Hypoxia is not the primary mechanism contributing to exercise-induced proteinuria

Carla Rue; John Delamere; Owen D Thomas; Brian Johnson; Kelsley E Joyce; Susie Bradwell; Stephen David Myers; Kimberly Ashdown; Samuel JE Lucas; Amy Fountain; Mark Edsell; Fiona Myers; Will Malein; Chris Imray; Alex Clarke; Chrisopher T Lewis; Charles Newman; Patrick Cadigan; Alexander Wright; Arthur Bradwell

doi:10.1136/bmjsem-2019-000662

BMJ Open Sport & Exercise Medicine (Dec 2020)

Hypoxia is not the primary mechanism contributing to exercise-induced proteinuria

Carla Rue,
John Delamere,
Owen D Thomas,
Brian Johnson,
Kelsley E Joyce,
Susie Bradwell,
Stephen David Myers,
Kimberly Ashdown,
Samuel JE Lucas,
Amy Fountain,
Mark Edsell,
Fiona Myers,
Will Malein,
Chris Imray,
Alex Clarke,
Chrisopher T Lewis,
Charles Newman,
Patrick Cadigan,
Alexander Wright,
Arthur Bradwell

Affiliations

Carla Rue: Occupational Performance Research Group, University of Chichester Department of Sport and Exercise Sciences, Chichester, West Sussex, UK
John Delamere: Birmingham Medical Research Expeditionary Society, University of Birmingham, Birmingham, UK
Owen D Thomas: Birmingham Medical Research Expeditionary Society, University of Birmingham, Birmingham, UK
Brian Johnson: University of Wisconsin-Madison, Madison, WI, USA
Kelsley E Joyce: School of Sport, Exercise, and Rehabilitation Sciences, University of Birmingham, Birmingham, UK
Susie Bradwell: Birmingham Medical Research Expeditionary Society, University of Birmingham, Birmingham, UK
Stephen David Myers: Birmingham Medical Research Expeditionary Society, University of Birmingham, Birmingham, UK
Kimberly Ashdown: Birmingham Medical Research Expeditionary Society, University of Birmingham, Birmingham, UK
Samuel JE Lucas: School of Sport, Exercise, and Rehabilitation Sciences, University of Birmingham, Birmingham, UK
Amy Fountain: Research & Development, Binding Site Group Ltd, Edgbaston, Birmingham, UK
Mark Edsell: Birmingham Medical Research Expeditionary Society, University of Birmingham, Birmingham, UK
Fiona Myers: School of Biological Sciences, University of Portsmouth, Portsmouth, UK
Will Malein: Birmingham Medical Research Expeditionary Society, University of Birmingham, Birmingham, UK
Chris Imray: Birmingham Medical Research Expeditionary Society, University of Birmingham, Birmingham, UK
Alex Clarke: Department of Bioengineering, Imperial College London, London, UK
Chrisopher T Lewis: Birmingham Medical Research Expeditionary Society, University of Birmingham, Birmingham, UK
Charles Newman: Birmingham Medical Research Expeditionary Society, University of Birmingham, Birmingham, UK
Patrick Cadigan: Birmingham Medical Research Expeditionary Society, University of Birmingham, Birmingham, UK
Alexander Wright: Birmingham Medical Research Expeditionary Society, University of Birmingham, Birmingham, UK
Arthur Bradwell: Birmingham Medical Research Expeditionary Society, University of Birmingham, Birmingham, UK

DOI: https://doi.org/10.1136/bmjsem-2019-000662
Journal volume & issue: Vol. 6, no. 1

Abstract

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Introduction Proteinuria increases at altitude and with exercise, potentially as a result of hypoxia. Using urinary alpha-1 acid glycoprotein (α1-AGP) levels as a sensitive marker of proteinuria, we examined the impact of relative hypoxia due to high altitude and blood pressure-lowering medication on post-exercise proteinuria.Methods Twenty individuals were pair-matched for sex, age and ACE genotype. They completed maximal exercise tests once at sea level and twice at altitude (5035 m). Losartan (100 mg/day; angiotensin-receptor blocker) and placebo were randomly assigned within each pair 21 days before ascent. The first altitude exercise test was completed within 24–48 hours of arrival (each pair within ~1 hour). Acetazolamide (125 mg two times per day) was administrated immediately after this test for 48 hours until the second altitude exercise test.Results With placebo, post-exercise α1-AGP levels were similar at sea level and altitude. Odds ratio (OR) for increased resting α1-AGP at altitude versus sea level was greater without losartan (2.16 times greater). At altitude, OR for reduced post-exercise α1-AGP (58% lower) was higher with losartan than placebo (2.25 times greater, p=0.059) despite similar pulse oximetry (SpO2) (p=0.95) between groups. Acetazolamide reduced post-exercise proteinuria by approximately threefold (9.3±9.7 vs 3.6±6.0 μg/min; p=0.025) although changes were not correlated (r=−0.10) with significant improvements in SpO2 (69.1%±4.5% vs 75.8%±3.8%; p=0.001).Discussion Profound systemic hypoxia imposed by altitude does not result in greater post-exercise proteinuria than sea level. Losartan and acetazolamide may attenuate post-exercise proteinuria, however further research is warranted.

Published in BMJ Open Sport & Exercise Medicine

ISSN: 2055-7647 (Online)
Publisher: BMJ Publishing Group
Country of publisher: United Kingdom
LCC subjects: Medicine: Medicine (General)
Website: http://bmjopensem.bmj.com

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