Natalia Grion scite author profile

Rhythms with time scales of multiple cycles per second permeate the mammalian brain, yet neuroscientists are not certain of their functional roles. One leading idea is that coherent oscillation between two brain regions facilitates the exchange of information between them. In rats, the hippocampus and the vibrissal sensorimotor system both are characterized by rhythmic oscillation in the theta range, 5–12 Hz. Previous work has been divided as to whether the two rhythms are independent or coherent. To resolve this question, we acquired three measures from rats—whisker motion, hippocampal local field potential (LFP), and barrel cortex unit firing—during a whisker-mediated texture discrimination task and during control conditions (not engaged in a whisker-mediated memory task). Compared to control conditions, the theta band of hippocampal LFP showed a marked increase in power as the rats approached and then palpated the texture. Phase synchronization between whisking and hippocampal LFP increased by almost 50% during approach and texture palpation. In addition, a greater proportion of barrel cortex neurons showed firing that was phase-locked to hippocampal theta while rats were engaged in the discrimination task. Consistent with a behavioral consequence of phase synchronization, the rats identified the texture more rapidly and with lower error likelihood on trials in which there was an increase in theta-whisking coherence at the moment of texture palpation. These results suggest that coherence between the whisking rhythm, barrel cortex firing, and hippocampal LFP is augmented selectively during epochs in which the rat collects sensory information and that such coherence enhances the efficiency of integration of stimulus information into memory and decision-making centers.

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A passive, camera-based head-tracking system for real-time, three-dimensional estimation of head position and orientation in rodents

Vanzella

Grion

Bertolini

et al. 2019

Journal of Neurophysiology

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Tracking head position and orientation in small mammals is crucial for many applications in the field of behavioral neurophysiology, from the study of spatial navigation to the investigation of active sensing and perceptual representations. Many approaches to head tracking exist, but most of them only estimate the 2D coordinates of the head over the plane where the animal navigates. Full reconstruction of the pose of the head in 3D is much more more challenging and has been achieved only in handful of studies, which employed headsets made of multiple LEDs or inertial units. However, these assemblies are rather bulky and need to be powered to operate, which prevents their application in wireless experiments and in the small enclosures often used in perceptual studies. Here we propose an alternative approach, based on passively imaging a lightweight, compact, 3D structure, painted with a pattern of black dots over a white background. By applying a cascade of feature extraction algorithms that progressively refine the detection of the dots and reconstruct their geometry, we developed a tracking method that is highly precise and accurate, as assessed through a battery of validation measurements. We show that this method can be used to study how a rat samples sensory stimuli during a perceptual discrimination task and how a hippocampal place cell represents head position over extremely small spatial scales. Given its minimal encumbrance and wireless nature, our method could be ideal for high-throughput applications, where tens of animals need to be simultaneously and continuously tracked. NEW & NOTEWORTHY Head tracking is crucial in many behavioral neurophysiology studies. Yet reconstruction of the head’s pose in 3D is challenging and typically requires implanting bulky, electrically powered headsets that prevent wireless experiments and are hard to employ in operant boxes. Here we propose an alternative approach, based on passively imaging a compact, 3D dot pattern that, once implanted over the head of a rodent, allows estimating the pose of its head with high precision and accuracy.

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A passive, camera-based head-tracking system for real-time, 3D estimate of head position and orientation in rodents

Vanzella

Grion

Bertolini

et al. 2019

Preprint

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2Tracking head's position and orientation of small mammals is crucial in many behavioral 3 3 neurophysiology studies. Yet, full reconstruction of the head's pose in 3D is a 3 4 challenging problem that typically requires implanting custom headsets made of multiple 3 5LEDs or inertial units. These assemblies need to be powered in order to operate, thus 3 6preventing wireless experiments, and, while suitable to study navigation in large arenas, 3 7 their application is unpractical in the narrow operant boxes employed in perceptual 3 8 studies. Here we propose an alternative approach, based on passively imaging a 3D-3 9printed structure, painted with a pattern of black dots over a white background. We show 4 0 that this method is highly precise and accurate and we demonstrate that, given its 4 1 minimal weight and encumbrance, it can be used to study how rodents sample sensory 4 2 stimuli during a perceptual discrimination task and how hippocampal place cells 4 3 represent head position over extremely small spatial scales. 4 4 4 5

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Natalia Grion

Coherence between Rat Sensorimotor System and Hippocampus Is Enhanced during Tactile Discrimination

A passive, camera-based head-tracking system for real-time, three-dimensional estimation of head position and orientation in rodents

A passive, camera-based head-tracking system for real-time, 3D estimate of head position and orientation in rodents

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