The mechanism of protection by sound conditioning from acoustic trauma.
- Author:
Hong-Yan ZUO
1
;
Ming-Quan WU
;
Bo CUI
;
Xiao-Jun SHE
Author Information
- Publication Type:Journal Article
- MeSH: Acclimatization; Actins; metabolism; Animals; Auditory Threshold; Calcium; metabolism; Calmodulin; metabolism; Cytoskeleton; Disease Models, Animal; Female; Guinea Pigs; HSC70 Heat-Shock Proteins; metabolism; Hair Cells, Auditory; cytology; metabolism; Hearing Loss, Noise-Induced; pathology; Male
- From: Chinese Journal of Applied Physiology 2005;21(4):462-465
- CountryChina
- Language:Chinese
-
Abstract:
AIMTo investigate the mechanism of protection by sound conditioning from acoustic trauma.
METHODSSound conditioning experimental model of animals was established. The expression of CaM, HSP70 and F-actin in hair cells were examined with the method of immunohistochemistry. Free calcium concentration in hair cells was observed by LSCM at the same time. Quantitative investigation was devised to assess the changes of F-actin, CaM, HSP70 and intracellular calcium concentration in hair cells.
RESULTSThe expression of CaM, HSP70 and F-actin all showed an increased trend after noise exposure. HSP70 and F-actin expressed significantly more in group CH than that expressed in group H. Compared with group H, the expression of CaM showed an increased trend in group CH. Elevation of intracellular calcium concentration could be resulted from noise exposure. The calcium concentration in group H was significantly higher than that in group C and group CH.
CONCLUSIONA suitable sound conditioning can make the auditory system of guinea pig more resistant to noise trauma. The strengthened cytoskeleton system and the intracellular calcium homeostasis play a critical role in the protective mechanism of sound conditioning.
