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3. Motor Cortex

Author

Borra, E., primary, Gerbella, M., additional, Rozzi, S., additional, and Luppino, G., additional

Published
2015
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6. Sistema renale

Author

Bossi, E., Cesca, F., Curia, G, Gerbella, M., Lapi, D., Mapelli, J., Russo, G., Sancini, G. A., Toniolo, L., Valente, P., and Veronesi, C.

Subjects
Socio-culturale
Published
2019

7. Single neurons in the insular cortex of a macaque monkey respond to skin brushing: Preliminary data of the possible representation of pleasant touch

Author

Grandi, L, Gerbella, M, Grandi L. C., Gerbella M., Grandi, L, Gerbella, M, Grandi L. C., and Gerbella M.

Abstract

Pleasant touch may serve as a foundation for affiliative behavior, providing a mechanism for the formation and maintenance of social bonds among conspecifics. In humans, this touch is usually referred to as the caress. Dynamic caressing performed on the hairy skin with a velocity of 1-10 cm/s is perceived as being pleasant and determines positive cardio-physiological effects. Furthermore, imaging human studies show that affiliative touch activates the posterior insular cortex (pIC). Recently, it was demonstrated that pleasant touch in monkeys (i.e., sweeping in a grooming-like manner) is performed with velocities similar to those characteristics of human caress (9.31 cm/s), and causes similarly positive autonomic effects, if performed with velocity of 5 cm/s and 10 cm/s, but not lower or higher. Due to similarities between the human caress and non-human primate sweeping, we investigated for the first time whether single neurons of the perisylvian regions (secondary somatosensory cortex [SII] and pIC) of a rhesus monkey can process sweeping touch differently depending on the stimulus speed. We applied stimulation with two speeds: one that optimally induces positive cardio-physiological effects in the monkey who receives it, and includes the real speed of sweep (5-15 cm/s, sweep fast), and a non-optimal speed (1-5 cm/s, sweep slow). The results show that single neurons of insular cortex differently encode the stimulus speed. In particular, even the majority of recorded somatosensory neurons (82.96%) did not discriminate the two speeds, a small set of neurons (16.59%) were modulated just during the sweep fast. These findings represent the first evidence that single neurons of the non-human primates insular cortex can code affiliative touch, highlighting the similarity between human and non-human primates' social touch systems. This study constitutes an important starting point to carry out deeper investigation on neuronal processing of pleasant sweeping in the central

Published
2016

8. Plasticità cerebrale

Author

Angrilli, A, Basso, G, Berlucchi, G, Bolognini, N, Bonini, L, Coco, M, Ferrari, P, Fogassi, L, Gerbella, M, Maravita, A, Olivieri, M, Papagno, C, Romano, D, Sacchetti, B, Tempia, F, Tirindelli, R, Zoccoli, G, Angrilli, A, Basso, G, Berlucchi, G, Bolognini, N, Bonini, L, Coco, M, Ferrari, P, Fogassi, L, Gerbella, M, Maravita, A, Olivieri, M, Papagno, C, Romano, D, Sacchetti, B, Tempia, F, Tirindelli, R, and Zoccoli, G

Published
2018

21. Anterior Intraparietal Area: A Hub in the Observed Manipulative Action Network

Author

Leonardo Fogassi, Monica Maranesi, Alessandro Livi, Michela Gamberini, Luca Bonini, Carolina Giulia Ferroni, Lauretta Passarelli, Marco Lanzilotto, Guy Orban, Marzio Gerbella, Elena Borra, and Lanzillotto M., Ferroni C., Livi A., Gerbella M., Maranesi M., Borra E., Passarelli L., Gamberini M., Fogassi L., Bonini L., Orban G. A.

Subjects
CORTICAL CONNECTIONS, MACAQUE MONKEY, DIRECTED HAND ACTIONS, Computer science, Cognitive Neuroscience, ACTION ORGANIZATION, Posterior parietal cortex, ARCHITECTONIC SUBDIVISION, action observation, 050105 experimental psychology, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Biological neural network, Contextual information, 0501 psychology and cognitive sciences, POSTERIOR PARIETAL CORTEX, Prefrontal cortex, visuomotor processing, anatomical connectivity, macaque monkey, parietal cortex, Science & Technology, 05 social sciences, Neurosciences, MIRROR NEURONS, VENTRAL PREMOTOR, Action (philosophy), Temporal Regions, action observation, anatomical connectivity, macaque monkey, parietal cortex, visuomotor processing, Action observation, Neurosciences & Neurology, ACTION RECOGNITION, Neuroscience, Life Sciences & Biomedicine, 030217 neurology & neurosurgery, Coding (social sciences), INFERIOR PARIETAL
Abstract

Current knowledge regarding the processing of observed manipulative actions (OMAs) (e.g., grasping, dragging, or dropping) is limited to grasping and underlying neural circuitry remains controversial. Here, we addressed these issues by combining chronic neuronal recordings along the anteroposterior extent of monkeys' anterior intraparietal (AIP) area with tracer injections into the recorded sites. We found robust neural selectivity for 7 distinct OMAs, particularly in the posterior part of AIP (pAIP), where it was associated with motor coding of grip type and own-hand visual feedback. This cluster of functional properties appears to be specifically grounded in stronger direct connections of pAIP with the temporal regions of the ventral visual stream and the prefrontal cortex, as connections with skeletomotor related areas and regions of the dorsal visual stream exhibited opposite or no rostrocaudal gradients. Temporal and prefrontal areas may provide visual and contextual information relevant for manipulative action processing. These results revise existing models of the action observation network, suggesting that pAIP constitutes a parietal hub for routing information about OMA identity to the other nodes of the network. ispartof: CEREBRAL CORTEX vol:29 issue:4 pages:1816-1833 ispartof: location:United States status: published

Published
2019

22. Plasticità cerebrale

Author

Basso, G, Bolognini, N, Angrilli, A, Basso, G, Berlucchi, G, Bolognini, N, Bonini, L, Coco, M, Ferrari, P, Fogassi, L, Gerbella, M, Maravita, A, Olivieri, M, Papagno, C, Romano, D, Sacchetti, B, Tempia, F, Tirindelli, R, and Zoccoli, G

Subjects
neurofisiologia, neuroscienze, basi fisiologiche dell'attività psichica
Published
2018

23. Single neurons in the insular cortex of a macaque monkey respond to skin brushing: preliminary data of the possible representation of pleasant touch

Author

Laura Clara Grandi, Marzio Gerbella, Grandi, L, and Gerbella, M

Subjects
pleasant touch, Cognitive Neuroscience, Central nervous system, Stimulation, single neurons, Stimulus (physiology), Insular cortex, Somatosensory system, Macaque, 050105 experimental psychology, lcsh:RC321-571, 03 medical and health sciences, Behavioral Neuroscience, 0302 clinical medicine, biology.animal, medicine, 0501 psychology and cognitive sciences, Primate, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Original Research, biology, Secondary somatosensory cortex, 05 social sciences, perisylvian region, Grooming, Macaca mulatta, Neuropsychology and Physiological Psychology, medicine.anatomical_structure, insular cortex, Psychology, Neuroscience, 030217 neurology & neurosurgery, psychological phenomena and processes
Abstract

