhaps as a protective mechanism to protect against further reductions in the already diminished cerebral perfusion in this thermal state. However, individual differences in these responses do not appear to predict orthostatic tolerance during HS.
Keywords: hyperthermia; hypocapnia; inter-individual variability; simulated hemorrhage
Document Type: Research Article
Affiliations: Environmental and Autonomic Physiology Laboratory, Department of Kinesiology and Health Education, University of Texas at Austin, Austin, TX, USA
Publication date: 01 June 2014
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