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Symposium Reports |
1 Department of Physiology and The Ear Institute, University College London, Gower Street, London WC1E 6BT, UK
Determining the location of a sound source requires the use of binaural hearing – information about a sound at the two ears converges onto neurones in the auditory brainstem to create a binaural representation. The main binaural cue used by many mammals to locate a sound source is the interaural time difference, or ITD. For over 50 years a single model has dominated thinking on how ITDs are processed. The Jeffress model consists of an array of coincidence detectors – binaural neurones that respond maximally to simultaneous input from each ear – innervated by a series of delay lines – axons of varying length from the two ears. The purpose of this arrangement is to create a topographic map of ITD, and hence spatial position in the horizontal plane, from the relative timing of a sound at the two ears. This model appears to be realized in the brain of the barn owl, an auditory specialist, and has been assumed to hold for mammals also. Recent investigations, however, indicate that both the means by which neural tuning for preferred ITD, and the coding strategy used by mammals to determine the location of a sound source, may be very different to barn owls and to the model proposed by Jeffress.
(Received 12 January 2005;
accepted after revision 4 March 2005;
first published online 10 March 2005)
Corresponding author D. McAlpine: Department of Physiology and The Ear Institute, University College London, Gower Street, London WC1E 6BT, UK. Email: d.mcalpine{at}ucl.ac.uk
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