Pleasant touch may serve as a foundation for affiliative behavior, providing a mechanism for the formation and maintenance of social bonds among conspecifics. In humans, this touch is usually referred to as the caress. Dynamic caressing performed on the hairy skin with a velocity of 1–10 cm/sec is perceived as being pleasant and determines positive cardio-physiological effects. Furthermore, imaging human studies show that affiliative touch activates the posterior insular cortex.Recently, it was demonstrated that pleasant touch in monkeys (i.e. sweeping in a grooming-like manner) is performed with velocities similar to those characteristics of human caress (9.31 cm/sec), and causes similarly positive autonomic effects, if performed with velocity of 5 cm/sec and 10 cm/sec, but not lower or higher. Due to similarities between the human caress and non-human primate sweeping, we investigated for the first time whether single neurons of the perisylvian regions (secondary somatosensory cortex and posterior insular cortex) of a rhesus monkey can process sweeping touch differently depending on the stimulus speed. We applied stimulation with two speeds: one that optimally induce positive cardio-physiological effects in the monkey who receives it, and includes the real speed of sweep (5-15 cm/sec, sweep fast), and a non-optimal speed (1-5 cm/sec, sweep slow).The results show that single neurons of insular cortex differently encode the stimulus speed. In particular, even the majority of recorded somatosensory neurons (82%) did not discriminate the two speeds, a small set of neurons (18%) were modulated just during the sweep fast. These findings represent the first evidence that single neurons of the non-human primates insular cortex can code affiliative touch, highlighting the similarity between human and non-human primates’ social touch systems. This study constitutes an important starting point to carry out deeper investigation on neuronal processing of pleasant sweeping in the central nervous system.

Published
2016

24. Neural substrate for the engagement of the ventral visual stream in motor control in the macaque monkey.

Author

Borra E, Gerbella M, Rozzi S, and Luppino G

Subjects
Animals, Male, Temporal Lobe physiology, Macaca mulatta, Brain Mapping, Female, Psychomotor Performance physiology, Motor Activity physiology, Visual Pathways physiology
Abstract

The present study aimed to describe the cortical connectivity of a sector located in the ventral bank of the superior temporal sulcus in the macaque (intermediate area TEa and TEm [TEa/m]), which appears to represent the major source of output of the ventral visual stream outside the temporal lobe. The retrograde tracer wheat germ agglutinin was injected in the intermediate TEa/m in four macaque monkeys. The results showed that 58-78% of labeled cells were located within ventral visual stream areas other than the TE complex. Outside the ventral visual stream, there were connections with the memory-related medial temporal area 36 and the parahippocampal cortex, orbitofrontal areas involved in encoding subjective values of stimuli for action selection, and eye- or hand-movement related parietal (LIP, AIP, and SII), prefrontal (12r, 45A, and 45B) areas, and a hand-related dysgranular insula field. Altogether these data provide a solid substrate for the engagement of the ventral visual stream in large scale cortical networks for skeletomotor or oculomotor control. Accordingly, the role of the ventral visual stream could go beyond pure perceptual processes and could be also finalized to the neural mechanisms underlying the control of voluntary motor behavior., (© The Author(s) 2024. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published
2024
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25. Anatomo-functional basis of emotional and motor resonance elicited by facial expressions.

Author

Del Vecchio M, Avanzini P, Gerbella M, Costa S, Zauli FM, d'Orio P, Focacci E, Sartori I, and Caruana F

Subjects
Humans, Male, Female, Adult, Young Adult, Middle Aged, Brain Mapping methods, Electric Stimulation, Insular Cortex diagnostic imaging, Insular Cortex physiology, Magnetic Resonance Imaging methods, Emotions physiology, Facial Expression
Abstract

Simulation theories predict that the observation of other's expressions modulates neural activity in the same centres controlling their production. This hypothesis has been developed by two models, postulating that the visual input is directly projected either to the motor system for action recognition (motor resonance) or to emotional/interoceptive regions for emotional contagion and social synchronization (emotional resonance). Here we investigated the role of frontal/insular regions in the processing of observed emotional expressions by combining intracranial recording, electrical stimulation and effective connectivity. First, we intracranially recorded from prefrontal, premotor or anterior insular regions of 44 patients during the passive observation of emotional expressions, finding widespread modulations in prefrontal/insular regions (anterior cingulate cortex, anterior insula, orbitofrontal cortex and inferior frontal gyrus) and motor territories (Rolandic operculum and inferior frontal junction). Subsequently, we electrically stimulated the activated sites, finding that (i) in the anterior cingulate cortex and anterior insula, the stimulation elicited emotional/interoceptive responses, as predicted by the 'emotional resonance model'; (ii) in the Rolandic operculum it evoked face/mouth sensorimotor responses, in line with the 'motor resonance' model; and (iii) all other regions were unresponsive or revealed functions unrelated to the processing of facial expressions. Finally, we traced the effective connectivity to sketch a network-level description of these regions, finding that the anterior cingulate cortex and the anterior insula are reciprocally interconnected while the Rolandic operculum is part of the parieto-frontal circuits and poorly connected with the former. These results support the hypothesis that the pathways hypothesized by the 'emotional resonance' and the 'motor resonance' models work in parallel, differing in terms of spatio-temporal fingerprints, reactivity to electrical stimulation and connectivity patterns., (© The Author(s) 2024. Published by Oxford University Press on behalf of the Guarantors of Brain. All rights reserved. For commercial re-use, please contact reprints@oup.com for reprints and translation rights for reprints. All other permissions can be obtained through our RightsLink service via the Permissions link on the article page on our site—for further information please contact journals.permissions@oup.com.)

Published
2024
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26. Ventrolateral prefrontal neurons of the monkey encode instructions in the 'pragmatic' format of the associated behavioral outcomes.

Author

Rozzi S, Gravante A, Basile C, Cappellaro G, Gerbella M, and Fogassi L

Subjects
Animals, Macaca mulatta physiology, Prefrontal Cortex physiology, Neurons physiology
Abstract

The prefrontal cortex plays an important role in coding rules and producing context-appropriate behaviors. These processes necessarily require the generation of goals based on current context. Indeed, instructing stimuli are prospectively encoded in prefrontal cortex in relation to behavioral demands, but the coding format of this neural representation is, to date, largely unknown. In order to study how instructions and behaviors are encoded in prefrontal cortex, we recorded the activity of monkeys (Macaca mulatta) ventrolateral prefrontal neurons in a task requiring to perform (Action condition) or withhold (Inaction condition) grasping actions on real objects. Our data show that there are neurons responding in different task phases, and that the neuronal population discharge is stronger in the Inaction condition when the instructing cue is presented, and in the Action condition in the subsequent phases, from object presentation to action execution. Decoding analyses performed on neuronal populations showed that the neural activity recorded during the initial phases of the task shares the same type of format with that recorded during the final phases. We propose that this format has a pragmatic nature, that is instructions and goals are encoded by prefrontal neurons as predictions of the behavioral outcome., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published
2023
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27. Activation of Cerebellum, Basal Ganglia and Thalamus During Observation and Execution of Mouth, hand, and foot Actions.

