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Indoor CO 2 concentrations and cognitive function: A critical review
Author(s) -
Du Bowen,
Tandoc Marlie C.,
Mack Michael L.,
Siegel Jeffrey A.
Publication year - 2020
Publication title -
indoor air
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.387
H-Index - 99
eISSN - 1600-0668
pISSN - 0905-6947
DOI - 10.1111/ina.12706
Subject(s) - cognition , affect (linguistics) , confounding , effects of sleep deprivation on cognitive performance , ventilation (architecture) , consistency (knowledge bases) , pollutant , indoor air quality , environmental science , environmental health , psychology , computer science , medicine , engineering , statistics , environmental engineering , mathematics , ecology , neuroscience , biology , artificial intelligence , communication , mechanical engineering
Poor indoor air quality indicated by elevated indoor CO 2 concentrations has been linked with impaired cognitive function, yet current findings of the cognitive impact of CO 2 are inconsistent. This review summarizes the results from 37 experimental studies that conducted objective cognitive tests with manipulated CO 2 concentrations, either through adding pure CO 2 or adjusting ventilation rates (the latter also affects other indoor pollutants). Studies with varied designs suggested that both approaches can affect multiple cognitive functions. In a subset of studies that meet objective criteria for strength and consistency, pure CO 2 at a concentration common in indoor environments was only found to affect high‐level decision‐making measured by the Strategic Management Simulation battery in non‐specialized populations, while lower ventilation and accumulation of indoor pollutants, including CO 2 , could reduce the speed of various functions but leave accuracy unaffected. Major confounding factors include variations in cognitive assessment methods, study designs, individual and populational differences in subjects, and uncertainties in exposure doses. Accordingly, future research is suggested to adopt direct air delivery for precise control of CO 2 inhalation, include brain imaging techniques to better understand the underlying mechanisms that link CO 2 and cognitive function, and explore the potential interaction between CO 2 and other environmental stimuli.