Your search keyword '"Forli, Angelo"' showing total 5 results

1. Understanding the neural basis of natural intelligence.

Author

Forli, Angelo and Yartsev, Michael M.

Subjects

*REDUCTIONISM, *SPECIES

Abstract

Understanding the neural basis of natural intelligence necessitates a paradigm shift: from strict reductionism toward embracing complexity and diversity. New tools and theories enable us to tackle this challenge, providing unprecedented access to neural dynamics and behavior across time, contexts, and species. Principles for intelligent behavior and learning in the natural world are now, more than ever, within reach. [ABSTRACT FROM AUTHOR]

Published

2024

2. Optogenetic strategies for high-efficiency all-optical interrogation using blue-light-sensitive opsins.

Author

Forli, Angelo, Pisoni, Matteo, Printz, Yoav, Yizhar, Ofer, and Fellin, Tommaso

Subjects

*OPSINS, *LARGE-scale brain networks, *TORTURE, *BRAIN imaging, *MOTOR vehicle driving

Abstract

All-optical methods for imaging and manipulating brain networks with high spatial resolution are fundamental to study how neuronal ensembles drive behavior. Stimulation of neuronal ensembles using two-photon holographic techniques requires high-sensitivity actuators to avoid photodamage and heating. Moreover, two-photon-excitable opsins should be insensitive to light at wavelengths used for imaging. To achieve this goal, we developed a novel soma-targeted variant of the large-conductance blue-light-sensitive opsin CoChR (stCoChR). In the mouse cortex in vivo, we combined holographic two-photon stimulation of stCoChR with an amplified laser tuned at the opsin absorption peak and two-photon imaging of the red-shifted indicator jRCaMP1a. Compared to previously characterized blue-light-sensitive soma-targeted opsins in vivo, stCoChR allowed neuronal stimulation with more than 10-fold lower average power and no spectral crosstalk. The combination of stCoChR, tuned amplified laser stimulation, and red-shifted functional indicators promises to be a powerful tool for large-scale interrogation of neural networks in the intact brain. [ABSTRACT FROM AUTHOR]

Published

2021

3. Enhanced Feedback Inhibition Due to Increased Recruitment of Somatostatin-Expressing Interneurons and Enhanced Cortical Recurrent Excitation in a Genetic Mouse Model of Migraine.

Author

Marchionni, Ivan, Pilati, Nadia, Forli, Angelo, Sessolo, Michele, Tottene, Angelita, and Pietrobon, Daniela

Subjects

*NEURAL transmission, *SPREADING cortical depression, *MIGRAINE aura, *GENETIC models, *LABORATORY mice, *MIGRAINE, *ANIMAL disease models

Abstract

Migraine is a complex brain disorder, characterized by attacks of unilateral headache and global dysfunction in multisensory information processing, whose underlying cellular and circuit mechanisms remain unknown. The finding of enhanced excitatory, but unaltered inhibitory, neurotransmission at cortical synapses between pyramidal cells (PCs) and fast-spiking interneurons (FS INs) in mouse models of familial hemiplegic migraine (FHM) suggested the hypothesis that dysregulation of the excitatory-inhibitory (E/I) balance in specific circuits is a key pathogenic mechanism. Here, we investigated the cortical layer 2/3 (L2/3) feedback inhibition microcircuit involving somatostatin-expressing (SOM) INs in FHM1 mice of both sexes carrying a gain-of-function mutation in CaV2.1. Unitary inhibitory neurotransmission at SOM IN-PC synapses was unaltered while excitatory neurotransmission at both PCSOM IN and PC-PC synapses was enhanced, because of increased probability of glutamate release, in FHM1 mice. Short-term synaptic depression was enhanced at PC-PC synapses while short-term synaptic facilitation was unaltered at PC-SOM IN synapses during 25-Hz repetitive activity. The frequency-dependent disynaptic inhibition (FDDI) mediated by SOM INs was enhanced, lasted longer and required shorter high-frequency bursts to be initiated in FHM1 mice. These findings, together with previous evidence of enhanced disynaptic feedforward inhibition by FS INs, suggest that the increased inhibition may effectively counteract the increased recurrent excitation in FHM1 mice and may even prevail in certain conditions. Considering the involvement of SOM INs in c oscillations, surround suppression and context-dependent sensory perception, the facilitated recruitment of SOM INs, together with the enhanced recurrent excitation, may contribute to dysfunctional sensory processing in FHM1 and possibly migraine. [ABSTRACT FROM AUTHOR]

