Your search keyword '"Begliomini C"' showing total 46 results

1. The impulsive brain: Neural underpinnings of binge eating behavior in normal-weight adults

Author

Oliva, R., Morys, F., Horstmann, A., Castiello, U., and Begliomini, C.

Published

2019

2. Lexicality drives audio-motor transformations in Broca’s area

Author

Kotz, S.A., D’Ausilio, A., Raettig, T., Begliomini, C., Craighero, L., Fabbri-Destro, M., Zingales, C., Haggard, P., and Fadiga, L.

Published

2010

3. Statistically robust evidence of stochastic resonance in human auditory perceptual system

Author

Tabarelli, D., Vilardi, A., Begliomini, C., Pavani, F., Turatto, M., and Ricci, L.

Published

2009

4. Effect of Italy’s motorcycle helmet law on traumatic brain injuries

Author

Servadei, F, Begliomini, C, Gardini, E, Giustini, M, Taggi, F, and Kraus, J

Published

2003

5. The neural circuits underlying reaching and grasping movements: from planning to execution

Author

Begliomini C., De Sanctis T., Marangon M., Tarantino V., Sartori L., Miotto D., Motta R., Stramare R., Castiello U., Begliomini C., De Sanctis T., Marangon M., Tarantino V., Sartori L., Miotto D., Motta R., Stramare R., and Castiello U.

Subjects

fMRI, planning, action execution, grasping

Published

2014

6. Adherence issues related to sublingual immunotherapy as perceived by allergists

Author

Scurati, S., Frati, F., Passalacqua, G., Puccinelli, P., Hilaire, C., Incorvaia, C., D Avino, G., Comi, R., Lo Schiavo, M., Pezzuto, F., Montera, C., Pio, A., Teresa Ielpo, M., Cellini, F., Vicentini, L., Pecorari, R., Aresu, T., Capra, L., Benedictis, E., Bombi, C., Zauli, D., Vanzi, A., Alberto Paltrinieri, C., Bondioli, A., Paletta, I., Ventura, D., Mei, F., Paolini, F., Colangelo, C., Cavallucci, E., Cucinelli, F., Tinari, R., Ermini, G., Beltrami, V., Novembre, E., Begliomini, C., Marchese, E., Solito, E., Ammannati, V., Molino, G., Galli, E., Baldassini, M., Di Michele, L., Calvani, M., Gidaro, M., Venuti, A., Li Bianchi, E., Benassi, F., Pocobelli, D., Zangari, P., Rocco, M. G., Lo Vecchio, A., Pingitore, G., Grimaldi, O., Schiavino, D., Perrone, N., Antonietta Frieri, M., Di Rienzo, V., Tripodi, S., Scarpa, A., Tomsic, M., Bonaguro, R., Enrico Senna, G., Sirena, A., Turatello, F., Crescioli, S., Favero, E., Billeri, L., Chieco Bianchi, F., Gemignani, C., Zanforlin, M., Angiola Crivellaro, M., Hendrick, B., Maltauro, A., Masieri, S., Elisabetta Conte, M., Fama, M., Pozzan, M., Bonadonna, P., Casanova, S., Vallerani, E., Schiappoli, M., Borghesan, F., Giro, G., Casotto, S., Berardino, L., Zanoni, G., Ariano, R., Aquilina, R., Pellegrino, R., Marsico, P., Del Giudice, A., Narzisi, G., Tomaselli, V., Fornaca, G., Favro, M., Loperfido, B., Gallo, C., Buffoni, S., Gani, F., Raviolo, P., Faggionato, S., Truffelli, T., Vivalda, L., Albano, M., Enzo Rossi, R., Lattuada, G., Bona, F., Quaglio, L., Chiesa, A., Trapani, M., Seminara, R., Cucchi, B., Oderda, S., Borio, G., Galeasso, G., Garbaccio, P., Marco, A., Marengo, F., Cadario, G., Manzoni, S., Vinay, C., Curcio, A., Silvestri, A., Peduto, A., Riario-Sforza, G. G., Maria Forgnone, A., Barocelli, P., Tartaglia, N., Feyles, G., Giacone, A., Ricca, V., Guida, G., Nebiolo, F., Bommarito, L., Heffler, E., Vietti, F., Galimberti, M., Savi, E., Pappacoda, A., Bottero, P., Porcu, S., Felice, G., Berra, D., Francesca Spina, M., Pravettoni, V., Calamari, A. M., Varin, E., Iemoli, E., Lietti, D., Ghiglioni, D., Alessandro Fiocchi, Tosi, A., Poppa, M., Caviglia, A., Restuccia, M., Russello, M., Alciato, P., Manzotti, G., Ranghino, E., Luraschi, G., Rapetti, A., Rivolta, F., Allegri, F., Terracciano, L., Agostinis, F., Paolo Piras, P., Ronchi, G., Gaspardini, G., Caria, V., Tolu, F., Fantasia, D., Carta, P., Moraschini, A., Quilleri, R., Santelli, A., Prandini, P., Del Giudice, G., Apollonio, A., Bonazza, L., Teresa Franzini, M., Branchi, S., Zanca, M., Rinaldi, S., Catelli, L., Zanoletti, T., Cosentino, C., Della Torre, F., Cremonte, L., Musazzi, D., Suli, C., Rivolta, L., Ottolenghi, A., Marino, G., Sterza, G., Sambugaro, R., Orlandini, A., Minale, P., Voltolini, S., Bignardi, D., Omodeo, P., Tiri, A., Milani, S., Ronchi, B., Licardi, G., Bruni, P., Scibilia, J., Schroeder, J., Crosti, F., Maltagliati, A., Alesina, M. R., Mosca, M., Leone, G., Napolitano, G., Di Gruttola, G., Scala, G., Mascio, S., Valente, A., Marchetiello, I., Catello, R., Gazulli, A., Del Prete, A., Varricchio, A. M., Carbone, A., Forestieri, A., Stillitano, M., Leonetti, L., Tirroni, E., Castellano, F., Abbagnara, F., Romano, F., Levanti, C., Cilia, M., Longo, R., Ferrari, A., Merenda, R., Di Ponti, A., Guercio, E., Surace, L., Ammendola, G., Tansella, F., Peccarisi, L., Stragapede, L., Minenna, M., Granato, M., Fuiano, N., Pannofino, A., Ciuffreda, S., Giannotta, A., Morero, G., D Oronzio, L., Taddeo, G., Nettis, E., Cinquepalmi, G., Lamanna, C., Mastrandrea, F., Minelli, M., Salamino, F., Muratore, L., Latorre, F., Quarta, C., Ventura, M., D Ippolito, G., Giannoccaro, F., Dambra, P., Pinto, L., Triggiani, M., Munno, G., Manfredi, G., Lonero, G., Damiano, V., Errico, G., Di Leo, E., Manzari, F., Spagna, V., Arsieni, A., Matarrese, A., Mazzarella, G., Scarcia, G., Scarano, R., Ferrannini, A., Pastore, A., Maionchi, P., Filannino, L., Tria, M., Giuliano, G., Damiani, E., Scichilone, N., Marchese, M., Lucania, A., Marino, M., Strazzeri, L., Tumminello, S., Vitale, G. I., Gulotta, S., Gragotto, G., Zambito, M., Greco, D., Valenti, G., Licitra, G., Cannata, E., Filpi, R., Contraffatto, M., Sichili, S., Randazzo, S., Scarantino, G., Lo Porto, B., Pavone, F., Di Bartolo, C., Paternò, A., Rapisarda, F., Laudani, E., Leonardi, S., Padua, V., Cabibbo, G., Marino Guzzardi, G., Deluca, F., Agozzino, C., Pettinato, R., Ghini, M., Scurati S., Frati F., Passalacqua G., Puccinelli P., Hilaire C., Incorvaia C., D'Avino G., Comi R., Lo Schiavo M., Pezzuto F., Montera C., Pio A., Teresa Ielpo M., Cellini F., Vicentini L., Pecorari R., Aresu T., Capra L., De Benedictis E., Bombi C., Zauli D., Vanzi A., Alberto Paltrinieri C., Bondioli A., Paletta I., Ventura D., Mei F., Paolini F., Colangelo C., Cavallucci E., Cucinelli F., Tinari R., Ermini G., Beltrami V., Novembre E., Begliomini C., Marchese E., Solito E., Ammannati V., Molino G., Galli E., Baldassini M., Di Michele L., Calvani M., Gidaro M., Venuti A., Li Bianchi E., Benassi F., Pocobelli D., Zangari P., De Rocco M.G., Lo Vecchio A., Pingitore G., Grimaldi O., Schiavino D., Perrone N., Antonietta Frieri M., Di Rienzo V., Tripodi S., Scarpa A., Tomsic M., Bonaguro R., Enrico Senna G., Sirena A., Turatello F., Crescioli S., Favero E., Billeri L., Chieco Bianchi F., Gemignani C., Zanforlin M., Angiola Crivellaro M., Hendrick B., Maltauro A., Masieri S., Elisabetta Conte M., Fama M., Pozzan M., Bonadonna P., Casanova S., Vallerani E., Schiappoli M., Borghesan F., Giro G., Casotto S., Berardino L., Zanoni G., Ariano R., Aquilina R., Pellegrino R., Marsico P., Del Giudice A., Narzisi G., Tomaselli V., Fornaca G., Favro M., Loperfido B., Gallo C., Buffoni S., Gani F., Raviolo P., Faggionato S., Truffelli T., Vivalda L., Albano M., Enzo Rossi R., Lattuada G., Bona F., Quaglio L., Chiesa A., Trapani M., Seminara R., Cucchi B., Oderda S., Borio G., Galeasso G., Garbaccio P., De Marco A., Marengo F., Cadario G., Manzoni S., Vinay C., Curcio A., Silvestri A., Peduto A., Riario-Sforza G.G., Maria Forgnone A., Barocelli P., Tartaglia N., Feyles G., Giacone A., Ricca V., Guida G., Nebiolo F., Bommarito L., Heffler E., Vietti F., Galimberti M., Savi E., Pappacoda A., Bottero P., Porcu S., Felice G., Berra D., Francesca Spina M., Pravettoni V., Calamari A.M., Varin E., Iemoli E., Lietti D., Ghiglioni D., Fiocchi A., Tosi A., Poppa M., Caviglia A., Restuccia M., Russello M., Alciato P., Manzotti G., Ranghino E., Luraschi G., Rapetti A., Rivolta F., Allegri F., Terracciano L., Agostinis F., Paolo Piras P., Ronchi G., Gaspardini G., Caria V., Tolu F., Fantasia D., Carta P., Moraschini A., Quilleri R., Santelli A., Prandini P., Del Giudice G., Apollonio A., Bonazza L., Teresa Franzini M., Branchi S., Zanca M., Rinaldi S., Catelli L., Zanoletti T., Cosentino C., Della Torre F., Cremonte L., Musazzi D., Suli C., Rivolta L., Ottolenghi A., Marino G., Sterza G., Sambugaro R., Orlandini A., Minale P., Voltolini S., Bignardi D., Omodeo P., Tiri A., Milani S., Ronchi B., Licardi G., Bruni P., Scibilia J., Schroeder J., Crosti F., Maltagliati A., Alesina M.R., Mosca M., Leone G., Napolitano G., Di Gruttola G., Scala G., Mascio S., Valente A., Marchetiello I., Catello R., Gazulli A., Del Prete A., Varricchio A.M., Carbone A., Forestieri A., Stillitano M., Leonetti L., Tirroni E., Castellano F., Abbagnara F., Romano F., Levanti C., Cilia M., Longo R., Ferrari A., Merenda R., Di Ponti A., Guercio E., Surace L., Ammendola G., Tansella F., Peccarisi L., Stragapede L., Minenna M., Granato M., Fuiano N., Pannofino A., Ciuffreda S., Giannotta A., Morero G., D'Oronzio L., Taddeo G., Nettis E., Cinquepalmi G., Lamanna C., Mastrandrea F., Minelli M., Salamino F., Muratore L., Latorre F., Quarta C., Ventura M., D'Ippolito G., Giannoccaro F., Dambra P., Pinto L., Triggiani M., Munno G., Manfredi G., Lonero G., Damiano V., Errico G., Di Leo E., Manzari F., Spagna V., Arsieni A., Matarrese A., Mazzarella G., Scarcia G., Scarano R., Ferrannini A., Pastore A., Maionchi P., Filannino L., Tria M., Giuliano G., Damiani E., Scichilone N., Marchese M., Lucania A., Marino M., Strazzeri L., Tumminello S., Vitale G.I., Gulotta S., Gragotto G., Zambito M., Greco D., Valenti G., Licitra G., Cannata E., Filpi R., Contraffatto M., Sichili S., Randazzo S., Scarantino G., Lo Porto B., Pavone F., Di Bartolo C., Paterno A., Rapisarda F., Laudani E., Leonardi S., Padua V., Cabibbo G., Marino Guzzardi G., Deluca F., Agozzino C., Pettinato R., Ghini M., Scurati S, Frati F, Passalacqua G, Puccinelli P, Hilaire C, Incorvaia I, D'Avino G, Comi R, Lo Schiavio M, Pezzuto F, Montera C, Pio A, Ielpo MT, Cellini F, Vicentini L, Pecorari R, Aresu T, Capra L, De Benedictis E, Bombi C, Zauli D, and et al

