<p>Pitch perception is fundamental to speech and music, yet the neural representation of pitch in auditory cortex remains poorly understood. We hypothesized that mice rely on temporal cues for pitch perception because of their wide auditory filters and high-frequency hearing. To investigate, we developed a mouse auditory filter bank model that estimates the temporal pitch salience of complex tones. We then trained mice to discriminate low vs. high fundamental frequencies (F0s) in complex tones and found that modeled temporal pitch salience was highly correlated with behavioral discrimination sensitivity. Widefield calcium imaging showed that the organization of periodotopy in auditory cortex predicts how well mice recognize temporal pitch cues. Mice trained on an F0 discrimination task had larger periodotopic maps with greater vector strengths than naïve mice, demonstrating experience-dependent expansion and refinement of temporal pitch maps in auditory cortex. Our findings establish mice as a robust model for studying the neural basis of temporal pitch perception.</p><p></p>

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Cortical representation of pitch perception in mice

  • Jason W. Putnam,
  • Abhay Kumar,
  • Nasiru K. Gill,
  • Jonathan Dinh,
  • Franshesca Orellana Castellanos,
  • Sofia Leusch,
  • Sarah Vaughn,
  • Nikolas A. Francis

摘要

Pitch perception is fundamental to speech and music, yet the neural representation of pitch in auditory cortex remains poorly understood. We hypothesized that mice rely on temporal cues for pitch perception because of their wide auditory filters and high-frequency hearing. To investigate, we developed a mouse auditory filter bank model that estimates the temporal pitch salience of complex tones. We then trained mice to discriminate low vs. high fundamental frequencies (F0s) in complex tones and found that modeled temporal pitch salience was highly correlated with behavioral discrimination sensitivity. Widefield calcium imaging showed that the organization of periodotopy in auditory cortex predicts how well mice recognize temporal pitch cues. Mice trained on an F0 discrimination task had larger periodotopic maps with greater vector strengths than naïve mice, demonstrating experience-dependent expansion and refinement of temporal pitch maps in auditory cortex. Our findings establish mice as a robust model for studying the neural basis of temporal pitch perception.