Author

Errante A, Gerbella M, Mingolla GP, and Fogassi L

Subjects
Humans, Basal Ganglia diagnostic imaging, Basal Ganglia physiology, Mouth diagnostic imaging, Thalamus diagnostic imaging, Thalamus physiology, Hand physiology, Cerebellum diagnostic imaging, Cerebellum physiology
Abstract

Humans and monkey studies showed that specific sectors of cerebellum and basal ganglia activate not only during execution but also during observation of hand actions. However, it is unknown whether, and how, these structures are engaged during the observation of actions performed by effectors different from the hand. To address this issue, in the present fMRI study, healthy human participants were required to execute or to observe grasping acts performed with different effectors, namely mouth, hand, and foot. As control, participants executed and observed simple movements performed with the same effectors. The results show that: (1) execution of goal-directed actions elicited somatotopically organized activations not only in the cerebral cortex but also in the cerebellum, basal ganglia, and thalamus; (2) action observation evoked cortical, cerebellar and subcortical activations, lacking a clear somatotopic organization; (3) in the territories displaying shared activations between execution and observation, a rough somatotopy could be revealed in both cortical, cerebellar and subcortical structures. The present study confirms previous findings that action observation, beyond the cerebral cortex, also activates specific sectors of cerebellum and subcortical structures and it shows, for the first time, that these latter are engaged not only during hand actions observation but also during the observation of mouth and foot actions. We suggest that each of the activated structures processes specific aspects of the observed action, such as performing internal simulation (cerebellum) or recruiting/inhibiting the overt execution of the observed action (basal ganglia and sensory-motor thalamus)., (© 2023. The Author(s).)

Published
2023
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28. Investigating form and content of emotional and non-emotional laughing.

Author

Lombardi G, Gerbella M, Marchi M, Sciutti A, Rizzolatti G, and Di Cesare G

Subjects
Humans, Amygdala physiology, Magnetic Resonance Imaging methods, Brain Mapping methods, Emotions physiology, Laughter physiology
Abstract

As cold actions (i.e. actions devoid of an emotional content), also emotions are expressed with different vitality forms. For example, when an individual experiences a positive emotion, such as laughing as expression of happiness, this emotion can be conveyed to others by different intensities of face expressions and body postures. In the present study, we investigated whether the observation of emotions, expressed with different vitality forms, activates the same neural structures as those involved in cold action vitality forms processing. To this purpose, we carried out a functional magnetic resonance imaging study in which participants were tested in 2 conditions: emotional and non-emotional laughing both conveying different vitality forms. There are 3 main results. First, the observation of emotional and non-emotional laughing conveying different vitality forms activates the insula. Second, the observation of emotional laughing activates a series of subcortical structures known to be related to emotions. Furthermore, a region of interest analysis carried out in these structures reveals a significant modulation of the blood-oxygen-leveldependent (BOLD) signal during the processing of different vitality forms exclusively in the right amygdala, right anterior thalamus/hypothalamus, and periaqueductal gray. Third, in a subsequent electromyography study, we found a correlation between the zygomatic muscles activity and BOLD signal in the right amygdala only., (© The Author(s) 2022. Published by Oxford University Press.)

Published
2023
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29. Specific tractography differences in autism compared to developmental coordination disorder.

Author

Kilroy E, Gerbella M, Cao L, Molfese P, Butera C, Harrison L, Jayashankar A, Rizzolatti G, and Aziz-Zadeh L

Subjects
Adolescent, Child, Humans, Diffusion Tensor Imaging, Autism Spectrum Disorder diagnostic imaging, Autistic Disorder diagnostic imaging, Motor Skills Disorders diagnostic imaging, White Matter diagnostic imaging
Abstract

About 85% of children with autism spectrum disorder (ASD) experience comorbid motor impairments, making it unclear whether white matter abnormalities previously found in ASD are related to social communication deficits, the hallmark of ASD, or instead related to comorbid motor impairment. Here we aim to understand specific white matter signatures of ASD beyond those related to comorbid motor impairment by comparing youth (aged 8-18) with ASD (n = 22), developmental coordination disorder (DCD; n = 16), and typically developing youth (TD; n = 22). Diffusion weighted imaging was collected and quantitative anisotropy, radial diffusivity, mean diffusivity, and axial diffusivity were compared between the three groups and correlated with social and motor measures. Compared to DCD and TD groups, diffusivity differences were found in the ASD group in the mid-cingulum longitudinal and u-fibers, the corpus callosum forceps minor/anterior commissure, and the left middle cerebellar peduncle. Compared to the TD group, the ASD group had diffusivity differences in the right inferior frontal occipital/extreme capsule and genu of the corpus callosum. These diffusion differences correlated with emotional deficits and/or autism severity. By contrast, children with DCD showed unique abnormality in the left cortico-spinal and cortico-pontine tracts.Trial Registration All data are available on the National Institute of Mental Health Data Archive: https://nda.nih.gov/edit_collection.html?id=2254 ., (© 2022. The Author(s).)

Published
2022
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30. Laminar Origin of Corticostriatal Projections to the Motor Putamen in the Macaque Brain.

Author

Borra E, Rizzo M, Gerbella M, Rozzi S, and Luppino G

Subjects
Animals, Brain Mapping, Cerebral Cortex cytology, Corpus Striatum cytology, Feedback, Physiological physiology, Female, Frontal Lobe physiology, Macaca mulatta, Male, Motor Cortex physiology, Neural Pathways cytology, Neurons physiology, Parietal Lobe physiology, Putamen cytology, Cerebral Cortex physiology, Corpus Striatum physiology, Neural Pathways physiology, Putamen physiology
Abstract

