The following work describes the development and application of a neurological system to
definitively profile the auditory responses of aquatic animals, presented as audiograms
showing hearing threshold verses sound frequency. The accuracy of such information is
essential for the optimisation of bio-technical devices such as the Acoustic Fish Deterrent
(AFD) barrier deployed in the Illinois River to prevent the migration of non-indigenous
Asian carp into Lake Michigan, and in the impact assessment of anthropogenic underwater
sounds on the hearing of cetaceans and other marine animals.
The ensuing Auditory Brainstem Response (ABR) electrophysiological recording
technique developed at the University of Plymouth and described in this thesis is classified
by the UK Home Office as being non-invasive, yielding high quality data from vertebrates
in the absence of anaesthetics or implanted electrodes. The ABR technique was further
refined to allow for the recording of evoked potentials in response to either the sound
pressure or particle motion component of an acoustic signal, from animals stationed both at
and below the water surface and ranging in size from a few millimetres to nearly a meter in
length. The electrophysiological studies have resulted in the publication of three peer
reviewed manuscripts, one of which is the first to define hearing for any animal from the
order Acipenseriform (sturgeons and paddlefish).
In addition to the development of the electrophysiology system and protocols, the inner ear
morphology of the animals tested in this work were studied at the ultrastructural level,
along with detailed descriptions of the afferent nerve pathway from the ear to the brain.
Current literature shows a paucity of information on consistent and meticulous removal of
inner ear parts necessary to identify damage to the ultrastructure that is symptomatic of
hearing loss. In order for the acquisition of concise and reliable data, the dissection and
preparation technique for Scanning Electron Microscopy (SEM) was refined for each
species investigated and has resulted in the publication of a further three peer reviewed
manuscripts on inner ear morphology.
Date of Award | 2005 |
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Original language | English |
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Awarding Institution | |
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Development of a non-invasive electrophysiological system for measuring the auditory capability of marine animals
Lovell, J. M. (Author). 2005
Student thesis: PhD