Subjects

medicine.medical_specialty, Pathology, genetic structures, efficacy, Alternative medicine, Medicine (miscellaneous), Adherence, Cost, Efficacy, Side effects, Sublingual immunotherapy, Settore MED/10 - Malattie Dell'Apparato Respiratorio, sublingual immunotherapy, ALLERGEN, cost, medicine, Subcutaneous immunotherapy, Sublingual immunotherapy, adherence, Clinical efficacy, Intensive care medicine, Pharmacology, Toxicology and Pharmaceutics (miscellaneous), sublingual immunoterapy, Original Research, Asthma, AEROALLERGENS, side effects, business.industry, Health Policy, medicine.disease, Slit, eye diseases, Clinical trial, Patient Preference and Adherence, immunotherapy, sense organs, Allergists, ADHERENCE TO TREATMENT, business, Social Sciences (miscellaneous)

Abstract

Silvia Scurati1, Franco Frati1, Gianni Passalacqua2, Paola Puccinelli1, Cecile Hilaire1, Cristoforo Incorvaia3, Italian Study Group on SLIT Compliance 1Scientific and Medical Department, Stallergenes, Milan, Italy; 2Allergy and Respiratory Diseases, Department of Internal Medicine, Genoa; 3Allergy/Pulmonary Rehabilitation, ICP Hospital, Milan, ItalyObjectives: Sublingual immunotherapy (SLIT) is a viable alternative to subcutaneous immunotherapy to treat allergic rhinitis and asthma, and is widely used in clinical practice in many European countries. The clinical efficacy of SLIT has been established in a number of clinical trials and meta-analyses. However, because SLIT is self-administered by patients without medical supervision, the degree of patient adherence with treatment is still a concern. The objective of this study was to evaluate the perception by allergists of issues related to SLIT adherence.Methods: We performed a questionnaire-based survey of 296 Italian allergists, based on the adherence issues known from previous studies. The perception of importance of each item was assessed by a VAS scale ranging from 0 to 10.Results: Patient perception of clinical efficacy was considered the most important factor (ranked 1 by 54% of allergists), followed by the possibility of reimbursement (ranked 1 by 34%), and by the absence of side effects (ranked 1 by 21%). Patient education, regular follow-up, and ease of use of SLIT were ranked first by less than 20% of allergists.Conclusion: These findings indicate that clinical efficacy, cost, and side effects are perceived as the major issues influencing patient adherence to SLIT, and that further improvement of adherence is likely to be achieved by improving the patient information provided by prescribers.Keywords: adherence, sublingual immunotherapy, efficacy, cost, side effects

Published

2010

7. When ears drive hands: the influence of contact sound on reaching to grasp

Author

Gilbert, S., Castiello, U., Giordano, B.L., Begliomini, C., Ansuini, C., and Grassi, M.

