Low blood-oxygen levels were found to be the distinguishing factor that affected executive control-related neural activity and cognitive performance when exercise was performed in low-oxygen conditions
Tsukuba, Japan—When physically demanding activities are performed at high altitude or in other low-oxygen environments, excellent coordination, judgment, and decision-making are important. In some cases, such as when mountaineering, these capabilities may be the difference between life and death.
What is executive function and why is it important? Executive functions control and coordinate other brain functions, like memory, emotions, and movement control, to enable more complex behaviors—for example, learning, planning, judgment, and decision-making.
In a study published this month in Scientific Reports, researchers at the University of Tsukuba showed that reductions in neural activity in brain regions responsible for executive control-related cognitive functions and cognitive performance during exercise in low-oxygen conditions could be prevented by maintaining oxygen saturation.
Demonstrating causality—that the decreases in neural activity and performance are caused by low oxygen availability to brain tissue—is not straightforward because of the complexity exhibited by the brain and all its functions. Yet the University of Tsukuba research team have done just that. "We compared the effects of hypoxic conditions in which blood oxygen levels is reduced with those in which blood oxygen levels remains stable during exercise," says senior author Professor Hideaki Soya. "By doing this, we isolated low oxygen saturation as a factor for decreased neural activity and decreased performance."
Neural activity in the prefrontal cortex was measured with functional near-infrared spectroscopy to show change in oxygenated hemoglobin (i.e., oxygen usage from regional blood supply). Cognitive performance was assessed using Stroop interference, which is the difference in completion time (or number of errors) between neutral and incongruent trials. In incongruent trials, the color of the text must be identified when, for example, the word red is written in green. In neutral trials, only the color of a swatch must be identified.
"When blood oxygen levels remained stable during exercise, the Stroop effect was not as pronounced," says senior author Dr. Genta Ochi. "In the brain region of interest—the left dorsolateral prefrontal cortex—there was less of a decrease in activation from the neutral to the incongruent trial."
The study suggests that oxygen supply is important for maintaining cognitive function during exercise in low-oxygen environments. Furthermore, regions of the brain with newer (from an evolutionary point of view), less critical functions may be lower priority than those responsible for functions that keep us alive. Thus, the effects of cognitive fatigue must be taken into account when physical activities that require judgment and critical thinking are performed in low-oxygen environments.
This work was supported in part by the Japan Society for the Promotion of Science Grants JP15J00782 (G.O.), JP16H06405 (H.S.), JP18H04081 (H.S.), JP19K20036 (G.O.), and the Japan Science and Technology Agency Grants JPMJMI19D5 (H.S.).
The article, "Cognitive fatigue due to exercise under normobaric hypoxia is related to hypoxemia during exercise," was published in Scientific Reports at DOI: 10.1038/s41598-022-14146-5
Professor SOYA Hideaki
Advanced Research Initiative for Human High Performance (ARIHHP), Faculty of Health and Sport Sciences, University of Tsukuba
Lecturer OCHI Genta
Faculty of Health Sciences, Department of Health and Sports, Niigata University of Health and Welfare
Cognitive fatigue due to exercise under normobaric hypoxia is related to hypoxemia during exercise
Article Publication Date