Coincidence detection in the medial superior olive: mechanistic implications of an analysis of input spiking patterns

Coincidence detection by binaural neurons in the medial superior olive underlies sensitivity to interaural time difference (ITD) and interaural correlation (ρ). It is unclear whether this process is akin to a counting of individual coinciding spikes, or rather to a correlation of membrane potential waveforms resulting from converging inputs from each side. We analyzed spike trains of axons of the cat trapezoid body (TB) and auditory nerve (AN) in a binaural coincidence scheme. ITD was studied by delaying “ipsi-” vs. “contralateral” inputs; ρ was studied by using responses to different noises. We varied the number of inputs; the monaural and binaural threshold and the coincidence window duration. We examined physiological plausibility of output “spike trains” by comparing their rate and tuning to ITD and ρ to those of binaural cells. We found that multiple inputs are required to obtain a plausible output spike rate. In contrast to previous suggestions, monaural threshold almost invariably needed to exceed binaural threshold. Elevation of the binaural threshold to values larger than 2 spikes caused a drastic decrease in rate for a short coincidence window. Longer coincidence windows allowed a lower number of inputs and higher binaural thresholds, but decreased the depth of modulation. Compared to AN fibers, TB fibers allowed higher output spike rates for a low number of inputs, but also generated more monaural coincidences. We conclude that, within the parameter space explored, the temporal patterns of monaural fibers require convergence of multiple inputs to achieve physiological binaural spike rates; that monaural coincidences have to be suppressed relative to binaural ones; and that the neuron has to be sensitive to single binaural coincidences of spikes, for a number of excitatory inputs per side of 10 or less. These findings suggest that the fundamental operation in the mammalian binaural circuit is coincidence counting of single binaural input spikes.

[1]  I. C. WHITFIELD,et al.  Mechanisms of Sound Localization , 1971, Nature.

[2]  M. Konishi,et al.  Computation of Interaural Time Difference in the Owl's Coincidence Detector Neurons , 2011, The Journal of Neuroscience.

[3]  Richard M. Stern,et al.  Interaural Correlation as the Basis of a Working Model of Binaural Processing: An Introduction , 2005 .

[4]  M Konishi,et al.  Responses of neurons in the auditory pathway of the barn owl to partially correlated binaural signals. , 1995, Journal of neurophysiology.

[5]  C. Carr,et al.  Organization of the nucleus magnocellularis and the nucleus laminaris in the barn owl: Encoding and measuring interaural time differences , 1993, The Journal of comparative neurology.

[6]  Philip X Joris,et al.  Decorrelation Sensitivity of Auditory Nerve and Anteroventral Cochlear Nucleus Fibers to Broadband and Narrowband Noise , 2006, The Journal of Neuroscience.

[7]  T. Yin,et al.  Effects of interaural time delays of noise stimuli on low-frequency cells in the cat's inferior colliculus. I. Responses to wideband noise. , 1986, Journal of neurophysiology.

[8]  P. Joris Interaural Time Sensitivity Dominated by Cochlea-Induced Envelope Patterns , 2003, The Journal of Neuroscience.

[9]  T. Yin,et al.  Binaural interaction in low-frequency neurons in inferior colliculus of the cat. II. Effects of changing rate and direction of interaural phase. , 1983, Journal of neurophysiology.

[10]  B. Grothe,et al.  Modulation of synaptic input by GABAB receptors improves coincidence detection for computation of sound location , 2012, The Journal of physiology.

[11]  B. Grothe,et al.  Interaural Time Difference Processing in the Mammalian Medial Superior Olive: The Role of Glycinergic Inhibition , 2008, The Journal of Neuroscience.

[12]  M. Semple,et al.  Frequency-dependent interaural delays in the medial superior olive: implications for interaural cochlear delays. , 2011, Journal of neurophysiology.

[13]  Philip H Smith,et al.  Projections of physiologically characterized globular bushy cell axons from the cochlear nucleus of the cat , 1991, The Journal of comparative neurology.

[14]  H Steven Colburn,et al.  Simple models show the general advantages of dendrites in coincidence detection. , 2007, Journal of neurophysiology.

[15]  P. X. Joris,et al.  The volley theory and the spherical cell puzzle , 2008, Neuroscience.

[16]  Marcel van der Heijden,et al.  Factors Controlling the Input–Output Relationship of Spherical Bushy Cells in the Gerbil Cochlear Nucleus , 2011, The Journal of Neuroscience.

[17]  P X Joris,et al.  Enhancement of neural synchronization in the anteroventral cochlear nucleus. II. Responses in the tuning curve tail. , 1994, Journal of neurophysiology.

[18]  J Blauert,et al.  Localization and the law of the first wavefront in the median plane. , 1971, The Journal of the Acoustical Society of America.