Subjects

genetic structures

Abstract

Background\ud \ud Most research on the roles of auditory information and its interaction with vision has focused on perceptual performance. Little is known on the effects of sound cues on visually-guided hand movements.\ud \ud Methodology/Principal Findings\ud \ud We recorded the sound produced by the fingers upon contact as participants grasped stimulus objects which were covered with different materials. Then, in a further session the pre-recorded contact sounds were delivered to participants via headphones before or following the initiation of reach-to-grasp movements towards the stimulus objects. Reach-to-grasp movement kinematics were measured under the following conditions: (i) congruent, in which the presented contact sound and the contact sound elicited by the to-be-grasped stimulus corresponded; (ii) incongruent, in which the presented contact sound was different to that generated by the stimulus upon contact; (iii) control, in which a synthetic sound, not associated with a real event, was presented. Facilitation effects were found for congruent trials; interference effects were found for incongruent trials. In a second experiment, the upper and the lower parts of the stimulus were covered with different materials. The presented sound was always congruent with the material covering either the upper or the lower half of the stimulus. Participants consistently placed their fingers on the half of the stimulus that corresponded to the presented contact sound.\ud \ud Conclusions/Significance\ud \ud Altogether these findings offer a substantial contribution to the current debate about the type of object representations elicited by auditory stimuli and on the multisensory nature of the sensorimotor transformations underlying action.

Published

2010

8. P.1.j.017 Metacognition in individuals with a lifetime history of anorexia nervosa: a voxel based morphometry study

Author

Oliva, R., primary, Begliomini, C., additional, Cereser, L., additional, Camponogara, I., additional, Salvo, P., additional, Carlino, D., additional, Baiano, M., additional, and Oliva, L., additional

Published

2014

9. Testing the effects of end-goal during reach-to-grasp movements in Parkinson's disease.

Author

Ansuini C, Begliomini C, Ferrari T, and Castiello U

Abstract

Previous evidence suggests that hand shaping during reaching is modulated by the presence and the nature of the end-goal following object's grasp. Here we test whether such modulation is maintained in Parkinson's disease (PD). Six participants with PD and six healthy participants took part in the study. Participants were requested to reach towards a bottle filled with water, and then: (1) grasp it without performing any subsequent action; (2) grasp it and place it accurately on a target area; (3) grasp it and pour its contents within a container. The results showed that participants shaped their hand differently depending on the presence or absence of an action following object's grasp. However, the request to perform an action after grasp determined a modulation of hand kinematics which was delayed for PD than for control participants. Further, whereas for control participants the nature of the end-goal determined a modulation of hand shaping, for PD patients such modulation was not evident. Data are discussed in terms of the role played by basal ganglia in implementing anticipatory mechanisms for the control of manipulative activities. We contend that in PD patients these mechanisms are not totally compromised, but their implementation depends on the action information that has to be anticipated. [ABSTRACT FROM AUTHOR]

Published

2010

10. An investigation of the neural circuits underlying reaching and reach-to-grasp movements: from planning to execution

Author

Roberto Stramare, Raffaella Motta, Diego Miotto, Chiara Begliomini, Vincenza Tarantino, Mattia Marangon, Umberto Castiello, Luisa Sartori, Teresa De Sanctis, Begliomini C., De Sanctis T., Marangon M., Tarantino V., Sartori L., Miotto D., Motta R., Stramare R., Castiello U., Begliomini, Chiara, De Sanctis, Teresa, Marangon, Mattia, Tarantino, Vincenza, Sartori, Luisa, Miotto, Diego, Motta, Raffaella, Stramare, Roberto, and Castiello, Umberto

Subjects

Stimulus (physiology), lcsh:RC321-571, Behavioral Neuroscience, Neuroimaging, motor planning, Biological neural network, medicine, Reach to grasp, functional magnetic resonance imaging, motor execution, reach-to-grasp, reaching, Original Research Article, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Biological Psychiatry, Brain network, medicine.diagnostic_test, Settore M-PSI/02 - Psicobiologia E Psicologia Fisiologica, GRASP, functional magnetic resonance imaging (fMRI), Neuropsychology and Physiological Psychology, Neurology, Psychiatry and Mental Health, Time course, Functional magnetic resonance imaging, Psychology, Neuroscience

Abstract

Experimental evidence suggests the existence of a sophisticated brain circuit specifically dedicated to reach-to-grasp planning and execution, both in human and non-human primates (Castiello, 2005). Studies accomplished by means of neuroimaging techniques suggest the hypothesis of a dichotomy between a "reach-to-grasp" circuit, involving the anterior intraparietal area, the dorsal and ventral premotor cortices (PMd and PMv - Castiello and Begliomini, 2008; Filimon, 2010) and a "reaching" circuit involving the medial intraparietal area and the superior parieto-occipital cortex (Culham et al., 2006). However, the time course characterizing the involvement of these regions during the planning and execution of these two types of movements has yet to be delineated. A functional magnetic resonance imaging study has been conducted, including reach-to-grasp and reaching only movements, performed toward either a small or a large stimulus, and Finite Impulse Response model (Henson, 2003) was adopted to monitor activation patterns from stimulus onset for a time window of 10 s duration. Data analysis focused on brain regions belonging either to the reaching or to the grasping network, as suggested by Castiello and Begliomini (2008). Results suggest that reaching and grasping movements planning and execution might share a common brain network, providing further confirmation to the idea that the neural underpinnings of reaching and grasping may overlap in both spatial and temporal terms (Verhagen et al., 2013). But, although responsive for both actions, they show a significant predominance for either one of the two actions and such a preference is evident on a temporal scale. © 2014 Begliomini, De Sanctis, Marangon, Tarantino, Sartori, Miotto, Motta, Stramare and Castiello.

