Using models to deduce the functioning of the mammalian cochlea

dc.contributorAalto Universityen
dc.contributor.advisorVerhulst, Sarah, Prof., Ghent University, Belgium
dc.contributor.authorAltoè, Alessandro
dc.contributor.departmentSignaalinkäsittelyn ja akustiikan laitosfi
dc.contributor.departmentDepartment of Signal Processing and Acousticsen
dc.contributor.labCommunication Acousticsen
dc.contributor.schoolSähkötekniikan korkeakoulufi
dc.contributor.schoolSchool of Electrical Engineeringen
dc.contributor.supervisorPulkki, Ville, Prof., Aalto University, Department of Signal Processing and Acoustics, Finland
dc.description.abstractThe cochlea "transforms" sound-induced vibrations of the middle ear into patterns of neural pulses travelling to the brain along the fibers of the auditory nerve. This "transformation" happens by means of complex and nonlinear coupled mechanical, electrical and chemical mechanisms. To further complicate matters, the mechanical and electro-chemical properties of the cochlea depend upon delicate active processes, rendering the experimental determination of the physical properties of the intact cochlea extremely difficult. For these reasons,although many response properties of the cochlea are well established, their physical interpretation is less so. Despite the difficulties in modelling the detailed functioning of the cochlea, mathematical models of cochlear processing can guide the interpretation of experimental results. Following this idea, this thesis employs mathematical models to shed light on three aspects of cochlear processing that cannot be observed directly. First, this thesis examines the dynamics of the nonlinearity that causes a compressive growth of basilar membrane vibrations in response to increasing sound levels. In particular, studies showing non-instantaneous distortions in basilar membrane recordings suggested that the underlying nonlinearity operates similarly to an automatic gain control characterised by a finite activation time constant. In contrast, the analysis presented here concluded that (i) a finite activation time of the basilar-membrane nonlinearity produces opposite trends than those observed experimentally and (ii) instantaneous nonlinearities are capable of explaining the data well. Second, the differences between the frequency-tuning of the auditory nerve fibers and that of the inner-hair-cell stereocilia are examined using a model of inner-hair-cell mediated mechanical-to-neural transduction. In this way, it is possible to approximately estimate the frequency-tuning of the inner-hair-cell stereocilia in vivo, that is otherwise not directly measurable. Finally, this thesis examines how the nonlinear activation of K+ currents in the inner-hair-cell basolataral membrane affects the responses of the afferent auditory nerve fibers. The present results suggest that the nonlinearities in the inner-hair-cell basolateral membrane, typically neglected in previous models of mechanical-to-neural transduction, play an important role in determining basic response properties of the auditory nerve. In conclusion, the aforementioned findings are employed to improve existing models of the human cochlea, and results are compared against non-invasive measurements in humans. en
dc.format.extent48 + app. 108
dc.identifier.isbn978-952-60-7959-2 (printed)
dc.identifier.issn1799-4934 (printed)
dc.opnHemmert, Werner, Prof., Technical University of Munich, Germany
dc.publisherAalto Universityen
dc.relation.haspart[Publication 1]: Alessandro Altoè, Ville Pulkki, Sarah Verhulst. Transmission line cochlear models: Improved accuracy and efficiency. The Journal of the Acoustical Society of America, 136 (4) EL302–308, September 2014. DOI: 10.1121/1.4896416
dc.relation.haspart[Publication 2]: Renata Sisto, Arturo Moleti, Alessandro Altoè. Decoupling the level depenence of the basilar membrane gain and phase in nonlinear cochlea models. The Journal of the Acoustical Society of America, 138 (2) EL155–160, August 2015. DOI: 10.1121/1.4928291
dc.relation.haspart[Publication 3]: Alessandro Altoè, Karolina K. Charaziak, Christopher A. Shera. Dynamics of cochlear nonlinearities: Automatic gain control or instantaneous damping? The Journal of the Acoustical Society of America, 142(6) 3510–3519, December 2017. DOI: 10.1121/1.5014039
dc.relation.haspart[Publication 4]: Alessandro Altoè, Ville Pulkki, Sarah Verhulst. Model-based estimation of the frequency tuning of the inner-hair-cell stereocilia from neural tuning curves. The Journal of the Acoustical Society of America, 141(6) 4 4438–4451, June 2017. DOI: 10.1121/1.4985193
dc.relation.haspart[Publication 5]: Alessandro Altoè, Ville Pulkki, Sarah Verhulst. The effect of the inner-hair- cell mediated transduction on the shape of neural tuning curves. In 13th International Workshop on the Mechanics of Hearing, Brock University, Ontario, Canada, June 2017. DOI: 10.1063/1.5038476
dc.relation.haspart[Publication 6]: Alessandro Altoè, Ville Pulkki, Sarah Verhulst. The effects of the activation of the inner-hair-cell basolateral K+ channels on auditory nerve responses. Accepted for publication in Hearing Research, March 2018.
dc.relation.haspart[Publication 7]: Sarah Verhulst, Alessandro Altoè, Viacheslav Vasilkov. Computational modeling of the human auditory periphery: Auditory-nerve, evoked potential and hearing loss simulations. Hearing Research, 360 55–75, March 2018. DOI: 10.1016/j.heares.2017.12.018
dc.relation.ispartofseriesAalto University publication series DOCTORAL DISSERTATIONSen
dc.revNeely, Stephen T., Dr., Boys Town Research Hospital, USA
dc.revLopez-Poveda, Enrique A., Prof., University of Salamanca, Spain
dc.subject.keywordinner hair cellsen
dc.subject.keywordauditory nerveen
dc.titleUsing models to deduce the functioning of the mammalian cochleaen
dc.typeG5 Artikkeliväitöskirjafi
dc.type.ontasotDoctoral dissertation (article-based)en
dc.type.ontasotVäitöskirja (artikkeli)fi
local.aalto.acrisexportstatuschecked 2019-03-06_1457