Neural representation in the auditory midbrain of the envelope of vocalizations based on a peripheral ear model

The auditory midbrain implant (AMI) consists of a single shank array (20 sites) for stimulation along the tonotopic axis of the central nucleus of the inferior colliculus (ICC) and has been safely implanted in deaf patients who cannot benefit from a cochlear implant (CI). The AMI improves lip-reading abilities and environmental awareness in the implanted patients. However, the AMI cannot achieve the high levels of speech perception possible with the CI. It appears the AMI can transmit sufficient spectral cues but with limited temporal cues required for speech understanding. Currently, the AMI uses a CI-based strategy, which was originally designed to stimulate each frequency region along the cochlea with amplitude-modulated pulse trains matching the envelope of the bandpass-filtered sound components. However, it is unclear if this type of stimulation with only a single site within each frequency lamina of the ICC can elicit sufficient temporal cues for speech perception. At least speech understanding in quiet is still possible with envelope cues as low as 50 Hz. Therefore, we investigated how ICC neurons follow the bandpass-filtered envelope structure of natural stimuli in ketamine-anesthetized guinea pigs. We identified a subset of ICC neurons that could closely follow the envelope structure (up to ß100 Hz) of a diverse set of species-specific calls, which was revealed by using a peripheral ear model to estimate the true bandpass-filtered envelopes observed by the brain. Although previous studies have suggested a complex neural transformation from the auditory nerve to the ICC, our data suggest that the brain maintains a robust temporal code in a subset of ICC neurons matching the envelope structure of natural stimuli. Clinically, these findings suggest that a CI-based strategy may still be effective for the AMI if the appropriate neurons are entrained to the envelope of the acoustic stimulus and can transmit sufficient temporal cues to higher centers.

[1]  E. Kvašňák,et al.  Response properties of neurons in the central nucleus and external and dorsal cortices of the inferior colliculus in guinea pig , 2000, Experimental Brain Research.

[2]  F. de Ribaupierre,et al.  Changes of single unit activity in the cat's auditory thalamus and cortex associated to different anesthetic conditions , 1994, Neuroscience Research.

[3]  E. Kvašňák,et al.  Comparison of response properties of neurons in the inferior colliculus of guinea pigs under different anesthetics. , 1996, Audiology : official organ of the International Society of Audiology.

[4]  P. Torterolo,et al.  Inferior colliculus unitary activity in wakefulness, sleep and under barbiturates , 2002, Brain Research.

[5]  D. H. Johnson,et al.  The relationship between spike rate and synchrony in responses of auditory-nerve fibers to single tones. , 1980, The Journal of the Acoustical Society of America.

[6]  Sarah M. N. Woolley,et al.  Stimulus-Dependent Auditory Tuning Results in Synchronous Population Coding of Vocalizations in the Songbird Midbrain , 2006, The Journal of Neuroscience.

[7]  Chen Chen,et al.  Precise Feature Based Time Scales and Frequency Decorrelation Lead to a Sparse Auditory Code , 2012, The Journal of Neuroscience.

[8]  E. Lopez-Poveda,et al.  A computational algorithm for computing nonlinear auditory frequency selectivity. , 2001, The Journal of the Acoustical Society of America.

[9]  R. Andersen,et al.  Some features of the spatial organization of the central nucleus of the inferior colliculus of the cat , 1978, The Journal of comparative neurology.

[10]  H. Read,et al.  Multiparametric auditory receptive field organization across five cortical fields in the albino rat. , 2007, Journal of neurophysiology.

[11]  Qian-Jie Fu,et al.  The number of spectral channels required for speech recognition depends on the difficulty of the listening situation. , 2004, Acta oto-laryngologica. Supplementum.

[12]  Hubert H. Lim,et al.  Frequency representation within the human brain: Stability versus plasticity , 2013, Scientific reports.

