TY - JOUR T1 - Spatial integration during active tactile sensation drives elementary shape perception JF - bioRxiv DO - 10.1101/2020.03.16.994145 SP - 2020.03.16.994145 AU - Jennifer Brown AU - Ian Antón Oldenburg AU - Gregory I. Telian AU - Sandon Griffin AU - Mieke Voges AU - Vedant Jain AU - Hillel Adesnik Y1 - 2020/01/01 UR - http://biorxiv.org/content/early/2020/03/18/2020.03.16.994145.abstract N2 - Active haptic sensation is critical for object identification and manipulation, such as for tool use in humans, or prey capture in rodents. The neural circuit basis for recognizing objects through active touch alone is poorly understood. To address this gap, we combined optogenetics, two photon imaging, and high-speed behavioral tracking in mice solving a novel surface orientation discrimination task with their whiskers. We found that orientation discrimination required animals to summate input from multiple whiskers specifically along the whisker arc. Many animals discriminated the orientation of the stimulus per se, as their performance was invariant to the specific location of the presented stimulus. Two photon imaging showed that populations of neurons in the barrel cortex encoded each of the discriminated orientations, and this coding depended on integration over the whisker array. Finally, acute optogenetic inactivation of the barrel cortex strongly impaired surface orientation discrimination, and even cell-type specific optogenetic suppression of layer 4 excitatory neurons degraded performance, implying a role for superficial layers in this computation. These data suggest a model in which spatial summation over an active haptic array generates representations of an object’s surface orientations. These computations may facilitate the encoding of complex three-dimensional objects during active exploration. ER -