 Regularizing hyperparameters of interacting neural signals in the mouse cortex reflect states of arousalDmitry R Lyamzin, Andrea Alamia, Mohammad Abdolrahmani, Ryo Aoki and Andrea Benucci PLOS Computational Biology, 2024, vol. 20, issue 10, 1-25 Abstract: In natural behaviors, multiple neural signals simultaneously drive activation across overlapping brain networks. Due to limitations in the amount of data that can be acquired in common experimental designs, the determination of these interactions is commonly inferred via modeling approaches, which reduce overfitting by finding appropriate regularizing hyperparameters. However, it is unclear whether these hyperparameters can also be related to any aspect of the underlying biological phenomena and help interpret them. We applied a state-of-the-art regularization procedure—automatic locality determination—to interacting neural activations in the mouse posterior cortex associated with movements of the body and eyes. As expected, regularization significantly improved the determination and interpretability of the response interactions. However, regularizing hyperparameters also changed considerably, and seemingly unpredictably, from animal to animal. We found that these variations were not random; rather, they correlated with the variability in visually evoked responses and with the variability in the state of arousal of the animals measured by pupillometry—both pieces of information that were not included in the modeling framework. These observations could be generalized to another commonly used—but potentially less informative—regularization method, ridge regression. Our findings demonstrate that optimal model hyperparameters can be discovery tools that are informative of factors not a priori included in the model’s design.Author summary: Statistical and machine learning models are increasingly being utilized to analyze and interpret neural data, often in conjunction with statistical regularization methods to improve the accuracy and robustness of the models. Here, we demonstrate that regularization techniques can be used to gain insights into neurophysiological phenomena which are not pre-specified in the original modeling framework. This was demonstrated by modeling cortical neural activations in the mouse posterior cortex during a visual discrimination task. Application of a state-of-the-art regularization technique, automatic locality determination (ALD), revealed that the optimized hyperparameters varied irregularly among mice. However, when correlating this variability with neural and behavioral data not initially provided to the model, such as visual-evoked responses and pupil dilations, we observed that the variance in hyperparameters was indicative of across-animal differences in average states of arousal. Additionally, we showed that these conclusions were not limited to ALD, but were also applicable to a simpler regularization technique, ridge regression. Our findings suggest that regularization hyperparameters can be utilized as valuable discovery tools and should be employed more frequently for data interpretation alongside model parameters. Date: 2024 Downloads: (external link) Related works: Export reference: BibTeX RIS (EndNote, ProCite, RefMan) HTML/Text Persistent link: https://EconPapers.repec.org/RePEc:plo:pcbi00:1012478 DOI: 10.1371/journal.pcbi.1012478 Access Statistics for this article More articles in PLOS Computational Biology from Public Library of Science |
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