[13]  A. Palmer,et al.  Processing of Communication Calls in Guinea Pig Auditory Cortex , 2012, PloS one.

[14]  Thomas Lenarz,et al.  Coactivation of different neurons within an isofrequency lamina of the inferior colliculus elicits enhanced auditory cortical activation. , 2012, Journal of neurophysiology.

[15]  S. Shore,et al.  Spatial representation of corticofugal input in the inferior colliculus: a multicontact silicon probe approach , 2003, Experimental Brain Research.

[16]  L. Carney,et al.  A phenomenological model of peripheral and central neural responses to amplitude-modulated tones. , 2004, The Journal of the Acoustical Society of America.

[17]  E. Lopez-Poveda,et al.  A human nonlinear cochlear filterbank. , 2001, The Journal of the Acoustical Society of America.

[18]  Morest Dk,et al.  The neuronal architecture of the human posterior colliculus. A study with the Golgi method. , 1971, Acta oto-laryngologica. Supplementum.

[19]  Adrian Rees,et al.  Laminar organization of frequency‐defined local axons within and between the inferior colliculi of the guinea pig , 1995, The Journal of comparative neurology.

[20]  D. Bendor,et al.  Neural coding of temporal information in auditory thalamus and cortex , 2008, Neuroscience.

[21]  M. Escabí,et al.  Distinct Roles for Onset and Sustained Activity in the Neuronal Code for Temporal Periodicity and Acoustic Envelope Shape , 2008, The Journal of Neuroscience.

[22]  Roy D. Patterson,et al.  A Dynamic Compressive Gammachirp Auditory Filterbank , 2006, IEEE Transactions on Audio, Speech, and Language Processing.

[23]  G. Langner,et al.  Temporal and spatial coding of periodicity information in the inferior colliculus of awake chinchilla (Chinchilla laniger) , 2002, Hearing Research.

[24]  A. Rees,et al.  Regularity of firing of neurons in the inferior colliculus. , 1997, Journal of neurophysiology.

[25]  A. Shneiderman,et al.  Banding of lateral superior olivary nucleus afferents in the inferior colliculus: A possible substrate for sensory integration , 1987, The Journal of comparative neurology.

[26]  Gérard Faucon,et al.  Evaluation of two computational models of amplitude modulation coding in the inferior colliculus , 2006, Hearing Research.

[27]  T. Dau,et al.  A computational model of human auditory signal processing and perception. , 2008, The Journal of the Acoustical Society of America.

[28]  T. Stankowich Behavior , 2009, The Quarterly Review of Biology.

[29]  A. Rees,et al.  Neuronal responses to amplitude-modulated and pure-tone stimuli in the guinea pig inferior colliculus, and their modification by broadband noise. , 1989, The Journal of the Acoustical Society of America.

[30]  Thomas Lenarz,et al.  Auditory Midbrain Implant: A Review , 2009, Trends in amplification.

[31]  M. Semple,et al.  Transformation of Temporal Properties between Auditory Midbrain and Cortex in the Awake Mongolian Gerbil , 2007, The Journal of Neuroscience.

[32]  Hubert H. Lim,et al.  Spatially Distinct Functional Output Regions within the Central Nucleus of the Inferior Colliculus: Implications for an Auditory Midbrain Implant , 2007, The Journal of Neuroscience.

[33]  Laurel H Carney,et al.  A phenomenological model of the synapse between the inner hair cell and auditory nerve: long-term adaptation with power-law dynamics. , 2009, The Journal of the Acoustical Society of America.

[34]  Régine Le Bouquin-Jeannès,et al.  A physiologically based model for temporal envelope encoding in human primary auditory cortex , 2007, Hearing Research.

[35]  W. S. Rhode Observations of the vibration of the basilar membrane in squirrel monkeys using the Mössbauer technique. , 1971, The Journal of the Acoustical Society of America.

[36]  I. Stiebler Tone-threshold mapping in the inferior colliculus of the house mouse , 1986, Neuroscience Letters.