Published

2014

11. Neural underpinnings of the perceived linkage between voluntary actions and sensory effects: a transcranial direct current stimulation study

Author

Cavazzana, Annachiara, Penolazzi, Barbara, CHIARA BEGLIOMINI, patrizia bisiacchi, Cavazzana, A., Penolazzi, B., Begliomini, C., and Bisiacchi, Patrizia

12. The Role of Cognitive Reserve in Protecting Cerebellar Volumes of Older Adults with mild Cognitive Impairment.

Author

Devita M, Debiasi G, Anglani M, Ceolin C, Mazzonetto I, Begliomini C, Cauzzo S, Raffaelli C, Lazzarin A, Ravelli A, Bordignon A, De Rui M, Sergi G, Bertoldo A, Mapelli D, and Coin A

Subjects

Humans, Male, Aged, Female, Aged, 80 and over, Middle Aged, Organ Size, Cognitive Dysfunction diagnostic imaging, Cognitive Dysfunction psychology, Cognitive Dysfunction physiopathology, Cognitive Reserve physiology, Cerebellum diagnostic imaging, Cerebellum pathology, Magnetic Resonance Imaging, Neuropsychological Tests

Abstract

The present study aims to investigate the relationship between cerebellar volumes and cognitive reserve in individuals with Mild Cognitive Impairment (MCI). A description of proxies of cerebellar cognitive reserve in terms of different volumes across lobules is also provided. 36 individuals with MCI underwent neuropsychological (MoCA, MMSE, Clock test, CRIq) assessment and neuroimaging acquisition with magnetic resonance imaging at 3 T. Simple linear correlations were applied between cerebellar volumes and cognitive measures. Multiple linear regression models were then used to estimate standardized regression coefficients and 95% confidence intervals. Simple linear correlations between cerebellar lobules volumes and cognitive features highlighted a significant association between CRIq_Working activity and specific motor cerebellar volumes: Left_V (ρ = 0.40, p = 0.02), Right_V (r = 0.42, p = 0.002), Vermis_VIIIb (ρ = 0.47, p = 0.003), Left_X (ρ = -0.46, p = 0.002) and Vermis_X (r = 0.35, p = 0.03). Furthermore, CRIq_Working activity scores correlated with certain cerebellar lobules implicated in cognition: Left_Crus_II, Vermis VIIb, Left_IX. MMSE was associated only with the Right_VIIB volume (r = 0.35, p = 0.02), while Clock Drawing Test scores correlated with both Left_Crus_I and Right_Crus_I (r = -0.42 and r = 0.42, p = 0.02, respectively). This study suggests that a higher cognitive reserve is associated with specific cerebellar lobule volumes and that Working activity may play a predominant role in this association. These findings contribute to the understanding of the relationship between cerebellar volumes and cognitive reserve, highlighting the potential modulatory role of Working activity on cerebellum response to cognitive decline., (© 2024. The Author(s).)

Published

2024

13. Deep into Cognition: The Neuropsychological Identikit of Younger and Older Individuals after COVID-19 Infection.

Author

Devita M, Ravelli A, Panzeri A, Di Rosa E, Iannizzi P, Bottesi G, Ceolin C, De Rui M, Cattelan A, Cavinato S, Begliomini C, Volpe B, Schiavo R, Ghisi M, and Mapelli D

Abstract

The literature on COVID-19 continues to increase daily. Cognitive sequelae associated with COVID-19 infection still draw the attention of the scientific community given the lack of consensus about their existence, etiology, characterization and reversibility. The aim of this study is to provide a neuropsychological identikit for younger (<65 years) and older (≥65 years) individuals diagnosed with COVID-19 infection, at baseline and after 3 and 6 months. In total, 226 individuals took part in a retrospective observational study and their cognitive performance was compared across groups (younger adults vs. older adults) and time (T0, T1, T2). The results highlighted differences between younger and older adults in the Montreal Cognitive Assessment (MoCA) global score, as expected in consideration of the different physiological conditions of the two populations. However, memory performance highlighted the two groups as characterized by a difference in patterns of recall that may move beyond a physiological explanation and provide information about COVID-19 cognitive sequelae. This study suggests that cognitive deficits observed in COVID-19 survivors may reflect a difficulty in attention and concentration that interferes mainly with retrieval processes. This result fits well with the concept of "brain fog" typical of post-COVID-19 syndrome and may also reflect the stress experienced while facing the pandemic.

Published

2024

14. The effect of emotion intensity on time perception: a study with transcranial random noise stimulation.

Author

Visalli A, Begliomini C, and Mioni G

Subjects

Humans, Emotions physiology, Anger physiology, Cues, Facial Expression, Time Perception, Transcranial Direct Current Stimulation methods

Abstract

Emotional facial expressions provide cues for social interactions and emotional events can distort our sense of time. The present study investigates the effect of facial emotional stimuli of anger and sadness on time perception. Moreover, to investigate the causal role of the orbitofrontal cortex (OFC) in emotional recognition, we employed transcranial random noise stimulation (tRNS) over OFC and tested the effect on participants' emotional recognition as well as on time processing. Participants performed a timing task in which they were asked to categorize as "short" or "long" temporal intervals marked by images of people expressing anger, sad or neutral emotional facial expressions. In addition, they were asked to judge if the image presented was of a person expressing anger or sadness. The visual stimuli were facial emotional stimuli indicating anger or sadness with different degrees of intensity at high (80%), medium (60%) and low (40%) intensity, along with neutral emotional face stimuli. In the emotional recognition task, results showed that participants were faster and more accurate when emotional intensity was higher. Moreover, tRNS over OFC interfered with emotion recognition, which is in line with its proposed role in emotion recognition. In the timing task, participants overestimated the duration of angry facial expressions, although neither emotional intensity not OFC stimulation significantly modulated this effect. Conversely, as the emotional intensity increased, participants exhibited a greater tendency to overestimate the duration of sad faces in the sham condition. However, this tendency disappeared with tRNS. Taken together, our results are partially consistent with previous findings showing an overestimation effect of emotionally arousing stimuli, revealing the involvement of OFC in emotional distortions of time, which needs further investigation., (© 2023. The Author(s).)

Published

2023

15. When Corticospinal Inhibition Favors an Efficient Motor Response.

Author

Betti S, Zani G, Guerra S, Granziol U, Castiello U, Begliomini C, and Sartori L

Abstract

Many daily activities involve responding to the actions of other people. However, the functional relationship between the motor preparation and execution phases still needs to be clarified. With the combination of different and complementary experimental techniques (i.e., motor excitability measures, reaction times, electromyography, and dyadic 3-D kinematics), we investigated the behavioral and neurophysiological signatures characterizing different stages of a motor response in contexts calling for an interactive action. Participants were requested to perform an action (i.e., stirring coffee or lifting a coffee cup) following a co-experimenter's request gesture. Another condition, in which a non-interactive gesture was used, was also included. Greater corticospinal inhibition was found when participants prepared their motor response after observing an interactive request, compared to a non-interactive gesture. This, in turn, was associated with faster and more efficient action execution in kinematic terms (i.e., a social motor priming effect). Our results provide new insights on the inhibitory and facilitatory drives guiding social motor response generation. Altogether, the integration of behavioral and neurophysiological indexes allowed us to demonstrate that a more efficient action execution followed a greater corticospinal inhibition. These indexes provide a full picture of motor activity at both planning and execution stages.

Published

2023

16. Structure of the Motor Descending Pathways Correlates with the Temporal Kinematics of Hand Movements.

Author

Begliomini C, Ceccarini F, Dell'Acqua VP, Budisavljevic S, and Castiello U

Abstract

The projection system, a complex organization of ascending and descending white matter pathways, is the principal system for conveying sensory and motor information, connecting frontal and sensorimotor regions with ventral regions of the central nervous system. The corticospinal tract (CST), one of the principal projection pathways, carries distal movement-related information from the cortex to the spinal cord, and whether its microstructure is linked to the kinematics of hand movements is still an open question. The aim of the present study was to explore how microstructure of descending branches of the projection system, namely the hand motor tract (HMT), the corticospinal tract (CST) and its sector within the internal capsule (IC), can relate to the temporal profile of reaching and reach-to-grasp movements. Projection pathways of 31 healthy subjects were virtually dissected by means of diffusion tractography and the kinematics of reaching and reach-to-grasp movements were also analyzed. A positive association between Hindrance Modulated Orientation Anisotropy (HMOA) and kinematics was observed, suggesting that anisotropy of the considered tract can influence the temporal unfolding of motor performance. We highlight, for the first time, that hand kinematics and the visuomotor transformation processes underlying reaching and reach-to-grasp movements relate to the microstructure of specific projection fibers subserving these movements.

