Complementary effects of adaptation and gain control on sound encoding in primary auditory cortex
Abstract
A common model for the function of auditory cortical neurons is the linear-nonlinear spectro-temporal receptive field (LN STRF). However, while the LN model can account for many aspects of auditory coding, it fails to account for long-lasting effects of sensory context on sound-evoked activity. Two models have expanded on the LN STRF to account for these contextual effects, using short-term plasticity (STP) or contrast-dependent gain control (GC). Both models improve performance over the LN model, but they have never been compared directly. Thus, it is unclear whether they account for distinct processes or describe the same phenomenon in different ways. To address this question, we recorded activity of primary auditory cortical neurons in awake ferrets during presentation of natural sound stimuli. We fit models incorporating one nonlinear mechanism (GC or STP) or both (GC+STP) on this single dataset. We compared model performance according to prediction accuracy on a held-out dataset not used for fitting and found that the GC+STP model performed significantly better than either individual model. We also quantified equivalence between the STP and GC models by calculating the partial correlation between their predictions, relative to the LN model. We found only a modest degree of equivalence between them. We observed similar results for a smaller dataset collected in clean and noisy acoustic contexts. Together, the improved performance of the combined model and weak equivalence between STP and GC models suggest that they describe distinct processes. Therefore, models incorporating both mechanisms are necessary to fully describe auditory cortical coding.
About the Presenter
Jacob Pennington
Jacob Pennington earned his Bachelor of Science in Neuroscience at Washington State University Vancouver (WSUV) in 2019. He is now pursuing a doctoral degree in Applied Mathematics at WSUV with a focus on Computational Neuroscience. Jacob is also employed as a research assistant at the Laboratory of Brain, Hearing, and Behavior (within the Oregon Hearing Research Center) with Dr. Stephen David. In the lab, Jacob collaborates with Dr. David and Dr. Alexander Dimitrov (his WSUV faculty advisor) to study neural encoding in auditory cortex using computational models.