Cerebral uptake of microvesicles occurs in normocapnic but not hypocapnic passive hyperthermia in young healthy male adults

Author:

Parikh Khushali1,Shepley Brooke R.1ORCID,Tymko Michael M.23,Hijmans Jamie G.4,Hoiland Ryan L.25678,Desouza Christopher A.4ORCID,Sekhon Mypinder S.56789,Ainslie Philip N.2ORCID,Bain Anthony R.1ORCID

Affiliation:

1. Faculty of Human Kinetics Department of Kinesiology University of Windsor Windsor ON Canada

2. Centre for Heart, Lung and Vascular Health University of British Columbia Kelowna BC Canada

3. Department of Human Health and Nutritional Sciences College of Biological Science University of Guelph Guelph ON Canada

4. Department of Integrative Biology University of Colorado Boulder Boulder CO USA

5. Division of Critical Care Medicine Department of Medicine Faculty of Medicine University of British Columbia Vancouver BC Canada

6. Division of Neurosurgery Department of Surgery Faculty of Medicine University of British Columbia Vancouver BC Canada

7. International Collaboration on Repair Discoveries University of British Columbia Vancouver BC Canada

8. Collaborative Entity for Researching Brain Ischemia University of British Columbia Vancouver BC Canada

9. Djavad Mowafaghian Centre for Brain Health University of British Columbia Vancouver BC Canada

Abstract

AbstractPassive hyperthermia causes cerebral hypoperfusion primarily from heat‐induced respiratory alkalosis. However, despite the cerebral hypoperfusion, it is possible that the mild alkalosis might help to attenuate cerebral inflammation. In this study, the cerebral exchange of extracellular vesicles (microvesicles), which are known to elicit pro‐inflammatory responses when released in conditions of stress, were examined in hyperthermia with and without respiratory alkalosis. Ten healthy male adults were heated passively, using a warm water‐perfused suit, up to core temperature + 2°C. Blood samples were taken from the radial artery and internal jugular bulb. Microvesicle concentrations were determined in platelet‐poor plasma via cells expressing CD62E (activated endothelial cells), CD31+/CD42b (apoptotic endothelial cells), CD14 (monocytes) and CD45 (pan‐leucocytes). Cerebral blood flow was measured via duplex ultrasound of the internal carotid and vertebral arteries to determine cerebral exchange kinetics. From baseline to poikilocapnic (alkalotic) hyperthermia, there was no change in microvesicle concentration from any cell origin measured (P‐values all >0.05). However, when blood CO2 tension was normalized to baseline levels in hyperthermia, there was a marked increase in cerebral uptake of microvesicles expressing CD62E (P = 0.028), CD31+/CD42b (P = 0.003) and CD14 (P = 0.031) compared with baseline, corresponding to large increases in arterial but not jugular venous concentrations. In a subset of seven participants who underwent hypercapnia and hypocapnia in the absence of heating, there was no change in microvesicle concentrations or cerebral exchange, suggesting that hyperthermia potentiated the CO2/pH‐mediated cerebral uptake of microvesicles. These data provide insight into a potential beneficial role of respiratory alkalosis in heat stress. imageKey points The hyperthermia‐induced hyperventilatory response is observed in most humans, despite causing potentially harmful reductions in cerebral blood flow. We tested the hypothesis that the respiratory‐induced alkalosis is associated with lower circulating microvesicle concentrations, specifically in the brain, despite the reductions in blood flow. At core temperature + 2°C with respiratory alkalosis, microvesicles derived from endothelial cells, monocytes and leucocytes were at concentrations similar to baseline in the arterial and cerebral venous circulation, with no changes in cross‐brain microvesicle kinetics. However, when core temperature was increased by 2°C with CO2/pH normalized to resting levels, there was a marked cerebral uptake of microvesicles derived from endothelial cells and monocytes. The CO2/pH‐mediated alteration in cerebral microvesicle uptake occurred only in hyperthermia. These new findings suggest that the heat‐induced hyperventilatory response might serve a beneficial role by preventing potentially inflammatory microvesicle uptake in the brain.

Funder

Natural Sciences and Engineering Research Council of Canada

Foundation for the National Institutes of Health

Publisher

Wiley

Subject

Physiology

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