In the macaque brain, projections from distant, interconnected cortical areas converge in specific zones of the striatum. For example, specific zones of the motor putamen are targets of projections from frontal motor, inferior parietal, and ventrolateral prefrontal hand-related areas and thus are integral part of the so-called "lateral grasping network." In the present study, we analyzed the laminar distribution of corticostriatal neurons projecting to different parts of the motor putamen. Retrograde neural tracers were injected in different parts of the putamen in 3 Macaca mulatta (one male) and the laminar distribution of the labeled corticostriatal neurons was analyzed quantitatively. In frontal motor areas and frontal operculum, where most labeled cells were located, almost everywhere the proportion of corticostriatal labeled neurons in layers III and/or VI was comparable or even stronger than in layer V. Furthermore, within these regions, the laminar distribution pattern of corticostriatal labeled neurons largely varied independently from their density and from the projecting area/sector, but likely according to the target striatal zone. Accordingly, the present data show that cortical areas may project in different ways to different striatal zones, which can be targets of specific combinations of signals originating from the various cortical layers of the areas of a given network. These observations extend current models of corticostriatal interactions, suggesting more complex modes of information processing in the basal ganglia for different motor and nonmotor functions and opening new questions on the architecture of the corticostriatal circuitry. SIGNIFICANCE STATEMENT Projections from the ipsilateral cerebral cortex are the major source of input to the striatum. Previous studies have provided evidence for distinct zones of the putamen specified by converging projections from specific sets of interconnected cortical areas. The present study shows that the distribution of corticostriatal neurons in the various layers of the primary motor and premotor areas varies depending on the target striatal zone. Accordingly, different striatal zones collect specific combinations of signals from the various cortical layers of their input areas, possibly differing in terms of coding, timing, and direction of information flow (e.g., feed-forward, or feed-back)., (Copyright © 2021 the authors.)

Published
2021
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31. Projections to the putamen from neurons located in the white matter and the claustrum in the macaque.

Author

Borra E, Luppino G, Gerbella M, Rozzi S, and Rockland KS

Subjects
Animals, Claustrum chemistry, Female, Macaca, Macaca mulatta, Male, Nerve Net chemistry, Neural Pathways chemistry, Neural Pathways physiology, Neurons chemistry, Putamen chemistry, White Matter chemistry, Claustrum physiology, Nerve Net physiology, Neurons physiology, Putamen physiology, White Matter physiology
Abstract

Continuing investigations of corticostriatal connections in rodents emphasize an intricate architecture where striatal projections originate from different combinations of cortical layers, include an inhibitory component, and form terminal arborizations which are cell-type dependent, extensive, or compact. Here, we report that in macaque monkeys, deep and superficial cortical white matter neurons (WMNs), peri-claustral WMNs, and the claustrum proper project to the putamen. WMNs retrogradely labeled by injections in the putamen (four injections in three macaques) were widely distributed, up to 10 mm antero-posterior from the injection site, mainly dorsal to the putamen in the external capsule, and below the premotor cortex. Striatally projecting labeled WMNs (WMNsST) were heterogeneous in size and shape, including a small GABAergic component. We compared the number of WMNsST with labeled claustral and cortical neurons and also estimated their proportion in relation to total WMNs. Since some WMNsST were located adjoining the claustrum, we wanted to compare results for density and distribution of striatally projecting claustral neurons (ClaST). ClaST neurons were morphologically heterogeneous and mainly located in the dorsal and anterior claustrum, in regions known to project to frontal, motor, and cingulate cortical areas. The ratio of ClaST to WMNsST was about 4:1 averaged across the four injections. These results provide new specifics on the connectional networks of WMNs in nonhuman primates, and delineate additional loops in the corticostriatal architecture, consisting of interconnections across cortex, claustralstriatal and striatally projecting WMNs., (© 2019 Wiley Periodicals, Inc.)

Published
2020
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33. Connectional gradients underlie functional transitions in monkey pre-supplementary motor area.

Author

Albertini D, Gerbella M, Lanzilotto M, Livi A, Maranesi M, Ferroni CG, and Bonini L

Subjects
Animals, Behavior, Animal physiology, Electrocorticography, Macaca mulatta, Macaca nemestrina, Male, Mirror Neurons physiology, Neuroanatomical Tract-Tracing Techniques, Personal Space, Connectome, Corpus Striatum physiology, Gyrus Cinguli physiology, Motor Activity physiology, Motor Cortex physiology, Nerve Net physiology, Prefrontal Cortex physiology, Visual Perception physiology
Abstract

The pre-supplementary motor area F6 is involved in a variety of functions in multiple domains, from planning/withholding goal-directed actions in space to rule-based cognitive processes and social interactions. Yet, the neural machinery underlying this functional heterogeneity remains unclear. Here, we measured local population dynamics in different rostro-caudal sites of cytoarchitectonically verified area F6 in two monkeys during spatial, contextual and motor processes, both in individual and social conditions. Then, we correlated multimodal population tuning with local anatomical connectivity revealed by neural tracer injections into the functionally characterized sites. We found stronger tuning for object position relative to the monkey in the rostral portion of area F6 than in its caudal part, which in turn exhibits stronger tuning to self and other's (observed) action. Functional specificities were associated with a rostro-caudal transition in connectivity strength from lateral prefrontal cortex, pregenual anterior cingulate cortex and associative striatum (rostrally), to dorso-ventral premotor areas and the motor putamen (caudally). These findings suggest that the functional heterogeneity of the pre-supplementary area F6 is accounted for by gradual transitions in functional properties grounded on local cortico-cortical and cortico-striatal connectional specificities., (Copyright © 2019 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published
2020
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34. The neural bases of vitality forms.

Author

Di Cesare G, Gerbella M, and Rizzolatti G

Abstract

Unlike emotions, which are short-lasting events accompanied by viscero-motor responses, vitality forms are continuous internal states that modulate the motor behaviors of individuals and are devoid of the autonomic modifications that characterize real emotions. Despite the importance of vitality forms in social life, only recently have neurophysiological studies been devoted to this issue. The first part of this review describes fMRI experiments, showing that the dorso-central insula is activated during the execution, the perception and the imagination of arm actions endowed with different vitality forms as well as during the hearing and the production of speech conveying vitality forms. In the second part, we address the means by which the dorso-central insula modulates the networks for controlling action execution and how the sensory and interoceptive information is conveyed to this insular sector. Finally, we present behavioral data showing the importance of vitality forms in social interactions., (© The Author(s) 2019. Published by Oxford University Press on behalf of China Science Publishing & Media Ltd.)

Published
2020
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35. Insula Connections With the Parieto-Frontal Circuit for Generating Arm Actions in Humans and Macaque Monkeys.

Author

Di Cesare G, Pinardi C, Carapelli C, Caruana F, Marchi M, Gerbella M, and Rizzolatti G

Subjects
Animals, Cerebral Cortex physiology, Diffusion Magnetic Resonance Imaging, Female, Frontal Lobe physiology, Humans, Macaca mulatta, Male, Neural Pathways anatomy & histology, Neural Pathways physiology, Parietal Lobe physiology, Species Specificity, White Matter anatomy & histology, White Matter physiology, Arm physiology, Cerebral Cortex anatomy & histology, Frontal Lobe anatomy & histology, Motor Activity, Parietal Lobe anatomy & histology
Abstract

It has been recently found that the human dorso-central insular cortex contributes to the execution and recognition of the affective component of hand actions, most likely through modulation of the activity of the parieto-frontal circuits. While the anatomical connections between the hand representation of the insula and, the parietal and frontal regions controlling reaching/grasping actions is well assessed in the monkey, it is unknown the existence of a homolog circuit in humans. In the present study, we performed a multifiber tractography investigation to trace the tracts possibly connecting the insula to the parieto-frontal circuits by locating seeds in the parietal, premotor, and prefrontal nodes of the reaching/grasping network, in both humans and monkeys. Results showed that, in both species, the insula is connected with the cortical action execution/recognition circuit by similar white matter tracts, running in parallel to the third branch of the superior longitudinal fasciculus and the anterior segment of the arcuate fasciculus., (© The Author(s) 2018. Published by Oxford University Press. All rights reserved. For Permissions, please e-mail: journals.permissions@oup.com.)