[37]  J. E. Wagner,et al.  The Biology of the Guinea Pig , 1976 .

[38]  Josef Syka,et al.  Responses to species-specific vocalizations in the auditory cortex of awake and anesthetized guinea pigs , 2005, Hearing Research.

[39]  J. Ostwald,et al.  Anesthesia changes frequency tuning of neurons in the rat primary auditory cortex. , 2001, Journal of neurophysiology.

[40]  Nathan C Higgins,et al.  Thalamic label patterns suggest primary and ventral auditory fields are distinct core regions , 2010, The Journal of comparative neurology.

[41]  B. Pfingst,et al.  Spectral and temporal cues for speech recognition: Implications for auditory prostheses , 2008, Hearing Research.

[42]  Günter Ehret,et al.  Mapping responses to frequency sweeps and tones in the inferior colliculus of house mice , 2003, The European journal of neuroscience.

[43]  L. Carney,et al.  A phenomenological model for the responses of auditory-nerve fibers: I. Nonlinear tuning with compression and suppression. , 2001, The Journal of the Acoustical Society of America.

[44]  E F Evans,et al.  The frequency response and other properties of single fibres in the guinea‐pig cochlear nerve , 1972, The Journal of physiology.

[45]  C. Schreiner,et al.  Periodicity coding in the inferior colliculus of the cat. II. Topographical organization. , 1988, Journal of neurophysiology.

[46]  M N Semple,et al.  Representation of sound frequency and laterality by units in central nucleus of cat inferior colliculus. , 1979, Journal of neurophysiology.

[47]  Fan-Gang Zeng,et al.  Spectral and Temporal Cues in Cochlear Implant Speech Perception , 2006, Ear and hearing.

[48]  Josef Syka,et al.  Representation of species-specific vocalizations in the inferior colliculus of the guinea pig. , 2003, Journal of neurophysiology.

[49]  W. Loftus,et al.  Organization of binaural excitatory and inhibitory inputs to the inferior colliculus from the superior olive , 2004, The Journal of comparative neurology.

[50]  Boris Gourévitch,et al.  Neural codes in the thalamocortical auditory system: From artificial stimuli to communication sounds , 2011, Hearing Research.

[51]  Gerald Langner,et al.  Topology of functional parameters in the inferior colliculus of the cat , 1987 .

[52]  Hubert H. Lim,et al.  Effects of Pulse Phase Duration and Location of Stimulation Within the Inferior Colliculus on Auditory Cortical Evoked Potentials in a Guinea Pig Model , 2010, Journal of the Association for Research in Otolaryngology.

[53]  D. Oliver,et al.  Neuronal Responses to Lemniscal Stimulation in Laminar Brain Slices of the Inferior Colliculus , 2006, Journal of the Association for Research in Otolaryngology.

[54]  N. Cant,et al.  Parallel auditory pathways: projection patterns of the different neuronal populations in the dorsal and ventral cochlear nuclei , 2003, Brain Research Bulletin.

[55]  Auditory thalamus responses to guinea-pig vocalizations: A comparison between rat and guinea-pig , 2005, Hearing Research.

[56]  G. K. Yates,et al.  Nonlinear input-output functions derived from the responses of guinea-pig cochlear nerve fibres: Variations with characteristic frequency , 1994, Hearing Research.

[57]  Ian M. Winter,et al.  Basilar membrane nonlinearity determines auditory nerve rate-intensity functions and cochlear dynamic range , 1990, Hearing Research.

[58]  Daniel J Tollin,et al.  Neural correlates of the precedence effect in the inferior colliculus of behaving cats. , 2004, Journal of neurophysiology.

[59]  R. Meddis,et al.  A computer model of amplitude-modulation sensitivity of single units in the inferior colliculus. , 1994, The Journal of the Acoustical Society of America.

[60]  J. A. Pruszynski,et al.  Neural correlates , 2023 .

