Spatiotemporal Patterns of Contact Across the Rat Vibrissal Array During Exploratory Behavior

Hobbs, Jennifer; Towal, R. Blythe; Hartmann, Mitra J. Z.

doi:10.3389/fnbeh.2015.00356

Cited by 40 publications

(49 citation statements)

References 79 publications

(159 reference statements)

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“…However, this naturalistic approach prevented us from identifying the precise moments of multi-whisker touch, thereby obscuring the effects of multi-whisker integration on the fine temporal structure of spiking. Future studies, using technological advances that permit the imaging and quantification of multi-whisker contacts during exploration of objects with complex surface geometry (Hobbs et al, 2016), in combination with the physiological approaches here, could address how a spatial map in S1 facilitates the encoding of higher order stimulus features. Furthermore, processing stages downstream of S1 could integrate topographic information of scanned space with sensorimotor signals conveying whisking set point to construct an egocentric map of space.…”

Section: Discussionmentioning

confidence: 99%

Surround Integration Organizes a Spatial Map during Active Sensation

Pluta

Lyall

Telian

et al. 2017

Neuron

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During active sensation, sensors scan space in order to generate a representation of the outside world. However, since spatial coding in sensory systems is typically addressed by measuring receptive fields in a fixed, sensor-based coordinate frame, the cortical representation of scanned space is poorly understood. To address this question, we probed spatial coding in the rodent whisker system using a combination of two photon imaging and electrophysiology during active touch. We found that surround whiskers powerfully transform the cortical representation of scanned space. On the single neuron level, surround input profoundly alters response amplitude and modulates spatial preference in the cortex. On the population level, surround input organizes the spatial preference of neurons into a continuous map of the space swept out by the whiskers. These data demonstrate how spatial summation over a moving sensor array is critical to generating population codes of sensory space.

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Section: Discussionmentioning

confidence: 99%

Surround Integration Organizes a Spatial Map during Active Sensation

Pluta

Lyall

Telian

et al. 2017

Neuron

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“…In contrast, during tactile contact, vibration frequencies will depend in complex ways on intrinsic whisker dynamics, the location (along the whisker length) of whisker-object contact, object surface texture, stick-slip and friction (Ritt et al, 2008;Wolfe et al, 2008). In addition, vibrations will damp as the whisker increasingly presses against the object (Boubenec et al, 2012;Quist et al, 2014;Hobbs et al, 2016). If all whiskers simultaneously deflect past an edge, they will vibrate near resonance, but vibrations will damp and will not be superposed on a quasistatic bend.…”

Section: The Mechanics Of Airflow Versus Touchmentioning

confidence: 99%

“…In contrast, when the whiskers are protracted against an object, they will tend to slip in different directions depending on their kinematic trajectory, their intrinsic curvature, object geometry and friction Hartmann, 2008, 2010;Hobbs et al, 2016;Huet et al, 2015;Huet and Hartmann, 2016).…”

Section: The Mechanics Of Airflow Versus Touchmentioning

confidence: 99%

Mechanical responses of rat vibrissae to airflow

Graff

Hartmann

2016

Journal of Experimental Biology

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The survival of many animals depends in part on their ability to sense the flow of the surrounding fluid medium. To date, however, little is known about how terrestrial mammals sense airflow direction or speed. The present work analyzes the mechanical response of isolated rat macrovibrissae (whiskers) to airflow to assess their viability as flow sensors. Results show that the whisker bends primarily in the direction of airflow and vibrates around a new average position at frequencies related to its resonant modes. The bending direction is not affected by airflow speed or by geometric properties of the whisker. In contrast, the bending magnitude increases strongly with airflow speed and with the ratio of the whisker's arc length to base diameter. To a much smaller degree, the bending magnitude also varies with the orientation of the whisker's intrinsic curvature relative to the direction of airflow. These results are used to predict the mechanical responses of vibrissae to airflow across the entire array, and to show that the rat could actively adjust the airflow data that the vibrissae acquire by changing the orientation of its whiskers. We suggest that, like the whiskers of pinnipeds, the macrovibrissae of terrestrial mammals are multimodal sensors -able to sense both airflow and touch -and that they may play a particularly important role in anemotaxis.

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“…The organized morphology of the rat vibrissal array plays an important role in shaping tactile input (23,24,45,46). WHISKiT incorporates this morphology (51) to permit simulation of the complete mechanosensory input to the system during naturalistic behaviors.…”

Section: Mechanical Signals Across the Full Rat Vibrissal Arraymentioning

confidence: 99%

“…Therefore, tools to simulate somatosensory input are crucial. they will ultimately enable the field to take approaches, such as analysis of natural scene statistics (23)(24)(25)(26), that are well established for vision and audition but have remained largely unexplored for somatosensation. Although some models of sensory input have been developed for the primate hand (27,28), we still lack a model of the complete mechanosensory input to the rodent vibrissal array, the most widely used animal model in somatosensory research.…”

Section: Introductionmentioning

confidence: 99%

WHISKiT Physics: A three-dimensional mechanical model of the rat vibrissal array

Zweifel¹,

Bush²,

Abraham³

et al. 2019

Preprint

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Rodents tactually explore the environment using ~62 whiskers (vibrissae), regularly arranged in arrays on both sides of the face. The rat vibrissal system is one of the most commonly used models to study how the brain encodes and processes somatosensory information. To date, however, researchers have been unable to quantify the mechanosensory input at the base of each whisker, because the field lacks accurate models of three-dimensional whisker dynamics. To close this gap, we developed WHISKiT Physics, a simulation framework that incorporates realistic morphology of the full rat whisker array to predict time-varying mechanical signals for all whiskers. The dynamics of single whiskers were optimized based on experimental data, and then validated against free tip oscillations and the dynamic response to collision. The model is then extrapolated to include all whiskers in the array, taking into account each whisker's individual geometry. Simulations of first mode resonances across the array approximately match previous experimental results and fall well within the range expected from biological variability. Finally, we use WHISKiT Physics to simulate mechanical signals across the array during three distinct behavioral conditions: passive whisker stimulation, active whisking against two pegs, and active whisking in a natural environment. The results demonstrate that the simulation system can be used to predict input signals during a variety of behaviors, something that would be difficult or impossible in the biological animal. In all behavioral conditions, interactions between array morphology and individual whisker geometry shape the tactile input to the whisker system. * , * = argmin ∈[2.0,6.5], ∈[0.15,0.6] ( , ) Across all trials used during optimization, high Pearson correlation coefficients for both whiskers, α (x: 0.92, y: 0.92) and B1 (x: 0.99, y: 0.78), indicate a close match between simulation and experiment for both whiskers.

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Spatiotemporal Patterns of Contact Across the Rat Vibrissal Array During Exploratory Behavior

Cited by 40 publications

References 79 publications

Surround Integration Organizes a Spatial Map during Active Sensation

Surround Integration Organizes a Spatial Map during Active Sensation

Mechanical responses of rat vibrissae to airflow

WHISKiT Physics: A three-dimensional mechanical model of the rat vibrissal array

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