Odorant exposure increases olfactory sensitivity: olfactory epithelium is implicated

Odorant exposure increases olfactory sensitivity: olfactory epithelium is implicated

Exposure-induced shifts in sensitivity to odors may involve peripheral and/or central components of the olfactory system. The ability to disconnect the olfactory epithelium from the bulbs provides a unique opportunity to examine how odorant exposure affects each component. In one experiment, odor th...

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Bibliographic Details
Published in:Physiology & behavior Vol. 72; no. 5; pp. 705 - 711
Main Authors: Yee, Karen K, Wysocki, Charles J
Format: Journal Article
Language:English
Published: Cambridge Elsevier Inc 01-04-2001
New York, NY Elsevier
Subjects:
amyl acetate
Androstenone
Animals
Behavior
Biological and medical sciences
Fundamental and applied biological sciences. Psychology
Induced odor sensitivity
Male
Mice
Mice, Inbred CBA
Nerve transection
Odorants
Olfaction
Olfactory Bulb - physiology
Olfactory Mucosa - physiology
Olfactory Nerve - physiology
Olfactory system and olfaction. Gustatory system and gustation
Pentanols - pharmacology
Smell - physiology
Vertebrates: nervous system and sense organs
Behavior
Nerve transection
Androstenone
Induced odor sensitivity
Olfaction
Perception threshold
Rodentia
Central nervous system
Transect method
Olfactory system
Mus domesticus
Vertebrata
Sensitivity
Mammalia
Olfactory pathway
Olfactory nerve
Detection threshold
Perception
Olfactory bulb
Olfactory epithelium
Chemical stimulus
Brain (vertebrata)
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Summary:Exposure-induced shifts in sensitivity to odors may involve peripheral and/or central components of the olfactory system. The ability to disconnect the olfactory epithelium from the bulbs provides a unique opportunity to examine how odorant exposure affects each component. In one experiment, odor thresholds were established for either amyl acetate or androstenone. The mice were then exposed for 10 days to the same test odorant for which a threshold was obtained. After exposure, sensitivity to the odorant increased relative to preexposure levels. The mice then underwent bilateral olfactory nerve transection (BNX). When both groups of mice were tested 45–50 days after recovery from surgery and return of olfactory function, increased sensitivity to the exposed odorant persisted; however, 121–203 days after surgery, sensitivity returned to preexposure levels. Another experiment was similar to the first except that mice were exposed to an odorant, either amyl acetate or androstenone, for 10 days beginning 1 day after BNX or sham surgery. When the mice were tested 45–50 days after surgery, sensitivity to the exposed odorant was increased relative to preexposure levels, whereas sensitivity to the nonexposed odorant remained at preexposure levels. Although further work is needed to determine the precise mechanism(s) underlying shifts in sensitivity to odors, these studies provide additional evidence for peripheral involvement in exposure-induced sensitization to odorants and demonstrate the remarkable capacity of the olfactory system to maintain or even regain sensitivity after injury.
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ISSN:0031-9384
1873-507X
DOI:10.1016/S0031-9384(01)00428-0