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Central Chemoreceptors: Locations and Functions

  1. Eugene Nattie,
  2. Aihua Li

Published Online: 1 JAN 2012

DOI: 10.1002/cphy.c100083

Comprehensive Physiology

Comprehensive Physiology

How to Cite

Nattie, E. and Li, A. 2012. Central Chemoreceptors: Locations and Functions. Comprehensive Physiology. 2:221–254.

Author Information

  1. Dartmouth Medical School, Department of Physiology, Lebanon, New Hampshire

Publication History

  1. Published Online: 1 JAN 2012

Abstract

Central chemoreception traditionally refers to a change in ventilation attributable to changes in CO2/H+ detected within the brain. Interest in central chemoreception has grown substantially since the previous Handbook of Physiology published in 1986. Initially, central chemoreception was localized to areas on the ventral medullary surface, a hypothesis complemented by the recent identification of neurons with specific phenotypes near one of these areas as putative chemoreceptor cells. However, there is substantial evidence that many sites participate in central chemoreception some located at a distance from the ventral medulla. Functionally, central chemoreception, via the sensing of brain interstitial fluid H+, serves to detect and integrate information on (i) alveolar ventilation (arterial PCO2), (ii) brain blood flow and metabolism, and (iii) acid-base balance, and, in response, can affect breathing, airway resistance, blood pressure (sympathetic tone), and arousal. In addition, central chemoreception provides a tonic “drive” (source of excitation) at the normal, baseline PCO2 level that maintains a degree of functional connectivity among brainstem respiratory neurons necessary to produce eupneic breathing. Central chemoreception responds to small variations in PCO2 to regulate normal gas exchange and to large changes in PCO2 to minimize acid-base changes. Central chemoreceptor sites vary in function with sex and with development. From an evolutionary perspective, central chemoreception grew out of the demands posed by air versus water breathing, homeothermy, sleep, optimization of the work of breathing with the “ideal” arterial PCO2, and the maintenance of the appropriate pH at 37°C for optimal protein structure and function. © 2012 American Physiological Society. Compr Physiol 2:221-254, 2012.