Published
2019
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36. Pathways for smiling, disgust and fear recognition in blindsight patients.

Author

Gerbella M, Caruana F, and Rizzolatti G

Subjects
Animals, Facial Expression, Humans, Laughter, Blindness physiopathology, Blindness psychology, Disgust, Emotions, Fear, Recognition, Psychology, Smiling, Visual Pathways physiopathology
Abstract

The aim of the present review is to discuss the localization of circuits that allow recognition of emotional facial expressions in blindsight patients. Because recognition of facial expressions is function of different centers, and their localization is not always clear, we decided to discuss here three emotional facial expression - smiling, disgust, and fear - whose anatomical localization in the pregenual sector of the anterior cingulate cortex (pACC), anterior insula (AI), and amygdala, respectively, is well established. We examined, then, the possible pathways that may convey affective visual information to these centers following lesions of V1. We concluded that the pathway leading to pACC, AI, and amygdala involves the deep layers of the superior colliculus, the medial pulvinar, and the superior temporal sulcus region. We suggest that this visual pathway provides an image of the observed affective faces, which, although deteriorated, is sufficient to determine some overt behavior, but not to provide conscious experience of the presented stimuli., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published
2019
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37. Anterior Intraparietal Area: A Hub in the Observed Manipulative Action Network.

Author

Lanzilotto M, Ferroni CG, Livi A, Gerbella M, Maranesi M, Borra E, Passarelli L, Gamberini M, Fogassi L, Bonini L, and Orban GA

Subjects
Action Potentials, Animals, Female, Hand, Macaca mulatta, Male, Neural Pathways physiology, Neurons cytology, Parietal Lobe anatomy & histology, Prefrontal Cortex anatomy & histology, Prefrontal Cortex physiology, Temporal Lobe anatomy & histology, Temporal Lobe physiology, Motor Activity physiology, Neurons physiology, Parietal Lobe physiology, Visual Perception physiology
Abstract

Current knowledge regarding the processing of observed manipulative actions (OMAs) (e.g., grasping, dragging, or dropping) is limited to grasping and underlying neural circuitry remains controversial. Here, we addressed these issues by combining chronic neuronal recordings along the anteroposterior extent of monkeys' anterior intraparietal (AIP) area with tracer injections into the recorded sites. We found robust neural selectivity for 7 distinct OMAs, particularly in the posterior part of AIP (pAIP), where it was associated with motor coding of grip type and own-hand visual feedback. This cluster of functional properties appears to be specifically grounded in stronger direct connections of pAIP with the temporal regions of the ventral visual stream and the prefrontal cortex, as connections with skeletomotor related areas and regions of the dorsal visual stream exhibited opposite or no rostrocaudal gradients. Temporal and prefrontal areas may provide visual and contextual information relevant for manipulative action processing. These results revise existing models of the action observation network, suggesting that pAIP constitutes a parietal hub for routing information about OMA identity to the other nodes of the network., (© The Author(s) 2019. Published by Oxford University Press.)

Published
2019
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38. Rostro-caudal Connectional Heterogeneity of the Dorsal Part of the Macaque Prefrontal Area 46.

Author

Borra E, Ferroni CG, Gerbella M, Giorgetti V, Mangiaracina C, Rozzi S, and Luppino G

Subjects
Animals, Executive Function physiology, Female, Macaca fascicularis, Male, Nerve Net chemistry, Parietal Lobe chemistry, Prefrontal Cortex chemistry, Nerve Net physiology, Parietal Lobe physiology, Prefrontal Cortex physiology
Abstract

Based on neural tracer injections we found evidence for 3 connectionally distinct sectors of the dorsal part of the macaque prefrontal area 46 (46d), located at different rostro-caudal levels. Specifically, a rostral sector displayed an almost exclusive and extensive intraprefrontal connectivity and extraprefrontal connections limited to superior temporal areas and the caudal cingulate area 31. Conversely, both a middle and a caudal sector were characterized by robust, topographically organized connections with parietal and frontal sensorimotor areas. Both these sectors shared connections with caudal and medial superior parietal areas (V6A and PGm) where visuospatial information is combined with gaze- and arm-related signals for visuomotor control of arm reaching and/or eye movements. However, the caudal sector was preferentially connected to parietal and frontal oculomotor areas, whereas the middle one was preferentially connected to skeletomotor, mostly arm-related, parietal and premotor areas. The present study provides evidence for a rostro-caudal organization of area 46d similar to that described for the ventrolateral prefrontal cortex, in which more caudal areas are relatively more directly involved in controlling different aspects of motor behavior and more rostral areas are most likely involved in higher order, possibly more abstract, cognitive functions.

Published
2019
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39. Motor and emotional behaviours elicited by electrical stimulation of the human cingulate cortex.

Author

Caruana F, Gerbella M, Avanzini P, Gozzo F, Pelliccia V, Mai R, Abdollahi RO, Cardinale F, Sartori I, Lo Russo G, and Rizzolatti G

Subjects
Electric Stimulation, Female, Humans, Male, Retrospective Studies, Emotions physiology, Gyrus Cinguli anatomy & histology, Gyrus Cinguli physiology, Motor Activity physiology
Abstract

