Julien Fournier scite author profile

A major role of vision is to guide navigation, and navigation is strongly driven by vision. Indeed, the brain's visual and navigational systems are known to interact, and signals related to position in the environment have been suggested to appear as early as in the visual cortex. Here, to establish the nature of these signals, we recorded in the primary visual cortex (V1) and hippocampal area CA1 while mice traversed a corridor in virtual reality. The corridor contained identical visual landmarks in two positions, so that a purely visual neuron would respond similarly at those positions. Most V1 neurons, however, responded solely or more strongly to the landmarks in one position rather than the other. This modulation of visual responses by spatial location was not explained by factors such as running speed. To assess whether the modulation is related to navigational signals and to the animal's subjective estimate of position, we trained the mice to lick for a water reward upon reaching a reward zone in the corridor. Neuronal populations in both CA1 and V1 encoded the animal's position along the corridor, and the errors in their representations were correlated. Moreover, both representations reflected the animal's subjective estimate of position, inferred from the animal's licks, better than its actual position. When animals licked in a given location-whether correctly or incorrectly-neural populations in both V1 and CA1 placed the animal in the reward zone. We conclude that visual responses in V1 are controlled by navigational signals, which are coherent with those encoded in hippocampus and reflect the animal's subjective position. The presence of such navigational signals as early as a primary sensory area suggests that they permeate sensory processing in the cortex.

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In vitro and in vivo measures of evoked excitatory and inhibitory conductance dynamics in sensory cortices

Monier

Fournier

Frégnac

2008

Journal of Neuroscience Methods

139

175

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Attributable mortality of ICU-acquired bloodstream infections: Impact of the source, causative micro-organism, resistance profile and antimicrobial therapy

Adrie¹,

Garrouste-Orgeas²,

Essaied³

et al. 2017

Journal of Infection

102

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High-Resolution Intracellular Recordings Using a Real-Time Computational Model of the Electrode

Brette

Piwkowska

Monier

et al. 2008

Neuron

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Intracellular recordings of neuronal membrane potential are a central tool in neurophysiology. In many situations, especially in vivo, the traditional limitation of such recordings is the high electrode resistance and capacitance, which may cause significant measurement errors during current injection. We introduce a computer-aided technique, Active Electrode Compensation (AEC), based on a digital model of the electrode interfaced in real time with the electrophysiological setup. The characteristics of this model are first estimated using white noise current injection. The electrode and membrane contribution are digitally separated, and the recording is then made by online subtraction of the electrode contribution. Tests performed in vitro and in vivo demonstrate that AEC enables high-frequency recordings in demanding conditions, such as injection of conductance noise in dynamic-clamp mode, not feasible with a single high-resistance electrode until now. AEC should be particularly useful to characterize fast neuronal phenomena intracellularly in vivo.

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Hidden Complexity of Synaptic Receptive Fields in Cat V1

et al. 2014

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Adaptation of the simple or complex nature of V1 receptive fields to visual statistics

et al. 2011

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Mouse Visual Cortex Is Modulated by Distance Traveled and by Theta Oscillations

et al. 2020

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Summary The visual responses of neurons in the primary visual cortex (V1) are influenced by the animal’s position in the environment [ 1 , 2 , 3 , 4 , 5 ]. V1 responses encode positions that co-fluctuate with those encoded by place cells in hippocampal area CA1 [ 2 , 5 ]. This correlation might reflect a common influence of non-visual spatial signals on both areas. Place cells in CA1, indeed, do not rely only on vision; their place preference depends on the physical distance traveled [ 6 , 7 , 8 , 9 , 10 , 11 ] and on the phase of the 6–9 Hz theta oscillation [ 12 , 13 ]. Are V1 responses similarly influenced by these non-visual factors? We recorded V1 and CA1 neurons simultaneously while mice performed a spatial task in a virtual corridor by running on a wheel and licking at a reward location. By changing the gain that couples the wheel movement to the virtual environment, we found that ∼20% of V1 neurons were influenced by the physical distance traveled, as were ∼40% of CA1 place cells. Moreover, the firing rate of ∼24% of V1 neurons was modulated by the phase of theta oscillations recorded in CA1 and the response profiles of ∼7% of V1 neurons shifted spatially across the theta cycle, analogous to the phase precession observed in ∼37% of CA1 place cells. The influence of theta oscillations on V1 responses was more prominent in putative layer 6. These results reveal that, in a familiar environment, sensory processing in V1 is modulated by the key non-visual signals that influence spatial coding in the hippocampus.

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Looking for the roots of cortical sensory computation in three-layered cortices

Fournier

Müller

Laurent

2015

Current Opinion in Neurobiology

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Despite considerable effort over a century and the benefit of remarkable technical advances in the past few decades, we are still far from understanding mammalian cerebral cortex. With its six layers, modular architecture, canonical circuits, innumerable cell types, and computational complexity, isocortex remains a challenging mystery. In this review, we argue that identifying the structural and functional similarities between mammalian piriform cortex and reptilian dorsal cortex could help reveal common organizational and computational principles and by extension, some of the most primordial computations carried out in cortical networks.

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Julien Fournier

Coherent encoding of subjective spatial position in visual cortex and hippocampus

In vitro and in vivo measures of evoked excitatory and inhibitory conductance dynamics in sensory cortices

Attributable mortality of ICU-acquired bloodstream infections: Impact of the source, causative micro-organism, resistance profile and antimicrobial therapy

High-Resolution Intracellular Recordings Using a Real-Time Computational Model of the Electrode

Hidden Complexity of Synaptic Receptive Fields in Cat V1

Adaptation of the simple or complex nature of V1 receptive fields to visual statistics

Mouse Visual Cortex Is Modulated by Distance Traveled and by Theta Oscillations

Looking for the roots of cortical sensory computation in three-layered cortices

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