Kidneys crucial for high-altitude acclimatization, research indicates

A study by a Mount Royal University physiologist and his team demonstrates the key role of the kidneys in acclimatization to high altitude, and illustrates another way that Sherpas are better adapted to high altitude ascent.

Results from the study were recently published in the journal Proceedings of the National Academy of Sciences.

The paper, “Comparing integrative ventilatory and renal acid-base acclimatization in lowlanders and Tibetan highlanders during ascent to 4,300 m,” describes findings from an international high altitude research expedition to the Nepal Himalaya, where the team led by Dr. Trevor Day, Ph.D. studied the blood acid-base acclimatization responses to incremental ascent in lowlanders and Tibetan highlanders (Sherpa).

The team found that Sherpa participants had more rapid and larger magnitude blood acid-base acclimatization than lowlanders with incremental ascent to 4,300 meters. This study highlights the key role of the kidneys in acclimatization to high altitude, and illustrates another way that Sherpa are better adapted to high altitude ascent.

“With so many people now living and traveling to high altitudes, understanding integrated acclimatization and adaptation to high altitude in human populations is of increasing importance, particularly comparing lowlander to highlander populations,” explains Day.

High altitude exposure imposes a blood oxygenation and acid–base challenge, compensated by respiratory and renal acclimatization. The team assessed respiratory and renal acclimatization between unacclimatized age- and sex-matched groups of lowlanders and Tibetan highlanders (Sherpa) during incremental ascent to 4,300 meters in the Nepal Himalaya. Sherpa had a larger magnitude and more rapid time-course of respiratory and renal acclimatization, resulting in fully compensated blood pH at 4,300 meters, whereas lowlanders were still alkalemic.

“This study provides insight into the interplay of ancestry and physiological mechanisms contributing to acclimatization to high altitude, which may indicate selective pressure on ancestral Tibetan highlander populations related to renal function with acclimatization,” says Day.

Insights from the research benefit physiology as a whole, and add new understanding about how different populations acclimatize to high altitude ascent.

The study’s co-first authors were MRU undergraduate trainees Nicole Johnson and Jessica Dickenson, with contributions from two other MRU undergraduate trainees, Benjamin Mackenzie and Rodion Isakovich, and fellow MRU faculty member Dr. Nick Strzalkowski.

Provided by
Mount Royal University

A study by a Mount Royal University physiologist and his team demonstrates the key role of the kidneys in acclimatization to high altitude, and illustrates another way that Sherpas are better adapted to high altitude ascent.

Results from the study were recently published in the journal Proceedings of the National Academy of Sciences.

The paper, “Comparing integrative ventilatory and renal acid-base acclimatization in lowlanders and Tibetan highlanders during ascent to 4,300 m,” describes findings from an international high altitude research expedition to the Nepal Himalaya, where the team led by Dr. Trevor Day, Ph.D. studied the blood acid-base acclimatization responses to incremental ascent in lowlanders and Tibetan highlanders (Sherpa).

The team found that Sherpa participants had more rapid and larger magnitude blood acid-base acclimatization than lowlanders with incremental ascent to 4,300 meters. This study highlights the key role of the kidneys in acclimatization to high altitude, and illustrates another way that Sherpa are better adapted to high altitude ascent.

“With so many people now living and traveling to high altitudes, understanding integrated acclimatization and adaptation to high altitude in human populations is of increasing importance, particularly comparing lowlander to highlander populations,” explains Day.

High altitude exposure imposes a blood oxygenation and acid–base challenge, compensated by respiratory and renal acclimatization. The team assessed respiratory and renal acclimatization between unacclimatized age- and sex-matched groups of lowlanders and Tibetan highlanders (Sherpa) during incremental ascent to 4,300 meters in the Nepal Himalaya. Sherpa had a larger magnitude and more rapid time-course of respiratory and renal acclimatization, resulting in fully compensated blood pH at 4,300 meters, whereas lowlanders were still alkalemic.

“This study provides insight into the interplay of ancestry and physiological mechanisms contributing to acclimatization to high altitude, which may indicate selective pressure on ancestral Tibetan highlander populations related to renal function with acclimatization,” says Day.

Insights from the research benefit physiology as a whole, and add new understanding about how different populations acclimatize to high altitude ascent.

The study’s co-first authors were MRU undergraduate trainees Nicole Johnson and Jessica Dickenson, with contributions from two other MRU undergraduate trainees, Benjamin Mackenzie and Rodion Isakovich, and fellow MRU faculty member Dr. Nick Strzalkowski.

Provided by
Mount Royal University