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In-situ visualization of sound-induced otolith motion using hard X-ray phase contrast imaging.


ABSTRACT: Regarding the basics of ear structure-function relationships in fish, the actual motion of the solid otolith relative to the underlying sensory epithelium has rarely been investigated. Otolith motion has been characterized based on a few experimental studies and on approaches using mathematical modeling, which have yielded partially conflicting results. Those studies either predicted a simple back-and-forth motion of the otolith or a shape-dependent, more complex motion. Our study was designed to develop and test a new set-up to generate experimental data on fish otolith motion in-situ. Investigating the basic parameters of otolith motion requires an approach with high spatial and temporal resolution. We therefore used hard X-ray phase contrast imaging (XPCI). We compared two anatomically well-studied cichlid species, Steatocranus tinanti and Etroplus maculatus, which, among other features, differ in the 3D shape of their otoliths. In a water-filled tank, we presented a pure tone of 200?Hz to 1) isolated otoliths embedded in agarose serving as a simple model or 2) to a fish (otoliths in-situ). Our new set-up successfully visualized the motion of otoliths in-situ and therefore paves the way for future studies evaluating the principles of otolith motion.

SUBMITTER: Schulz-Mirbach T 

PROVIDER: S-EPMC5814409 | biostudies-literature | 2018 Feb

REPOSITORIES: biostudies-literature

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In-situ visualization of sound-induced otolith motion using hard X-ray phase contrast imaging.

Schulz-Mirbach Tanja T   Olbinado Margie M   Rack Alexander A   Mittone Alberto A   Bravin Alberto A   Melzer Roland R RR   Ladich Friedrich F   Heß Martin M  

Scientific reports 20180215 1


Regarding the basics of ear structure-function relationships in fish, the actual motion of the solid otolith relative to the underlying sensory epithelium has rarely been investigated. Otolith motion has been characterized based on a few experimental studies and on approaches using mathematical modeling, which have yielded partially conflicting results. Those studies either predicted a simple back-and-forth motion of the otolith or a shape-dependent, more complex motion. Our study was designed t  ...[more]

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