Dynamic cues for whisker-based object localization: An analytical solution to vibration during active whisker touch

Vaxenburg, Roman; Wyche, Isis; Svoboda, Karel; Efros, Alexander L.; Hires, Samuel Andrew

doi:10.1371/journal.pcbi.1006032

Cited by 10 publications

(40 citation statements)

References 55 publications

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“…In touch, however, only those touched whiskers will vibrate. A number of parameters, including the whisker's intrinsic dynamics, the contact location along the whisker length, stick-slip, friction, and object surface texture, affect its vibration frequencies (Ritt et al, 2008;Wolfe et al, 2008;Boubenec et al, 2012;Quist et al, 2014;Vaxenburg et al, 2018). Additionally, as the whisker increasingly deflects against an object, these touch-induced vibrations will damp out (Boubenec et al, 2012;Quist et al, 2014;Hobbs et al, 2016).…”

Section: Airflow Versus Touch Stimulimentioning

confidence: 99%

Whisker Vibrations and the Activity of Trigeminal Primary Afferents in Response to Airflow

Bush²,

Hartmann

2019

J. Neurosci.

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Rodents are the most commonly studied model system in neuroscience, but surprisingly few studies investigate the natural sensory stimuli that rodent nervous systems evolved to interpret. Even fewer studies examine neural responses to these natural stimuli. Decades of research have investigated the rat vibrissal (whisker) system in the context of direct touch and tactile stimulation, but recent work has shown that rats also use their whiskers to help detect and localize airflow. The present study investigates the neural basis for this ability as dictated by the mechanical response of whiskers to airflow. Mechanical experiments show that a whisker's vibration magnitude depends on airspeed and the intrinsic shape of the whisker. Surprisingly, the direction of the whisker's vibration changes as a function of airflow speed: vibrations transition from parallel to perpendicular with respect to the airflow as airspeed increases. Recordings from primary sensory trigeminal ganglion neurons show that these neurons exhibit responses consistent with those that would be predicted from direct touch. Trigeminal neuron firing rate increases with airspeed, is modulated by the orientation of the whisker relative to the airflow, and is influenced by the whisker's resonant frequencies. We develop a simple model to describe how a population of neurons could leverage mechanical relationships to decode both airspeed and direction. These results open new avenues for studying vibrissotactile regions of the brain in the context of evolutionarily important airflow-sensing behaviors and olfactory search. Although this study used only female rats, all results are expected to generalize to male rats.The rodent vibrissal (whisker) system has been studied for decades in the context of direct tactile sensation, but recent work has indicated that rats also use whiskers to help localize airflow. Neural circuits in somatosensory regions of the rodent brain thus likely evolved in part to process airflow information. This study investigates the whiskers' mechanical response to airflow and the associated neural response. Airspeed affects the magnitude of whisker vibration and the response magnitude of whisker-sensitive primary sensory neurons in the trigeminal ganglion. Surprisingly, the direction of vibration and the associated directionally dependent neural response changes with airspeed. These findings suggest a population code for airflow speed and direction and open new avenues for studying vibrissotactile regions of the brain.

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Section: Airflow Versus Touch Stimulimentioning

confidence: 99%

Whisker Vibrations and the Activity of Trigeminal Primary Afferents in Response to Airflow

Bush²,

Hartmann

2019

J. Neurosci.

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“…Understanding the underlying principles of the rat somatosensory pathway therefore cannot rely on modeling the sensors of an individual rat in detail (65). Although existing single-whisker models may be able to predict the dynamics of individual whiskers more accurately (32,38,51), the present model has been validated to generate reasonable approximations of real whisker dynamics, well within the naturally occurring variability within and across animals. The present model can be viewed as a "prototypical" rat, whose parameters and dynamics fall within the range of biological rats.…”

Section: Discussionmentioning

confidence: 95%

“…Mechanical responses of isolated whiskers have been quantified in various contexts (33,40,43,(47)(48)(49)(50)(51)(52)(53), but models of the vibrissal system have typically been quasi-static, two-dimensional (2D), and limited to a single whisker (32,34,38,42,44,(54)(55)(56)(57)(58)(59)(60). These are significant limitations when studying neural circuitry that has evolved with multiple sensors interacting with a three-dimensional complex world.…”

Section: Discussionmentioning

confidence: 99%

“…Values of Young's modulus have been reported to fall between 1. 3-7.8 GPa (33)(34)(35)(36)(37), while the damping ratio has been estimated between 0.05 and 0.28 (33,34,38).…”

Section: Optimization Of Single-whisker Dynamics In Two Dimensionsmentioning

confidence: 91%

“…The damping ratio calculated from the kinematic behavior of the whisker is smaller than the optimized value for parameter . This difference is likely attributable to the assumption that the damping ratio is uniform along the whisker, as previous studies have suggested that the damping ratio decreases from base to tip (32,33,38). Matching material properties between simulation and experiment does not guarantee that simulated dynamics will accurately match experimental data.…”

Section: Optimization Of Single-whisker Dynamics In Two Dimensionsmentioning

confidence: 91%

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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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The Sensorimotor Basis of Whisker-Guided Anteroposterior Object Localization in Head-Fixed Mice

et al. 2019

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Dynamic cues for whisker-based object localization: An analytical solution to vibration during active whisker touch

Cited by 10 publications

References 55 publications

Whisker Vibrations and the Activity of Trigeminal Primary Afferents in Response to Airflow

Whisker Vibrations and the Activity of Trigeminal Primary Afferents in Response to Airflow

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

The Sensorimotor Basis of Whisker-Guided Anteroposterior Object Localization in Head-Fixed Mice

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