Published

2022

4. Extended field-of-view ultrathin microendoscopes for high-resolution two-photon imaging with minimal invasiveness.

Author

Antonini, Andrea, Sattin, Andrea, Moroni, Monica, Bovetti, Serena, Moretti, Claudio, Succol, Francesca, Forli, Angelo, Vecchia, Dania, Rajamanickam, Vijayakumar P., Bertoncini, Andrea, Panzeri, Stefano, Liberale, Carlo, and Fellin, Tommaso

Subjects

*OPTICAL aberrations, *THALAMIC nuclei, *SIGNAL-to-noise ratio, *MICROLENSES, *ENDOSCOPES

Abstract

Imaging neuronal activity with high and homogeneous spatial resolution across the field-of-view (FOV) and limited invasiveness in deep brain regions is fundamental for the progress of neuroscience, yet is a major technical challenge. We achieved this goal by correcting optical aberrations in gradient index lens-based ultrathin (≤500 μm) microendoscopes using aspheric microlenses generated through 3D-microprinting. Corrected microendoscopes had extended FOV (eFOV) with homogeneous spatial resolution for two-photon fluorescence imaging and required no modification of the optical set-up. Synthetic calcium imaging data showed that, compared to uncorrected endoscopes, eFOV-microendoscopes led to improved signal-to-noise ratio and more precise evaluation of correlated neuronal activity. We experimentally validated these predictions in awake head-fixed mice. Moreover, using eFOV-microendoscopes we demonstrated cell-specific encoding of behavioral state-dependent information in distributed functional subnetworks in a primary somatosensory thalamic nucleus. eFOV-microendoscopes are, therefore, small-cross-section ready-to-use tools for deep two-photon functional imaging with unprecedentedly high and homogeneous spatial resolution. [ABSTRACT FROM AUTHOR]

Published

2020

5. Temporal Sharpening of Sensory Responses by Layer V in the Mouse Primary Somatosensory Cortex.

Author

Vecchia, Dania, Beltramo, Riccardo, Vallone, Fabio, Chéreau, Ronan, Forli, Angelo, Molano-Mazón, Manuel, Bawa, Tanika, Binini, Noemi, Moretti, Claudio, Holtmaat, Anthony, Panzeri, Stefano, and Fellin, Tommaso

Subjects

*SOMATOSENSORY cortex, *PYRAMIDAL neurons, *NEURAL circuitry, *REACTION time, *MEMBRANE potential, *MICE

Abstract

The timing of stimulus-evoked spikes encodes information about sensory stimuli. Here we studied the neural circuits controlling this process in the mouse primary somatosensory cortex. We found that brief optogenetic activation of layer V pyramidal cells just after whisker deflection modulated the membrane potential of neurons and interrupted their long-latency whisker responses, increasing their accuracy in encoding whisker deflection time. In contrast, optogenetic inhibition of layer V during either passive whisker deflection or active whisking decreased accuracy in encoding stimulus or touch time, respectively. Suppression of layer V pyramidal cells increased reaction times in a texture discrimination task. Moreover, two-color optogenetic experiments revealed that cortical inhibition was efficiently recruited by layer V stimulation and that it mainly involved activation of parvalbumin-positive rather than somatostatin-positive interneurons. Layer V thus performs behaviorally relevant temporal sharpening of sensory responses through circuit-specific recruitment of cortical inhibition. • Layer V pyramidal neurons sharpen the temporal profile of sensory responses in S1 • Layer V pyramidal cells control the precision of encoding of whisker stimulus time • Inhibition of layer V increases behavioral reaction time in a discrimination task • The effect of layer V activation is largely mediated by PV-positive interneurons Using cell-type-specific optogenetic manipulations, Vecchia et al. show that layer V pyramidal cells control the precision of encoding of whisker stimulus time in the primary somatosensory cortex through the activation of a specific inhibitory circuit. Layer V activity impacts behavioral reaction time in a whisker-based texture discrimination task. [ABSTRACT FROM AUTHOR]

Published

2020