I research in cochlear physiology and biophysics. Cochlear micromechanics, energy production and propagation in the cochlea which makes the cochlea a perfect frequency analyser with enormous dynamic range are my primary research questions. I am involved in research on interaction between different types of cochlear sensory and supporting cell. Understanding of this interaction is a prerequisite for successful treatment of hearing disorders. I study generation and propagation of optoacoustic emissions. Otoacoustic emissions are widely used in clinics for objective assessment of hearing in patients and knowledge of the mechanisms of emission generation is a matter of great importance. I am interested not only in basic mechanisms of hearing but also in applied research which helps to diagnose and cure hearing disorders. My work on novel mechanisms of cochlear excitation through the round window of the cochlea provides theoretical and practical design principles for the development of new types of hearing aids. I am involved in development of methods for drug delivery into the cochlea.

Physiology and biophysics of the mammalian cochlea with focus on cochlear micromechanics and generation of optoacoustic emissions; Hearing impairment as a consequence of genetic mutation, noise and age-related hearing loss; Development of new types of hearing aid and new ways of drug delivery into the cochlea.