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Sparse Coding in Temporal Association Cortex Improves Complex Sound Discriminability

Libi Feigin, Gen‐ichi Tasaka, Ido Maor, Adi Mizrahi

2021Journal of Neuroscience27 citationsDOIOpen Access PDF

Abstract

The mouse auditory cortex is comprised of several auditory fields spanning the dorsoventral axis of the temporal lobe. The ventral most auditory field is the temporal association cortex (TeA), which remains largely unstudied. Using Neuropixels probes, we simultaneously recorded from primary auditory cortex (AUDp), secondary auditory cortex (AUDv), and TeA, characterizing neuronal responses to pure tones and frequency modulated (FM) sweeps in awake head-restrained female mice. As compared with AUDp and AUDv, single-unit (SU) responses to pure tones in TeA were sparser, delayed, and prolonged. Responses to FMs were also sparser. Population analysis showed that the sparser responses in TeA render it less sensitive to pure tones, yet more sensitive to FMs. When characterizing responses to pure tones under anesthesia, the distinct signature of TeA was changed considerably as compared with that in awake mice, implying that responses in TeA are strongly modulated by non-feedforward connections. Together, these findings provide a basic electrophysiological description of TeA as an integral part of sound processing along the cortical hierarchy. <b>SIGNIFICANCE STATEMENT</b> This is the first comprehensive characterization of the auditory responses in the awake mouse auditory temporal association cortex (TeA). The study provides the foundations for further investigation of TeA and its involvement in auditory learning, plasticity, auditory driven behaviors etc. The study was conducted using state of the art data collection tools, allowing for simultaneous recording from multiple cortical regions and numerous neurons.

Topics & Concepts

Association (psychology)Coding (social sciences)Auditory cortexNeural codingPsychologyNeuroscienceSound (geography)Speech recognitionCognitive psychologyComputer scienceMathematicsAcousticsStatisticsPsychotherapistPhysicsNeural dynamics and brain functionNeuroscience and Music PerceptionOlfactory and Sensory Function Studies
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