The cingulate cortex is a mosaic of different anatomical fields, whose functional characterization is still a matter of debate. In humans, one method that may provide useful insights on the role of the different cingulate regions, and to tackle the issue of the functional differences between its anterior, middle and posterior subsectors, is intracortical electrical stimulation. While previous reports showed that a variety of integrated behaviours could be elicited by stimulating the midcingulate cortex, little is known about the effects of the electrical stimulation of anterior and posterior cingulate regions. Moreover, the internal arrangement of different behaviours within the midcingulate cortex is still unknown. In the present study, we extended previous stimulation studies by retrospectively analysing all the clinical manifestations induced by intracerebral high frequency electrical stimulation (50 Hz, pulse width: 1 ms, 5 s, current intensity: average intensity of 2.7 ± 0.7 mA, biphasic) of the entire cingulate cortex in a cohort of 329 drug-resistant epileptic patients (1789 stimulation sites) undergoing stereo-electroencephalography for a presurgical evaluation. The large number of patients, on one hand, and the accurate multimodal image-based localization of stereo-electroencephalography electrodes, on the other hand, allowed us to assign specific functional properties to modern anatomical subdivisions of the cingulate cortex. Behavioural or subjective responses were elicited from the 32.3% of all cingulate sites, mainly located in the pregenual and midcingulate regions. We found clear functional differences between the pregenual part of the cingulate cortex, hosting the majority of emotional, interoceptive and autonomic responses, and the anterior midcingulate sector, controlling the majority of all complex motor behaviours. Particularly interesting was the 'actotopic' organization of the anterior midcingulate sector, arranged along the ventro-dorsal axis: (i) whole-body behaviours directed to the extra-personal space, such as getting-up impulses, were elicited ventrally, close to the corpus callosum; (ii) hand actions in the peripersonal space were evoked by the stimulation of the intermediate position; and (iii) body-directed actions were induced by the stimulation of the dorsal branch of the cingulate sulcus. The caudal part of the midcingulate cortex and the posterior cingulate cortex were, in contrast, poorly excitable, and mainly devoted to sensory modalities. In particular, the caudal part of the midcingulate cortex hosted the majority of vestibular responses, while posterior cingulate cortex was the principal recipient of visual effects. We will discuss our data in the light of current controversies on the role of the cingulate cortex in cognition and emotion.

Published
2018
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40. Cortical and subcortical connections of parietal and premotor nodes of the monkey hand mirror neuron network.

Author

Bruni S, Gerbella M, Bonini L, Borra E, Coudé G, Ferrari PF, Fogassi L, Maranesi M, Rodà F, Simone L, Serventi FU, and Rozzi S

Subjects
Action Potentials physiology, Afferent Pathways, Animals, Cholera Toxin metabolism, Female, Macaca nemestrina, Male, Motor Cortex physiology, Parietal Lobe physiology, Wheat Germ Agglutinin-Horseradish Peroxidase Conjugate metabolism, Brain Mapping, Hand physiology, Mirror Neurons physiology, Motor Cortex cytology, Parietal Lobe cytology, Psychomotor Performance physiology
Abstract

Mirror neurons (MNs) are a class of cells originally discovered in the monkey ventral premotor cortex (PMv) and inferior parietal lobule (IPL). They discharge during both action execution and action observation and appear to play a crucial role in understanding others' actions. It has been proposed that the mirror mechanism is based on a match between the visual description of actions, encoded in temporal cortical regions, and their motor representation, provided by PMv and IPL. However, neurons responding to action observation have been recently found in other cortical regions, suggesting that the mirror mechanism relies on a wider network. Here we provide the first description of this network by injecting neural tracers into physiologically identified IPL and PMv sectors containing hand MNs. Our results show that these sectors are reciprocally connected, in line with the current view, but IPL MN sectors showed virtually no direct connection with temporal visual areas. In addition, we found that PMv and IPL MN sectors share connections with several cortical regions, including the dorsal and mesial premotor cortex, the primary motor cortex, the secondary somatosensory cortex, the mid-dorsal insula and the ventrolateral prefrontal cortex, as well as subcortical structures, such as motor and polysensory thalamic nuclei and the mid-dorsal claustrum. We propose that each of these regions constitutes a node of an "extended network", through which information relative to ongoing movements, social context, environmental contingencies, abstract rules, and internal states can influence MN activity and contribute to several socio-cognitive functions.

Published
2018
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41. The extended object-grasping network.

Author

Gerbella M, Rozzi S, and Rizzolatti G

Subjects
Animals, Humans, Motor Cortex anatomy & histology, Nerve Net anatomy & histology, Parietal Lobe anatomy & histology, Prefrontal Cortex anatomy & histology, Hand physiology, Motor Activity physiology, Motor Cortex physiology, Nerve Net physiology, Parietal Lobe physiology, Prefrontal Cortex physiology, Visual Perception physiology
Abstract

Grasping is the most important skilled motor act of primates. It is based on a series of sensorimotor transformations through which the affordances of the objects to be grasped are transformed into appropriate hand movements. It is generally accepted that a circuit formed by inferior parietal areas AIP and PFG and ventral premotor area F5 represents the core circuit for sensorimotor transformations for grasping. However, selection and control of appropriate grip should also depend on higher-order information, such as the meaning of the object to be grasped, and the overarching goal of the action in which grasping is embedded. In this review, we describe recent findings showing that specific sectors of the ventrolateral prefrontal cortex are instrumental in controlling higher-order aspects of grasping. We show that these prefrontal sectors control the premotor cortex through two main gateways: the anterior subdivision of ventral area F5-sub-area F5a-, and the pre-supplementary area (area F6). We then review functional studies showing that both F5a and F6, besides being relay stations of prefrontal information, also play specific roles in grasping. Namely, sub-area F5a is involved in stereoscopic analysis of 3D objects, and in planning cue-dependent grasping activity. As for area F6, this area appears to play a crucial role in determining when to execute the motor program encoded in the parieto-premotor circuit. The recent discovery that area F6 contains a set of neurons encoding specific grip types suggests that this area, besides controlling "when to go", also may control the grip type, i.e., "how to go". We conclude by discussing clinical syndromes affecting grasping actions and their possible mechanisms.

Published
2017
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42. The macaque lateral grasping network: A neural substrate for generating purposeful hand actions.

Author

Borra E, Gerbella M, Rozzi S, and Luppino G

Subjects
Animals, Brain Mapping, Humans, Macaca, Motor Cortex, Psychomotor Performance, Visual Perception, Hand, Hand Strength
Abstract

In primates, neural mechanisms for controlling skilled hand actions primarily rely on sensorimotor transformations. These transformations are mediated by circuits linking specific inferior parietal with ventral premotor areas in which sensory coding of objects' features automatically triggers appropriate hand motor programs. Recently, connectional studies in macaques showed that these parietal and premotor areas are nodes of a large-scale cortical network, designated as "lateral grasping network," including specific temporal and prefrontal sectors involved in object recognition and executive functions, respectively. These data extend grasping models so far proposed in providing a possible substrate for interfacing perceptual, cognitive, and hand-related sensorimotor processes for controlling hand actions based on object identity, goals, and memory-based or contextual information and for the contribution of motor signals to cognitive motor functions. Human studies provided evidence for a possible counterpart of the macaque lateral grasping network, suggesting that in primate evolution the neural mechanisms for controlling hand actions described in the macaque have been retained and exploited for the emergence of human-specific motor and cognitive motor capacities., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published
2017
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43. Extending the Cortical Grasping Network: Pre-supplementary Motor Neuron Activity During Vision and Grasping of Objects.