[19]  L H Carney,et al.  Effects of interaural time delays of noise stimuli on low-frequency cells in the cat's inferior colliculus. III. Evidence for cross-correlation. , 1987, Journal of neurophysiology.

[20]  Christian Leibold,et al.  Tonotopic organization of the hyperpolarization-activated current (Ih) in the mammalian medial superior olive , 2013, Front. Neural Circuits.

[21]  Jayaganesh Swaminathan,et al.  Across-Fiber Coding of Temporal Fine-Structure: Effects of Noise-Induced Hearing Loss on Auditory-Nerve Responses , 2010 .

[22]  Peter Bremen,et al.  Axonal Recordings from Medial Superior Olive Neurons Obtained from the Lateral Lemniscus of the Chinchilla (Chinchilla laniger) , 2013, The Journal of Neuroscience.

[23]  P. Joris,et al.  Comparison of bandwidths in the inferior colliculus and the auditory nerve. I. Measurement using a spectrally manipulated stimulus. , 2007, Journal of neurophysiology.

[24]  T. Yin,et al.  Interaural time sensitivity in medial superior olive of cat. , 1990, Journal of neurophysiology.

[25]  Masakazu Konishi,et al.  Effects of Interaural Decorrelation on Neural and Behavioral Detection of Spatial Cues , 1998, Neuron.

[26]  Nace L. Golding,et al.  A Mechanistic Understanding of the Role of Feedforward Inhibition in the Mammalian Sound Localization Circuitry , 2013, Neuron.

[27]  Jeannette A. M. Lorteije,et al.  Directional Hearing by Linear Summation of Binaural Inputs at the Medial Superior Olive , 2013, Neuron.

[28]  Ramana Dodla,et al.  Subthreshold outward currents enhance temporal integration in auditory neurons , 2003, Biological Cybernetics.

[29]  M. Sachs,et al.  Encoding of steady-state vowels in the auditory nerve: representation in terms of discharge rate. , 1979, The Journal of the Acoustical Society of America.

[30]  Catherine E. Carr,et al.  Biophysical basis of the sound analog membrane potential that underlies coincidence detection in the barn owl , 2013, Front. Comput. Neurosci..

[31]  L H Carney,et al.  Enhancement of neural synchronization in the anteroventral cochlear nucleus. I. Responses to tones at the characteristic frequency. , 1994, Journal of neurophysiology.

[32]  L A JEFFRESS,et al.  A place theory of sound localization. , 1948, Journal of comparative and physiological psychology.

[33]  B. Grothe,et al.  Mechanisms of sound localization in mammals. , 2010, Physiological reviews.

[34]  B. Grothe,et al.  Precise inhibition is essential for microsecond interaural time difference coding , 2002, Nature.

[35]  N. Cant Projections to the lateral and medial superior olivary nuclei from the spherical and globular bushy cells of the anteroventral cochlear nucleus , 1991 .

[36]  Philip H Smith,et al.  Projections of physiologically characterized spherical bushy cell axons from the cochlear nucleus of the cat: Evidence for delay lines to the medial superior olive , 1993, The Journal of comparative neurology.

[37]  B. Grothe,et al.  Medial Superior Olivary Neurons Receive Surprisingly Few Excitatory and Inhibitory Inputs with Balanced Strength and Short-Term Dynamics , 2010, The Journal of Neuroscience.

[38]  E. Lopez-Poveda,et al.  The neurophysiological bases of auditory perception , 2010 .

[39]  S Kuwada,et al.  Binaural interaction in low-frequency neurons in inferior colliculus of the cat. I. Effects of long interaural delays, intensity, and repetition rate on interaural delay function. , 1983, Journal of neurophysiology.

[40]  Nace L. Golding,et al.  Weak action potential backpropagation is associated with high‐frequency axonal firing capability in principal neurons of the gerbil medial superior olive , 2007, The Journal of physiology.

[41]  H. Steven Colburn,et al.  Point-neuron model for binaural interaction in MSO , 1993, Hearing Research.

[42]  H. S. Colburn,et al.  Models of the Superior Olivary Complex , 2010 .

[43]  R. H. Arnott,et al.  Sensitivity to Interaural Correlation of Single Neurons in the Inferior Colliculusof Guinea Pigs , 2005, Journal of the Association for Research in Otolaryngology.

[44]  J. E. Rose,et al.  Some neural mechanisms in the inferior colliculus of the cat which may be relevant to localization of a sound source. , 1966, Journal of neurophysiology.

[45]  W. Hartmann,et al.  Human interaural time difference thresholds for sine tones: the high-frequency limit. , 2013, The Journal of the Acoustical Society of America.

[46]  Philip X Joris,et al.  Oscillatory Dipoles As a Source of Phase Shifts in Field Potentials in the Mammalian Auditory Brainstem , 2010, The Journal of Neuroscience.

