Research interests

• Much of cochlear physiology and pathophysiology remains poorly understood. For example, how do the 3000 rows of active outer hair cells interact with each other and with other cochlear structures to amplify the waves in the cochlea that allow us to hear? How are the motions of these cochlear structures related to the otoacoustic emissions that we can measure in the ear canal?  What role do the efferent nerves play?  What are the changes brought about by pathology? The long term research goal is to understand human cochlear physiology in both normal and pathological conditions with a view to aiding the development of improved clinical diagnostic techniques and treatments.  One approach to improving our understanding of the electro-mechanical aspect of physiology is to develop realistic models of the cochlea.  These should capture the essential hydrodynamics, structural dynamics, and electrical processes involved in cochlear physiology. The non-linear mechano-electrical and electro-mechanical transduction processes are key aspects of the physiology where our understanding remains at a basic level. The ways in which these models may be useful clinically are: to aid the development of treatments, or prostheses for hearing impairment, to improve our ability to interpret clinical results (such as measurements of otoacoustic emissions or electrophysiology), to aid the development of new clinical tests of cochlear function.

Current research

Modelling cochlear dynamics

The aim of this project theme is to develop and test models that capture the essential mechanics of the cochlea in humans. The models are constructed using estimates of mechanical properties of cochlear components, and formulations of the governing laws of motion. The model predictions are tested against available measurements of mechanical vibrations of cochlear components, and measurements of OAEs.

Signal processing of otoacoustic emissions (OAEs)

What can the features of the OAE signal reveal about the patient's auditory system? What are the optimal evoking stimuli and signal processing strategies for recording OAEs, in order to minimise the problems of stimulus artefacts and noise, and thus, for example, to maximise sensitivity and specificity for screening?

Cochlear modelling of distortion product otoacoustic emissions

Top-down processes and auditory processing

Are some people suffering as a result of increasing mass exposure of the public to ultrasound in air?

Electro-haptic hearing: Using tactile stimulation to improve cochlear implant listening

I graduated from Imperial College London in 1986 with a degree in Mechanical Engineering, after which I spent a year as a visiting research student at the Swiss Federal Institute (ETH) in Zurich studying aerodynamics.  I then worked as an engineer in the Wind Energy Group for several years, where my interest in noise and hearing developed.  I took a year out from industry to study for an MSc in Sound and Vibration at the ISVR in Southampton. After graduating, I returned to industry as a noise control engineer at Rover cars working on the design of the then new Mini.

I became intrigued by the mechanics of hearing and returned to the ISVR to study for a PhD modelling the generation of otoacoustic emissions in the cochlea.  After graduating with a PhD in 2001, I worked as a research scientist at the Institute of Hearing Research at the Royal South Hants Hospital investigating novel techniques for measuring otoacoustic emissions.  In 2004, I joined the ISVR as a lecturer where I have been teaching on the Audiology and Acoustical Engineering programmes ever since.

My early research interests have been in understanding the hearing system, especially cochlear mechanics and the mechanisms for generating otoacoustic emissions.  Following on from this, I am currently developing techniques for measuring hearing function, in particular in hearing high-frequency sound.  I have also investigated human responses to very-high frequency sound and ultrasound.