Author

Lanzilotto M, Livi A, Maranesi M, Gerbella M, Barz F, Ruther P, Fogassi L, Rizzolatti G, and Bonini L

Subjects
Action Potentials, Animals, Electric Stimulation, Electrodes, Implanted, Forearm physiology, Macaca mulatta, Macaca nemestrina, Male, Hand physiology, Motor Activity physiology, Motor Cortex physiology, Neurons physiology, Visual Perception physiology
Abstract

Grasping relies on a network of parieto-frontal areas lying on the dorsolateral and dorsomedial parts of the hemispheres. However, the initiation and sequencing of voluntary actions also requires the contribution of mesial premotor regions, particularly the pre-supplementary motor area F6. We recorded 233 F6 neurons from 2 monkeys with chronic linear multishank neural probes during reaching-grasping visuomotor tasks. We showed that F6 neurons play a role in the control of forelimb movements and some of them (26%) exhibit visual and/or motor specificity for the target object. Interestingly, area F6 neurons form 2 functionally distinct populations, showing either visually-triggered or movement-related bursts of activity, in contrast to the sustained visual-to-motor activity displayed by ventral premotor area F5 neurons recorded in the same animals and with the same task during previous studies. These findings suggest that F6 plays a role in object grasping and extend existing models of the cortical grasping network., (© The Author 2016. Published by Oxford University Press.)

Published
2016
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44. Corticostriate Projections from Areas of the "Lateral Grasping Network": Evidence for Multiple Hand-Related Input Channels.

Author

Gerbella M, Borra E, Mangiaracina C, Rozzi S, and Luppino G

Subjects
Animals, Cerebral Cortex physiology, Corpus Striatum physiology, Functional Laterality, Macaca fascicularis, Macaca mulatta, Macaca nemestrina, Neural Pathways cytology, Neural Pathways physiology, Neuroanatomical Tract-Tracing Techniques, Photomicrography, Cerebral Cortex cytology, Corpus Striatum cytology, Hand physiology, Motor Activity physiology
Abstract

Corticostriatal projections from the primate cortical motor areas partially overlap in different zones of a large postcommissural putaminal sector designated as "motor" putamen. These zones are at the origin of parallel basal ganglia-thalamocortical subloops involved in modulating the cortical motor output. However, it is still largely unknown how parietal and prefrontal areas, connected to premotor areas, and involved in controlling higher order aspects of motor control, project to the basal ganglia. Based on tracer injections at the cortical level, we analyzed the corticostriatal projections of the macaque hand-related ventrolateral prefrontal, ventral premotor, and inferior parietal areas forming a network for controlling purposeful hand actions (lateral grasping network). The results provided evidence for partial overlap or interweaving of these projections in correspondence of 2 putaminal zones, distinct from the motor putamen, one located just rostral to the anterior commissure, the other in the caudal and ventral part. Thus, the present data provide evidence for partial overlap or interweaving in specific striatal zones (input channels) of projections from multiple, even remote, areas taking part in a large-scale functionally specialized cortical network. Furthermore, they suggest the presence of multiple hand-related input channels, possibly differentially involved in controlling goal-directed hand actions., (© The Author 2015. Published by Oxford University Press. All rights reserved. For Permissions, please e-mail: journals.permissions@oup.com.)

Published
2016
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45. Single Neurons in the Insular Cortex of a Macaque Monkey Respond to Skin Brushing: Preliminary Data of the Possible Representation of Pleasant Touch.

Author

Grandi LC and Gerbella M

Abstract

Pleasant touch may serve as a foundation for affiliative behavior, providing a mechanism for the formation and maintenance of social bonds among conspecifics. In humans, this touch is usually referred to as the caress. Dynamic caressing performed on the hairy skin with a velocity of 1-10 cm/s is perceived as being pleasant and determines positive cardio-physiological effects. Furthermore, imaging human studies show that affiliative touch activates the posterior insular cortex (pIC). Recently, it was demonstrated that pleasant touch in monkeys (i.e., sweeping in a grooming-like manner) is performed with velocities similar to those characteristics of human caress (9.31 cm/s), and causes similarly positive autonomic effects, if performed with velocity of 5 cm/s and 10 cm/s, but not lower or higher. Due to similarities between the human caress and non-human primate sweeping, we investigated for the first time whether single neurons of the perisylvian regions (secondary somatosensory cortex [SII] and pIC) of a rhesus monkey can process sweeping touch differently depending on the stimulus speed. We applied stimulation with two speeds: one that optimally induces positive cardio-physiological effects in the monkey who receives it, and includes the real speed of sweep (5-15 cm/s, sweep fast), and a non-optimal speed (1-5 cm/s, sweep slow). The results show that single neurons of insular cortex differently encode the stimulus speed. In particular, even the majority of recorded somatosensory neurons (82.96%) did not discriminate the two speeds, a small set of neurons (16.59%) were modulated just during the sweep fast. These findings represent the first evidence that single neurons of the non-human primates insular cortex can code affiliative touch, highlighting the similarity between human and non-human primates' social touch systems. This study constitutes an important starting point to carry out deeper investigation on neuronal processing of pleasant sweeping in the central nervous system.

Published
2016
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46. Connections of the macaque Granular Frontal Opercular (GrFO) area: a possible neural substrate for the contribution of limbic inputs for controlling hand and face/mouth actions.

Author

Gerbella M, Borra E, Rozzi S, and Luppino G

Subjects
Animals, Brain cytology, Macaca mulatta, Macaca nemestrina, Neural Pathways cytology, Neuroanatomical Tract-Tracing Techniques, Face innervation, Frontal Lobe cytology, Hand innervation, Limbic System cytology, Mouth innervation
Abstract

We traced the connections of the macaque Granular Frontal Opercular (GrFO) area, located in the rostralmost part of the frontal opercular margin, and compared them with those of the caudally adjacent dorsal opercular (DO) and precentral opercular (PrCO) areas. Area GrFO displays strong connections with areas DO, PrCO, and ventrolateral prefrontal (VLPF) area 12l, and even more with the mostly hand-related ventral premotor (PMv) area F5a. Other connections involve the mostly face/mouth-related PMv area F5c, the arm-related area F6/pre-SMA, the hand-related fields of VLPF areas 46v and 12r, and area SII, mostly the hand representation. Furthermore, area GrFO shows rich connectivity with several components of the limbic system including orbitofrontal areas 12o, 12m, and 11, the agranular and dysgranular insula, the agranular cingulate area 24, and the amygdala. Thalamic afferents originate primarily from the parvocellular and the magnocellular subdivisions of the mediodorsal nucleus and from midline and intralaminar nuclei. This connectivity pattern clearly distinguishes area GrFO from areas DO and PrCO, characterized by a connectivity mostly involving oral sensorimotor and gustatory areas/subcortical structures. The present data suggest, based on connectivity patterns, an involvement of area GrFO in the cortical circuits for controlling goal-directed hand and face/mouth actions. In this context, area GrFO could represent a gateway for the access of limbic inputs, for example about subjective values, emotional significance of stimuli or internal states, to the PMv areas involved in selecting appropriate goal-directed hand and mouth/face actions.

Published
2016
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47. A shared neural network for emotional expression and perception: an anatomical study in the macaque monkey.