Published

2022

17. Neuroanatomical Correlates of Binge-Eating Behavior: At the Roots of Unstoppable Eating.

Author

Oliva R, Budisavljević S, Castiello U, and Begliomini C

Abstract

Binge-eating refers to episodes of uncontrolled eating accompanied by a perceived loss of control, which can be common in the general population. Given the profound negative consequences of persistent binge-eating such as weight and eating disorders, it is vital to determine what makes someone more vulnerable than others to engage in such a conduct. A total of 42 normal-weight individuals (21 with binge-eating episodes and 21 without binge-eating episodes) underwent a structural magnetic resonance imaging measurement and Voxel-based morphometry (VBM) was used to assess between-group differences in terms of gray matter volume (GMV), together with self-report impulsivity and binge-eating measures. The results showed binge-eating individuals as characterized by higher trait impulsivity and greater regional GMV in the left middle frontal gyrus: however, the GMV in this region appeared to be positively correlated only with measures of binge-eating but not with trait impulsivity measures. These findings provide novel insights on the neurobiological roots of BE in normal-weight individuals and highlight how this behavior can be associated with brain morphometric changes within prefrontal regions also in a non-clinical population. Overall, this study provides a further characterization of the neural correlates of binge-eating and novel insights into the treatment of its more severe pathological forms.

Published

2021

18. Reach-to-Grasp: A Multisensory Experience.

Author

Betti S, Castiello U, and Begliomini C

Abstract

The reach-to-grasp movement is ordinarily performed in everyday living activities and it represents a key behavior that allows humans to interact with their environment. Remarkably, it serves as an experimental test case for probing the multisensory architecture of goal-oriented actions. This review focuses on experimental evidence that enhances or modifies how we might conceptualize the "multisensory" substrates of prehension. We will review evidence suggesting that how reach-to-grasp movements are planned and executed is influenced by information coming from different sensory modalities such as vision, proprioception, audition, taste, and olfaction. The review closes with some considerations about the predominant role of the multisensory constituents in shaping prehensile behavior and how this might be important for future research developments, especially in the rehabilitative domain., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Betti, Castiello and Begliomini.)

Published

2021

19. Handedness and White Matter Networks.

Author

Budisavljevic S, Castiello U, and Begliomini C

Subjects

Corpus Callosum diagnostic imaging, Diffusion Tensor Imaging, Humans, Nerve Net diagnostic imaging, Pyramidal Tracts diagnostic imaging, White Matter diagnostic imaging, Corpus Callosum anatomy & histology, Functional Laterality physiology, Nerve Net anatomy & histology, Pyramidal Tracts anatomy & histology, White Matter anatomy & histology

Abstract

The development and persistence of laterality is a key feature of human motor behavior, with the asymmetry of hand use being the most prominent. The idea that asymmetrical functions of the hands reflect asymmetries in terms of structural and functional brain organization has been tested many times. However, despite advances in laterality research and increased understanding of this population-level bias, the neural basis of handedness remains elusive. Recent developments in diffusion magnetic resonance imaging enabled the exploration of lateralized motor behavior also in terms of white matter and connectional neuroanatomy. Despite incomplete and partly inconsistent evidence, structural connectivity of both intrahemispheric and interhemispheric white matter seems to differ between left and right-handers. Handedness was related to asymmetry of intrahemispheric pathways important for visuomotor and visuospatial processing (superior longitudinal fasciculus), but not to projection tracts supporting motor execution (corticospinal tract). Moreover, the interindividual variability of the main commissural pathway corpus callosum seems to be associated with handedness. The review highlights the importance of exploring new avenues for the study of handedness and presents the latest state of knowledge that can be used to guide future neuroscientific and genetic research.

Published

2021

20. Metacognition in individuals recovered from anorexia nervosa: a voxel-based morphometry study.

Author

Oliva R, Baiano M, Salvo P, Cereser L, Castiello U, and Begliomini C

Subjects

Anorexia Nervosa diagnostic imaging, Brain pathology, Cerebral Cortex diagnostic imaging, Cerebral Cortex pathology, Female, Gray Matter diagnostic imaging, Gray Matter pathology, Humans, Magnetic Resonance Imaging, Prefrontal Cortex diagnostic imaging, Prefrontal Cortex pathology, Anorexia Nervosa pathology, Brain diagnostic imaging, Metacognition

Abstract

Recent evidence shows that individuals with Anorexia Nervosa (AN) can be characterized by dysfunctional metacognition as well as reductions of gray matter volumes (GMV) in prefrontal brain regions involved in cognitive processes. However, whether these differences are reversible or stable markers has yet to be understood. Thus, we aimed at characterizing metacognition and brain morphometry in individuals recovered from AN (rec-AN). A combined psychometric-brain morphometry investigation on metacognitive functioning in rec-AN individuals was conducted. Fifteen healthy controls (HC) and fifteen rec-AN women underwent a psychometric assessment for metacognitive functioning and a high-resolution T1-weighted Magnetic Resonance Imaging measurement to assess global and regional brain volumes, using Voxel-Based Morphometry. The two groups did not differ for metacognitive functioning and GMV, while regional GMV reductions were observed in rec-AN compared to HC in the left Inferior Frontal Gyrus (IFG). While changes in metacognitive abilities may not represent a stable trait of AN, regional GMV reductions in brain regions devoted to specific cognitive functions, such as inhibitory/top-down control processes, can act as a neurobiological fingerprint for such condition. These findings can represent a promising hint for future investigations on the maintaining factors of AN., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2020

21. Characterizing impulsivity and resting-state functional connectivity in normal-weight binge eaters.

Author

Oliva R, Morys F, Horstmann A, Castiello U, and Begliomini C

Subjects

Adult, Female, Humans, Male, Young Adult, Binge-Eating Disorder psychology, Impulsive Behavior physiology, Magnetic Resonance Imaging methods

Abstract

Objective: Binge eating is characterized by episodes of uncontrolled eating, within discrete periods of time. Although it is usually described in obese individuals or as a symptom of Binge Eating Disorder (BED), this behavior can also occur in the normal-weight (NW) population. An interesting premise suggests that impulsivity might contribute to the onset of binge eating and the progression toward weight gain. Drawing upon this evidence, here we explored impulsivity in NW individuals reporting binge-eating episodes through a functional connectivity approach. We hypothesized that, even in the absence of an eating disorder, NW binge eaters would be characterized by connectivity pattern changes in corticostriatal regions implicated in impulsivity, similarly to the results described in BED individuals., Methods: A resting-state functional magnetic resonance imaging study tested 39 NW men and women, with and without binge eating (binge eaters, BE and non-BE). Brain functional connectivity was explored by means of graph theoretic centrality measures and traditional seed-based analysis; trait impulsivity was assessed with self-report questionnaires., Results: The BE group was characterized by a higher degree of trait impulsivity. Brain functional connectivity measures revealed lower degree centrality within the right middle frontal gyrus, left insula/putamen and left temporoparietal regions and a lower functional connectivity between the right middle frontal gyrus and right insula in the BE group., Discussion: The results support previous evidence on BED of altered functional connectivity and higher impulsivity at the roots of overeating behavior, but further extend this concept excluding any potential confounding effect exerted by the weight status., (© 2019 Wiley Periodicals, Inc.)