[61]  Ray Meddis,et al.  A nonlinear filter-bank model of the guinea-pig cochlear nerve: rate responses. , 2003, The Journal of the Acoustical Society of America.

[62]  Hubert H. Lim,et al.  Electrical Stimulation of the Midbrain for Hearing Restoration: Insight into the Functional Organization of the Human Central Auditory System , 2007, The Journal of Neuroscience.

[63]  R. Frisina Subcortical neural coding mechanisms for auditory temporal processing , 2001, Hearing Research.

[64]  C E Schreiner,et al.  Neural processing of amplitude-modulated sounds. , 2004, Physiological reviews.

[65]  Lonneke B. M. Eeuwes,et al.  Efficient Encoding of Vocalizations in the Auditory Midbrain , 2010, The Journal of Neuroscience.

[66]  John C. Middlebrooks,et al.  Topographic Spread of Inferior Colliculus Activation in Response to Acoustic and Intracochlear Electric Stimulation , 2004, Journal of the Association for Research in Otolaryngology.

[67]  Zachary M. Smith,et al.  Chimaeric sounds reveal dichotomies in auditory perception , 2002, Nature.

[68]  David J. Anderson,et al.  Auditory cortical responses to electrical stimulation of the inferior colliculus: implications for an auditory midbrain implant. , 2006, Journal of neurophysiology.

[69]  R V Shannon,et al.  Speech Recognition with Primarily Temporal Cues , 1995, Science.

[70]  Douglas L. Oliver,et al.  Neuronal Organization in the Inferior Colliculus , 2005 .

[71]  M. Semple,et al.  Auditory temporal processing: responses to sinusoidally amplitude-modulated tones in the inferior colliculus. , 2000, Journal of neurophysiology.

[72]  N. Cant,et al.  Organization of the inferior colliculus of the gerbil (Meriones unguiculatus): Differences in distribution of projections from the cochlear nuclei and the superior olivary complex , 2006, The Journal of comparative neurology.

[73]  E. Rouiller,et al.  Functional organization of the ventral division of the medial geniculate body of the cat: Evidence for a rostro-caudal gradient of response properties and cortical projections , 1989, Hearing Research.

[74]  S Kuwada,et al.  Simultaneous anterograde labeling of axonal layers from lateral superior olive and dorsal cochlear nucleus in the inferior colliculus of cat , 1997, The Journal of comparative neurology.

[75]  M Vollmer,et al.  Responses of inferior colliculus neurons to amplitude-modulated intracochlear electrical pulses in deaf cats. , 2000, Journal of neurophysiology.

[76]  N. Cant,et al.  Multiple topographically organized projections connect the central nucleus of the inferior colliculus to the ventral division of the medial geniculate nucleus in the gerbil, Meriones unguiculatus , 2007, The Journal of comparative neurology.

[77]  Boris Gourévitch,et al.  Follow-up of latency and threshold shifts of auditory brainstem responses after single and interrupted acoustic trauma in guinea pig , 2009, Brain Research.

[78]  M. Sachs,et al.  An auditory-periphery model of the effects of acoustic trauma on auditory nerve responses. , 2003, The Journal of the Acoustical Society of America.

[79]  Adrian Rees,et al.  Stimulus properties influencing the responses of inferior colliculus neurons to amplitude-modulated sounds , 1987, Hearing Research.

[80]  Ray Meddis,et al.  The temporal representation of speech in a nonlinear model of the guinea pig cochlea. , 2004, The Journal of the Acoustical Society of America.

[81]  S Kuwada,et al.  Monaural and binaural response properties of neurons in the inferior colliculus of the rabbit: effects of sodium pentobarbital. , 1989, Journal of neurophysiology.

[82]  G. C. Thompson,et al.  HRP study of the organization of auditory afferents ascending to central nucleus of inferior colliculus in cat , 1981, The Journal of comparative neurology.