The sensorimotor strategies and neuronal representations of tactile shape discrimination in mice

Rodgers, Chris C.; Nogueira, Ramon; Pil, B Christina; Greeman, Esther A.; Fusi, Stefano; Bruno, Randy M.

doi:10.1101/2020.06.16.126631

Cited by 4 publications

(9 citation statements)

References 173 publications

(202 reference statements)

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“…4c). In agreement with [8], we also found a deviation from classic somatotopy: C1 contacts were more strongly represented than C2 contacts in the C2 column, and than C3 contacts in the C3 column ( Supplementary Fig. S7).…”

Section: C3supporting

confidence: 88%

“…At response time shape category could be decoded with a performance of 56.8% ± 1.7% (green) and the animal's choice with a performance of 65.4% ± 2.0% (blue). Both shape and choice could be reliably decoded from neuronal ensembles in which we grouped together the activity from different recording sessions (pseudopopulations) [8]. As expected, populations of barrel cortex neurons encoded information about whisker contacts ( Fig.…”

Section: Nonlinear Mixed Selectivity In the Mouse Barrel Cortexmentioning

confidence: 63%

“…More specifically, this study follows up on a recent study [8] in which mice were trained to perform a whisker-based shape discrimination task while populations of single neurons were recorded in the barrel cortex. On each trial animals were presented with either a concave or a convex shape placed at one of three distances from the animal.…”

Section: Introductionmentioning

confidence: 99%

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The geometry of cortical representations of touch in rodents

Nogueira

Rodgers

Bruno

et al. 2021

Preprint

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Adaptive behavior in humans, rodents, and other animals often requires the integration over time of multiple sensory inputs. Here we studied the behavior and the neural activity of mice trained to actively integrate information from different whiskers to report the curvature of an object. The analysis of high speed videos of the whiskers revealed that the task could be solved by integrating linearly the whisker contacts on the object. However, recordings from the mouse barrel cortex revealed that the neural representations are high dimensional as the inputs from multiple whiskers are mixed non-linearly to produce the observed neural activity. The observed representation enables the animal to perform a broad class of significantly more complex tasks, with minimal disruption of the ability to generalize to novel situations in simpler tasks. Simulated recurrent neural networks trained to perform similar tasks reproduced both the behavioral and neuronal experimental observations. Our work suggests that the somatosensory cortex operates in a regime that represents an efficient compromise between generalization, which typically requires pure and linear mixed selectivity representations, and the ability to perform complex discrimination tasks, which is granted by non-linear mixed representations.

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Section: C3supporting

confidence: 88%

Section: Nonlinear Mixed Selectivity In the Mouse Barrel Cortexmentioning

confidence: 63%

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The geometry of cortical representations of touch in rodents

Nogueira

Rodgers

Bruno

et al. 2021

Preprint

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“…Research into many sensory modalities, especially somatosensation, has probed cortical circuitry and function using detection paradigms, in which animals must report the presence or absence of a stimulus (Brecht et al 1997, Hutson & Masterton 1986. Neurons in S1 have activity that correlates with touch, and manipulating their activity can alter detection behavior (Guo et al 2014b, Miyashita & Feldman 2013, O'Connor et al 2010, Sachidhanandam et al 2013, Yu et al 2016). Yet we recently showed that barrel cortex is, surprisingly, dispensable for both performing and learning a whisker-based go/no-go object detection task (Hong et al 2018).…”

Section: Introductionmentioning

confidence: 99%

Deep and superficial layers of the primary somatosensory cortex are critical for whisker-based texture discrimination in mice

Park

Hong

Rodgers

et al. 2020

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SummaryThe neocortex, comprised of multiple distinct layers, processes sensory input from the periphery, makes decisions, and executes actions. Despite extensive investigation of cortical anatomy and physiology, the contributions of different cortical layers to sensory guided behaviors remain unknown. Here, we developed a two-alternative forced choice (2AFC) paradigm in which head-fixed mice use a single whisker to either discriminate textures of parametrically varied roughness or detect the same textured surfaces. Lesioning the barrel cortex revealed that 2AFC texture discrimination, but not detection, was cortex-dependent. Paralyzing the whisker pad had little effect on performance, demonstrating that passive can rival active perception and cortical dependence is not movement-related. Transgenic Cre lines were used to target inhibitory opsins to excitatory cortical neurons of specific layers for selective perturbations. Both deep and superficial layers were critical for texture discrimination. We conclude that even basic cortical computations require coordinated transformation of sensory information across layers.Abstract Figure

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“…Mice, rats and some other small rodents and insectivores can move their large facial whiskers rhythmically with frequencies of 5–20 Hz, occasionally up to around 30 Hz, a speed that is rather unique in mammals (Berg and Kleinfeld, 2003 ; Knutsen et al, 2006 ; Munz et al, 2010 ; Rahmati et al, 2014 ). In doing so, they can actively explore their environment and establish the shapes and textures of the objects around them (Rodgers et al, 2020 ). Neural interpretation of such active touch is computationally demanding and consequently a large part of the rodent brain is related to the whisker system (Kleinfeld et al, 1999 ; Bosman et al, 2011 ).…”

Section: Introductionmentioning

confidence: 99%

WhiskEras: A New Algorithm for Accurate Whisker Tracking

Betting

Romano

Al-Ars

et al. 2020

Front. Cell. Neurosci.

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Rodents engage in active touch using their facial whiskers: they explore their environment by making rapid back-and-forth movements. The fast nature of whisker movements, during which whiskers often cross each other, makes it notoriously difficult to track individual whiskers of the intact whisker field. We present here a novel algorithm, WhiskEras, for tracking of whisker movements in high-speed videos of untrimmed mice, without requiring labeled data. WhiskEras consists of a pipeline of image-processing steps: first, the points that form the whisker centerlines are detected with sub-pixel accuracy. Then, these points are clustered in order to distinguish individual whiskers. Subsequently, the whiskers are parameterized so that a single whisker can be described by four parameters. The last step consists of tracking individual whiskers over time. We describe that WhiskEras performs better than other whisker-tracking algorithms on several metrics. On our four video segments, WhiskEras detected more whiskers per frame than the Biotact Whisker Tracking Tool. The signal-to-noise ratio of the output of WhiskEras was higher than that of Janelia Whisk. As a result, the correlation between reflexive whisker movements and cerebellar Purkinje cell activity appeared to be stronger than previously found using other tracking algorithms. We conclude that WhiskEras facilitates the study of sensorimotor integration by markedly improving the accuracy of whisker tracking in untrimmed mice.

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The sensorimotor strategies and neuronal representations of tactile shape discrimination in mice

Cited by 4 publications

References 173 publications

The geometry of cortical representations of touch in rodents

The geometry of cortical representations of touch in rodents

Deep and superficial layers of the primary somatosensory cortex are critical for whisker-based texture discrimination in mice

WhiskEras: A New Algorithm for Accurate Whisker Tracking

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