Published

2020

22. The effect of mental countermeasures on neuroimaging-based concealed information tests.

Author

Hsu CW, Begliomini C, Dall'Acqua T, and Ganis G

Subjects

Brain Mapping methods, Female, Humans, Magnetic Resonance Imaging, Male, Neuroimaging methods, Young Adult, Brain physiology, Recognition, Psychology physiology

Abstract

During the last decade and a half, functional magnetic resonance imaging (fMRI) has been used to determine whether it is possible to detect concealed knowledge by examining brain activation patterns, with mixed results. Concealed information tests rely on the logic that a familiar item (probe) elicits a stronger response than unfamiliar, but otherwise comparable items (irrelevants). Previous work has shown that physical countermeasures can artificially modulate neural responses in concealed information tests, decreasing the accuracy of these methods. However, the question remains as to whether purely mental countermeasures, which are much more difficult to detect than physical ones, can also be effective. An fMRI study was conducted to address this question by assessing the effect of attentional countermeasures on the accuracy of the classification between knowledge and no-knowledge cases using both univariate and multivariate analyses. Results replicate previous work and show reliable group activation differences between the probe and the irrelevants in fronto-parietal networks. Critically, classification accuracy was generally reduced by the mental countermeasures, but only significantly so with region of interest analyses (both univariate and multivariate). For whole-brain analyses, classification accuracy was relatively low, but it was not significantly reduced by the countermeasures. These results indicate that mental countermeasure need to be addressed before these paradigms can be used in applied settings and that methods to defeat countermeasures, or at least to detect their use, need to be developed. HIGHLIGHTS: FMRI-based concealed information tests are vulnerable to mental countermeasures Measures based on regions of interest are affected by mental countermeasures Whole-brain analyses may be more robust than region of interest ones Methods to detect mental countermeasure use are needed for forensic applications., (© 2019 Wiley Periodicals, Inc.)

Published

2019

23. The Neural Correlates of Grasping in Left-Handers: When Handedness Does Not Matter.

Author

Begliomini C, Sartori L, Di Bono MG, Budisavljević S, and Castiello U

Abstract

Neurophysiological studies showed that in macaques, grasp-related visuomotor transformations are supported by a circuit involving the anterior part of the intraparietal sulcus, the ventral and the dorsal region of the premotor area. In humans, a similar grasp-related circuit has been revealed by means of neuroimaging techniques. However, the majority of "human" studies considered movements performed by right-handers only, leaving open the question of whether the dynamics underlying motor control during grasping is simply reversed in left-handers with respect to right-handers or not. To address this question, a group of left-handed participants has been scanned with functional magnetic resonance imaging while performing a precision grasping task with the left or the right hand. Dynamic causal modeling was used to assess how brain regions of the two hemispheres contribute to grasping execution and whether the intra- and inter-hemispheric connectivity is modulated by the choice of the performing hand. Results showed enhanced inter-hemispheric connectivity between anterior intraparietal and dorsal premotor cortices during grasping execution with the left dominant hand (LDH) (e.g., right hemisphere) compared to the right (e.g., left hemisphere). These findings suggest that that the left hand, although dominant and theoretically more skilled in left handers, might need additional resources in terms of the visuomotor control and on-line monitoring to accomplish a precision grasping movement. The results are discussed in light of theories on the modulation of parieto-frontal networks during the execution of prehensile movements, providing novel evidence supporting the hypothesis of a handedness-independent specialization of the left hemisphere in visuomotor control.

Published

2018

24. Effects of intentionality and subliminal information in free-choices to inhibit.

Author

Dall'Acqua T, Begliomini C, Motta R, Miotto D, and Castiello U

Subjects

Adult, Brain diagnostic imaging, Brain Mapping, Cues, Executive Function physiology, Female, Humans, Magnetic Resonance Imaging, Male, Repetition Priming physiology, Visual Perception physiology, Volition physiology, Young Adult, Brain physiology, Choice Behavior physiology, Inhibition, Psychological, Motor Activity physiology, Subliminal Stimulation

Abstract

Stopping an action at the very last moment is an important feature of human behavioural flexibility. Intentional inhibition has been defined as the ability to inhibit an action on the basis of an internal decision process. Without this ability, actions would be impulsive and would leave little space to correct misguided decisions. Previous research suggests that making a choice between action alternatives activates a specific "choice network" that includes the rostral cingulate zone (RCZ), the anterior insula (AI), the dorsolateral prefrontal cortex (DLPFC) and the inferior parietal lobe (IPL). The activity of this network has shown to be influenced by non-conscious (subliminal) stimuli. In this study, we tested whether the same regions are recruited by free-choices to inhibit and modulated by unconscious information as reported in the case of free-choices to act. Using functional magnetic resonance imaging (fMRI) we manipulated the degree of 'freedom' of the choice between acting and inhibiting an action by introducing explicit cues or leaving the participants free to choose between action alternatives. We included subliminal masked primes to test whether responses to targets were facilitated and/or obstructed by conditions of congruency and incongruency between primes and targets. Our findings confirmed higher activation of the "choice network" in free-choice trials when compared to cued choices. However subliminal priming failed to significantly influence participants' responses, in free-choice conditions., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2018

25. Potential for social involvement modulates activity within the mirror and the mentalizing systems.

Author

Begliomini C, Cavallo A, Manera V, Becchio C, Stramare R, Miotto D, and Castiello U

Subjects

Adult, Biomechanical Phenomena, Brain physiology, Brain Mapping, Female, Humans, Intention, Magnetic Resonance Imaging, Male, Motion, Visual Perception, Young Adult, Interpersonal Relations, Mirror Neurons physiology, Theory of Mind

Abstract

Processing biological motion is fundamental for everyday life activities, such as social interaction, motor learning and nonverbal communication. The ability to detect the nature of a motor pattern has been investigated by means of point-light displays (PLD), sets of moving light points reproducing human kinematics, easily recognizable as meaningful once in motion. Although PLD are rudimentary, the human brain can decipher their content including social intentions. Neuroimaging studies suggest that inferring the social meaning conveyed by PLD could rely on both the Mirror Neuron System (MNS) and the Mentalizing System (MS), but their specific role to this endeavor remains uncertain. We describe a functional magnetic resonance imaging experiment in which participants had to judge whether visually presented PLD and videoclips of human-like walkers (HL) were facing towards or away from them. Results show that coding for stimulus direction specifically engages the MNS when considering PLD moving away from the observer, while the nature of the stimulus reveals a dissociation between MNS -mainly involved in coding for PLD- and MS, recruited by HL moving away. These results suggest that the contribution of the two systems can be modulated by the nature of the observed stimulus and its potential for social involvement.

Published

2017

26. Decoding social intentions in human prehensile actions: Insights from a combined kinematics-fMRI study.

Author

Di Bono MG, Begliomini C, Budisavljevic S, Sartori L, Miotto D, Motta R, and Castiello U

Subjects

Humans, Biomechanical Phenomena, Hand Strength, Magnetic Resonance Imaging methods

Abstract

Consistent evidence suggests that the way we reach and grasp an object is modulated not only by object properties (e.g., size, shape, texture, fragility and weight), but also by the types of intention driving the action, among which the intention to interact with another agent (i.e., social intention). Action observation studies ascribe the neural substrate of this 'intentional' component to the putative mirror neuron (pMNS) and the mentalizing (MS) systems. How social intentions are translated into executed actions, however, has yet to be addressed. We conducted a kinematic and a functional Magnetic Resonance Imaging (fMRI) study considering a reach-to-grasp movement performed towards the same object positioned at the same location but with different intentions: passing it to another person (social condition) or putting it on a concave base (individual condition). Kinematics showed that individual and social intentions are characterized by different profiles, with a slower movement at the level of both the reaching (i.e., arm movement) and the grasping (i.e., hand aperture) components. fMRI results showed that: (i) distinct voxel pattern activity for the social and the individual condition are present within the pMNS and the MS during action execution; (ii) decoding accuracies of regions belonging to the pMNS and the MS are correlated, suggesting that these two systems could interact for the generation of appropriate motor commands. Results are discussed in terms of motor simulation and inferential processes as part of a hierarchical generative model for action intention understanding and generation of appropriate motor commands.