[47]  R. L. Hyson,et al.  Projections from the lateral nucleus of the trapezoid body to the medial superior olivary nucleus in the gerbil , 1992, Hearing Research.

[48]  Philip X Joris,et al.  Binaural and cochlear disparities , 2006, Proceedings of the National Academy of Sciences.

[49]  Philip X Joris,et al.  On the limit of neural phase locking to fine structure in humans. , 2013, Advances in experimental medicine and biology.

[50]  Petr Lánský,et al.  Proposed mechanisms for coincidence detection in the auditory brainstem , 2005, Biological Cybernetics.

[51]  John Rinzel,et al.  Theroleofdendritesinauditory coincidence detection , 1998 .

[52]  H. Ohmori,et al.  Evaluation of the limiting acuity of coincidence detection in nucleus laminaris of the chicken , 2003, The Journal of physiology.

[53]  Petr Marsalek,et al.  Stochastic interpolation model of the medial superior olive neural circuit , 2012, Brain Research.

[54]  D. H. Louage,et al.  Temporal properties of responses to broadband noise in the auditory nerve. , 2004, Journal of neurophysiology.

[55]  J. Goldberg,et al.  Response of binaural neurons of dog superior olivary complex to dichotic tonal stimuli: some physiological mechanisms of sound localization. , 1969, Journal of neurophysiology.

[56]  C. Leibold Influence of inhibitory synaptic kinetics on the interaural time difference sensitivity in a linear model of binaural coincidence detection. , 2010, The Journal of the Acoustical Society of America.

[57]  Marcel van der Heijden,et al.  Correlation Index: A new metric to quantify temporal coding , 2006, Hearing Research.

[58]  Michael G. Heinz Spatiotemporal Encoding of Vowels in Noise Studied with the Responses of Individual Auditory-Nerve Fibers , 2007 .

[59]  H Steven Colburn,et al.  Coincidence model of MSO responses , 1990, Hearing Research.

[60]  Russell R. Pfeiffer,et al.  Classification of response patterns of spike discharges for units in the cochlear nucleus: Tone-burst stimulation , 2004, Experimental Brain Research.

[61]  L. Carney,et al.  A Model for Interaural Time Difference Sensitivity in the Medial Superior Olive: Interaction of Excitatory and Inhibitory Synaptic Inputs, Channel Dynamics, and Cellular Morphology , 2005, The Journal of Neuroscience.

[62]  J. Rinzel,et al.  The role of dendrites in auditory coincidence detection , 1998, Nature.

[63]  D. H. Louage,et al.  Enhanced Temporal Response Properties of Anteroventral Cochlear Nucleus Neurons to Broadband Noise , 2005, The Journal of Neuroscience.

[64]  R. Kempter,et al.  Signal-to-noise ratio in the membrane potential of the owl's auditory coincidence detectors. , 2012, Journal of neurophysiology.

[65]  Zachary M. Smith,et al.  Sensitivity to Interaural Time Differences in the Inferior Colliculus with Bilateral Cochlear Implants , 2007, The Journal of Neuroscience.

[66]  B. Delgutte Representation of speech-like sounds in the discharge patterns of auditory-nerve fibers. , 1979, The Journal of the Acoustical Society of America.

[67]  C Trahiotis,et al.  Masking with interaurally delayed stimuli: the use of "internal" delays in binaural detection. , 1999, The Journal of the Acoustical Society of America.

[68]  R. L. Hyson,et al.  Coincidence detection by binaural neurons in the chick brain stem. , 1993, Journal of neurophysiology.

[69]  Pablo E. Jercog,et al.  Control of submillisecond synaptic timing in binaural coincidence detectors by Kv1 channels , 2010, Nature Neuroscience.

[70]  C. S. Coffey,et al.  Detection of interaural correlation by neurons in the superior olivary complex, inferior colliculus and auditory cortex of the unanesthetized rabbit , 2006, Hearing Research.

[71]  P. Joris,et al.  Temporal damping in response to broadband noise. I. Inferior colliculus. , 2005, Journal of neurophysiology.

[72]  L. A. Jeffress,et al.  Effect of Varying the Interaural Noise Correlation on the Detectability of Tonal Signals , 1963 .

[73]  M. Furst,et al.  Stochastic properties of auditory brainstem coincidence detectors in binaural perception. , 2009, The Journal of the Acoustical Society of America.

[74]  T. Yin,et al.  A matter of time: internal delays in binaural processing , 2007, Trends in Neurosciences.

[75]  Philip X. Joris,et al.  The Interaural Time Difference Pathway: a Comparison of Spectral Bandwidth and Correlation Sensitivity at Three Anatomical Levels , 2013, Journal of the Association for Research in Otolaryngology.

[76]  Jonathan Z. Simon,et al.  Modeling coincidence detection in nucleus laminaris , 2003, Biological Cybernetics.

[77]  Ray Meddis,et al.  Computational models of the auditory system , 2010 .