Author

Jezzini A, Rozzi S, Borra E, Gallese V, Caruana F, and Gerbella M

Abstract

Over the past two decades, the insula has been described as the sensory "interoceptive cortex". As a consequence, human brain imaging studies have focused on its role in the sensory perception of emotions. However, evidence from neurophysiological studies in non-human primates have shown that the insula is also involved in generating emotional and communicative facial expressions. In particular, a recent study demonstrated that electrical stimulation of the mid-ventral sector of the insula evoked affiliative facial expressions. The present study aimed to describe the cortical connections of this "affiliative field". To this aim, we identified the region with electrical stimulation and injected neural tracers to label incoming and outgoing projections. Our results show that the insular field underlying emotional expression is part of a network involving specific frontal, cingulate, temporal, and parietal areas, as well as the amygdala, the basal ganglia, and thalamus, indicating that this sector of the insula is a site of integration of motor, emotional, sensory and social information. Together with our previous functional studies, this result challenges the classic view of the insula as a multisensory area merely reflecting bodily and internal visceral states. In contrast, it supports an alternative perspective; that the emotional responses classically attributed to the insular cortex are endowed with an enactive component intrinsic to each social and emotional behavior.

Published
2015
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48. Projections from caudal ventrolateral prefrontal areas to brainstem preoculomotor structures and to Basal Ganglia and cerebellar oculomotor loops in the macaque.

Author

Borra E, Gerbella M, Rozzi S, and Luppino G

Subjects
Animals, Caudate Nucleus cytology, Macaca fascicularis, Macaca mulatta, Neural Pathways cytology, Neuroanatomical Tract-Tracing Techniques, Pontine Tegmentum cytology, Superior Colliculi cytology, Tegmentum Mesencephali cytology, Basal Ganglia cytology, Brain Stem cytology, Cerebellum cytology, Eye Movements, Prefrontal Cortex cytology
Abstract

The caudal part of the macaque ventrolateral prefrontal (VLPF) cortex hosts several distinct areas or fields--45B, 45A, 8r, caudal 46vc, and caudal 12r--connected to the frontal eye field (area 8/FEF). To assess whether these areas/fields also display subcortical projections possibly mediating a role in controlling oculomotor behavior, we examined their descending projections, based on anterograde tracer injections in each area/field, and compared them with those of area 8/FEF. All the studied areas/fields displayed projections to brainstem preoculomotor structures, precerebellar centers, and striatal sectors that are also targets of projections originating from area 8/FEF. Specifically, these projections involved: (1) the intermediate and superficial layers of the superior colliculus; (2) the mesencephalic and pontine reticular formation; (3) the dorsomedial and lateral pontine nuclei and the reticularis tegmenti pontis; and (4) the body of the caudate nucleus. Furthermore, area 45B projected also to the regions around the trochlear nucleus and to the raphe interpositus. The present data provide evidence for a role of the caudal VLPF areas/fields in controlling oculomotor behavior not only through their connections to area 8/FEF, but also in parallel through a direct access to preoculomotor brainstem structures and to the cerebellar and basal ganglia oculomotor loops., (© The Author 2013. Published by Oxford University Press. All rights reserved. For Permissions, please e-mail: journals.permissions@oup.com.)

Published
2015
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49. Amygdalar connections of the macaque areas 45A and 45B.

Author

Gerbella M, Baccarini M, Borra E, Rozzi S, and Luppino G

Subjects
Amygdala anatomy & histology, Animals, Basal Ganglia anatomy & histology, Behavior, Animal physiology, Macaca, Neural Pathways anatomy & histology, Prefrontal Cortex anatomy & histology, Thalamus anatomy & histology, Thalamus physiology, Amygdala physiology, Basal Ganglia physiology, Brain Mapping, Neural Pathways physiology, Prefrontal Cortex physiology
Abstract

In the present study, based on injections of retro- or retro-anterograde tracers at the cortical level, we analyzed the amygdalar connections of the caudal ventrolateral prefrontal areas 45A and 45B of the macaque and compared them with those of the adjacent areas 8/FEF, 8r, 46v, and 12r. The results showed that areas 45A and 45B display reciprocal amygdalar connections, which appear to be considerably richer than those of their neighboring areas. Specifically, these two areas are a target of differentially weighted projections originating predominantly from the magnocellular and the intermediate subdivisions of the basal nucleus and are a source of projections mostly directed to the magnocellular subdivision of the basal nucleus and the dorsal part of the lateral nucleus. The present data, together with previous data on the thalamic connectivity of areas 45A and 45B (Contini et al. Eur J Neurosci 32:1337-53, 2010), suggest that direct and indirect-trans-thalamic-amygdalar connectivity is a characterizing connectional feature of these two areas. Specifically, the amygdalar connections of area 45A, for which a role in communication behavior has been proposed, could convey information on the emotional significance of communicative signals to this area, where it could play a crucial role in guiding appropriate social interactions. Furthermore, the amygdalar connections of area 45B, possibly involved in higher-order aspects of visual guidance of gaze, could convey information related to the relevance of visual stimuli, which could contribute to a representation of priority maps in this VLPF area.

Published
2014
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50. Projections to the superior colliculus from inferior parietal, ventral premotor, and ventrolateral prefrontal areas involved in controlling goal-directed hand actions in the macaque.

Author

Borra E, Gerbella M, Rozzi S, Tonelli S, and Luppino G

Subjects
Animals, Biotin analogs & derivatives, Biotin metabolism, Dextrans metabolism, Isoquinolines metabolism, Macaca, Neural Pathways physiology, Wheat Germ Agglutinin-Horseradish Peroxidase Conjugate metabolism, Brain Mapping, Cerebral Cortex physiology, Goals, Hand physiology, Parietal Lobe physiology, Superior Colliculi physiology
Abstract

We found that the macaque inferior parietal (PFG and anterior intraparietal [AIP]), ventral premotor (F5p and F5a), and ventrolateral prefrontal (rostral 46vc and intermediate 12r) areas forming a network involved in controlling purposeful hand actions ("lateral grasping network") are a source of corticotectal projections. Based on injections of anterograde tracers at the cortical level, the results showed that all these areas displayed relatively dense projections to the intermediate and deep gray layers of the ipsilateral superior colliculus (SC) and to the ventrally adjacent mesencephalic reticular formation. In the SC, the labeling tended to be richer in the lateral part along almost the entire rostro-caudal extent, that is, in regions controlling microsaccades and downward gaze shifts and hosting arm-related neurons and neurons modulated by the contact of the hand with the target. These projections could represent a descending motor pathway for controlling proximo-distal arm synergies. Furthermore, they could broadcast to the SC information related to hand action goals and object affordances extraction and selection. This information could be used in the SC for controlling orienting behavior (gaze and reaching movements) to the targets of object-oriented actions and for the eye-hand coordination necessary for appropriate hand-object interactions.

Published
2014
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