Published

2017

27. Intentional binding as a marker of agency across the lifespan.

Author

Cavazzana A, Begliomini C, and Bisiacchi PS

Subjects

Adult, Aged, Child, Female, Humans, Male, Young Adult, Human Development physiology, Intention, Internal-External Control, Psychomotor Performance physiology

Abstract

The feeling of control over actions and their external effects is known as Sense of Agency (SoAg). People usually have a distinctive SoAg for events caused by their own actions. However, if the agent is a child or an older person, this feeling of being responsible for the consequences of an action may differ from what an adult would feel. The idea would be that children and elderly may have a reduced SoAg since their frontal lobes are developing or have started to loose their efficiency. The aim of this study was to elucidate whether the SoAg changes across lifespan, using the Intentional Binding (i.e., the temporal attraction between a voluntary action and its sensory consequence) as implicit measure. Data show that children and elderly are characterized by a reduced SoAg as compared to adults. These findings provide a fundamental step in the characterization of SoAg dynamics throughout individuals' lifetime., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2017

28. Asymmetry and Structure of the Fronto-Parietal Networks Underlie Visuomotor Processing in Humans.

Author

Budisavljevic S, Dell'Acqua F, Zanatto D, Begliomini C, Miotto D, Motta R, and Castiello U

Subjects

Adult, Brain Mapping, Diffusion Magnetic Resonance Imaging methods, Diffusion Tensor Imaging methods, Humans, Image Processing, Computer-Assisted methods, White Matter physiology, Young Adult, Frontal Lobe physiology, Movement physiology, Nerve Net physiology, Neural Pathways physiology, Parietal Lobe physiology

Abstract

Research in both humans and monkeys has shown that even simple hand movements require cortical control beyond primary sensorimotor areas. An extensive functional neuroimaging literature demonstrates the key role that cortical fronto-parietal regions play for movements such as reaching and reach-to-grasp. However, no study so far has examined the specific white matter connections linking the fronto-parietal regions, namely the 3 parallel pathways of the superior longitudinal fasciculus (SLF). The aim of the current study was to explore how selective fronto-parietal connections are for different kinds of hand movement in 30 right-handed subjects by correlating diffusion imaging tractography and kinematic data. We showed that a common network, consisting of bilateral SLF II and SLF III, was involved in both reaching and reach-to-grasp movements. Larger SLF II and SLF III in the right hemisphere were associated with faster speed of visuomotor processing, while the left SLF II and SLF III played a role in the initial movement trajectory control. Furthermore, the right SLF II was involved in the closing grip phase necessary for efficient grasping of the object. We demonstrated for the first time that individual differences in asymmetry and structure of the fronto-parietal networks were associated with visuomotor processing in humans., (© The Author 2016. Published by Oxford University Press. All rights reserved. For Permissions, please e-mail: journals.permissions@oup.com.)

Published

2017

29. Probing the reaching-grasping network in humans through multivoxel pattern decoding.

Author

Di Bono MG, Begliomini C, Castiello U, and Zorzi M

Subjects

Adult, Female, Hand physiology, Humans, Magnetic Resonance Imaging methods, Male, Motor Cortex physiology, Movement physiology, Occipital Lobe physiology, Parietal Lobe physiology, Psychomotor Performance physiology, Statistics as Topic methods, Brain Mapping methods, Hand Strength physiology, Neural Pathways physiology

Abstract

Introduction: The quest for a putative human homolog of the reaching-grasping network identified in monkeys has been the focus of many neuropsychological and neuroimaging studies in recent years. These studies have shown that the network underlying reaching-only and reach-to-grasp movements includes the superior parieto-occipital cortex (SPOC), the anterior part of the human intraparietal sulcus (hAIP), the ventral and the dorsal portion of the premotor cortex, and the primary motor cortex (M1). Recent evidence for a wider frontoparietal network coding for different aspects of reaching-only and reach-to-grasp actions calls for a more fine-grained assessment of the reaching-grasping network in humans by exploiting pattern decoding methods (multivoxel pattern analysis--MVPA)., Methods: Here, we used MPVA on functional magnetic resonance imaging (fMRI) data to assess whether regions of the frontoparietal network discriminate between reaching-only and reach-to-grasp actions, natural and constrained grasping, different grasp types, and object sizes. Participants were required to perform either reaching-only movements or two reach-to-grasp types (precision or whole hand grasp) upon spherical objects of different sizes., Results: Multivoxel pattern analysis highlighted that, independently from the object size, all the selected regions of both hemispheres contribute in coding for grasp type, with the exception of SPOC and the right hAIP. Consistent with recent neurophysiological findings on monkeys, there was no evidence for a clear-cut distinction between a dorsomedial and a dorsolateral pathway that would be specialized for reaching-only and reach-to-grasp actions, respectively. Nevertheless, the comparison of decoding accuracy across brain areas highlighted their different contributions to reaching-only and grasping actions., Conclusions: Altogether, our findings enrich the current knowledge regarding the functional role of key brain areas involved in the cortical control of reaching-only and reach-to-grasp actions in humans, by revealing novel fine-grained distinctions among action types within a wide frontoparietal network.

Published

2015

30. Neural underpinnings of the 'agent brain': new evidence from transcranial direct current stimulation.

Author

Cavazzana A, Penolazzi B, Begliomini C, and Bisiacchi PS

Subjects

Adult, Auditory Cortex physiology, Female, Humans, Intention, Male, Young Adult, Motor Cortex physiology, Self Efficacy, Transcranial Direct Current Stimulation

Abstract

Intentional binding (IB) refers to the temporal compression between a voluntary action and its sensory effect, and it is considered an implicit measure of sense of agency (SoA), that is, the capacity to control one's own actions. IB has been thoroughly studied from a behavioural point of view but only few studies have investigated its neural underpinnings, always using the same two paradigms. Although providing evidence that the supplementary motor complex is involved, findings are still too scarce to draw definitive conclusions. The aim of the present study was to establish a causal relationship between the pre-supplementary motor area (pre-SMA), known for its key role in action planning and initiation, and IB by means of transcranial direct current stimulation (tDCS). Participants underwent anodal, cathodal and sham control stimulations during three separate sessions (Experiment I). Subsequently, they underwent the same stimulation protocol (Experiment II) using as control a region potentially involved in the processing of the sensory effects of voluntary action (i.e., the right primary auditory cortex for the auditory effects of action). A significant reduction in IB was found only after stimulation of the pre-SMA, which supports the causal contribution of this prefrontal area in the perceived linkage between action and its effects. As SoA could be disrupted in many psychiatric and neurological diseases, these results have direct clinical relevance as tDCS could be successfully used in this domain in virtue of the promising advantages it offers for rehabilitation., (© 2015 Federation of European Neuroscience Societies and John Wiley & Sons Ltd.)

Published

2015

31. Exploring manual asymmetries during grasping: a dynamic causal modeling approach.

Author

Begliomini C, Sartori L, Miotto D, Stramare R, Motta R, and Castiello U

Abstract

Recording of neural activity during grasping actions in macaques showed that grasp-related sensorimotor transformations are accomplished in a circuit constituted by the anterior part of the intraparietal sulcus (AIP), the ventral (F5) and the dorsal (F2) region of the premotor area. In humans, neuroimaging studies have revealed the existence of a similar circuit, involving the putative homolog of macaque areas AIP, F5, and F2. These studies have mainly considered grasping movements performed with the right dominant hand and only a few studies have measured brain activity associated with a movement performed with the left non-dominant hand. As a consequence of this gap, how the brain controls for grasping movement performed with the dominant and the non-dominant hand still represents an open question. A functional magnetic resonance imaging (fMRI) experiment has been conducted, and effective connectivity (dynamic causal modeling, DCM) was used to assess how connectivity among grasping-related areas is modulated by hand (i.e., left and right) during the execution of grasping movements toward a small object requiring precision grasping. Results underlined boosted inter-hemispheric couplings between dorsal premotor cortices during the execution of movements performed with the left rather than the right dominant hand. More specifically, they suggest that the dorsal premotor cortices may play a fundamental role in monitoring the configuration of fingers when grasping movements are performed by either the right and the left hand. This role becomes particularly evident when the hand less-skilled (i.e., the left hand) to perform such action is utilized. The results are discussed in light of recent theories put forward to explain how parieto-frontal connectivity is modulated by the execution of prehensile movements.

Published

2015

32. The left side of motor resonance.

Author

Sartori L, Begliomini C, Panozzo G, Garolla A, and Castiello U

Abstract

Motor resonance is defined as the internal activation of an observer's motor system, specifically attuned to the perceived movement. In social contexts, however, different patterns of observed and executed muscular activation are frequently required. This is the case, for instance, of seeing a key offered with a precision grip and received by opening the hand. Novel evidence suggests that compatibility effects in motor resonance can be altered by social response preparation. What is not known is how handedness modulates this effect. The present study aimed at determining how a left- and a right-handed actor grasping an object and then asking for a complementary response influences corticospinal activation in left- and right-handers instructed to observe the scene. Transcranial magnetic stimulation (TMS)-induced motor evoked potentials (MEPs) were thus recorded from the dominant hands of left- and right-handers. Interestingly, requests posed by the right-handed actor induced a motor activation in the participants' respective dominant hands, suggesting that left-handers tend to mirror right-handers with their most efficient hand. Whereas requests posed by the left-handed actor activated the anatomically corresponding muscles (i.e., left hand) in all the participants, right-handers included. Motor resonance effects classically reported in the literature were confirmed when observing simple grasping actions performed by the right-handed actor. These findings indicate that handedness influences both congruent motor resonance and complementary motor preparation to observed actions.

Published

2014

33. An investigation of the neural circuits underlying reaching and reach-to-grasp movements: from planning to execution.

Author

Begliomini C, De Sanctis T, Marangon M, Tarantino V, Sartori L, Miotto D, Motta R, Stramare R, and Castiello U

Abstract

Experimental evidence suggests the existence of a sophisticated brain circuit specifically dedicated to reach-to-grasp planning and execution, both in human and non-human primates (Castiello, 2005). Studies accomplished by means of neuroimaging techniques suggest the hypothesis of a dichotomy between a "reach-to-grasp" circuit, involving the anterior intraparietal area, the dorsal and ventral premotor cortices (PMd and PMv - Castiello and Begliomini, 2008; Filimon, 2010) and a "reaching" circuit involving the medial intraparietal area and the superior parieto-occipital cortex (Culham et al., 2006). However, the time course characterizing the involvement of these regions during the planning and execution of these two types of movements has yet to be delineated. A functional magnetic resonance imaging study has been conducted, including reach-to-grasp and reaching only movements, performed toward either a small or a large stimulus, and Finite Impulse Response model (Henson, 2003) was adopted to monitor activation patterns from stimulus onset for a time window of 10 s duration. Data analysis focused on brain regions belonging either to the reaching or to the grasping network, as suggested by Castiello and Begliomini (2008). Results suggest that reaching and grasping movements planning and execution might share a common brain network, providing further confirmation to the idea that the neural underpinnings of reaching and grasping may overlap in both spatial and temporal terms (Verhagen et al., 2013). But, although responsive for both actions, they show a significant predominance for either one of the two actions and such a preference is evident on a temporal scale.

Published

2014

34. Intentional binding effect in children: insights from a new paradigm.

Author

Cavazzana A, Begliomini C, and Bisiacchi PS

Abstract

Intentional binding (IB) refers to the temporal attraction between a voluntary action and its sensory consequence. Since its discovery in 2002, it has been considered to be a valid implicit measure of sense of agency (SoA), since it only occurs in the context of voluntary actions. The vast majority of studies considering IB have recruited young adults as participants, while neglecting possible age-related differences. The aim of the present work is to study the development of IB in 10-year-old children. In place of Libet's classical clock method, we decided to implement a new and more suitable paradigm in order to study IB, since children could have some difficulties in dealing with reading clocks. A stream of unpredictable letters was therefore used: participants had to remember which letter was on the screen when they made a voluntary action, heard a sound, or felt their right index finger moved down passively. In Experiment I, a group of young adults was tested in order to replicate the IB effect with this new paradigm. In Experiment II, the same paradigm was then administered to children in order to investigate whether such an effect has already emerged at this age. The data from Experiment I showed the presence of the IB effect in adults. However, Experiment II demonstrated a clear reduction of IB. The comparison of the two groups revealed that the young adult group differed from the children, showing a significantly stronger linkage between actions and their consequences. The results indicate a developmental trend in the IB effect. This finding is discussed in light of the maturation process of the frontal cortical network.

Published

2014

35. Object size modulates fronto-parietal activity during reaching movements.

Author

Tarantino V, De Sanctis T, Straulino E, Begliomini C, and Castiello U

Subjects

Adult, Biomechanical Phenomena, Electroencephalography, Event-Related Potentials, P300, Female, Humans, Male, Nerve Net physiology, Young Adult, Frontal Lobe physiology, Movement physiology, Parietal Lobe physiology, Psychomotor Performance physiology, Space Perception physiology

Abstract

In both monkeys and humans, reaching-related sensorimotor transformations involve the activation of a wide fronto-parietal network. Recent neurophysiological evidence suggests that some components of this network host not only neurons encoding the direction of arm reaching movements, but also neurons whose involvement is modulated by the intrinsic features of an object (e.g. size and shape). To date, it has yet to be investigated whether a similar modulation is evident in the human reaching-related areas. To fill this gap, we asked participants to reach towards either a small or a large object while kinematic and electroencephalographic signals were recorded. Behavioral results showed that the precision requirements were taken into account and the kinematics of reaching was modulated depending on the object size. Similarly, reaching-related neural activity at the level of the posterior parietal and premotor cortices was modulated by the level of accuracy determined by object size. We therefore conclude that object size is engaged in the neural computations for reach planning and execution, consistent with the results from physiological studies in non-human primates., (© 2014 Federation of European Neuroscience Societies and John Wiley & Sons Ltd.)

Published

2014

36. Co-registering kinematics and evoked related potentials during visually guided reach-to-grasp movements.

Author

De Sanctis T, Tarantino V, Straulino E, Begliomini C, and Castiello U

Subjects

Adult, Biomechanical Phenomena, Brain Mapping, Female, Hand physiology, Humans, Male, Movement physiology, Evoked Potentials, Motor physiology, Hand Strength physiology, Motor Cortex physiology, Parietal Lobe physiology, Psychomotor Performance physiology

Abstract

Background: In non-human primates grasp-related sensorimotor transformations are accomplished in a circuit involving the anterior intraparietal sulcus (area AIP) and both the ventral and the dorsal sectors of the premotor cortex (vPMC and dPMC, respectively). Although a human homologue of such a circuit has been identified, the time course of activation of these cortical areas and how such activity relates to specific kinematic events has yet to be investigated., Methodology/principal Findings: We combined kinematic and event-related potential techniques to explicitly test how activity within human grasping-related brain areas is modulated in time. Subjects were requested to reach towards and grasp either a small stimulus using a precision grip (i.e., the opposition of index finger and thumb) or a large stimulus using a whole hand grasp (i.e., the flexion of all digits around the stimulus). Results revealed a time course of activation starting at the level of parietal regions and continuing at the level of premotor regions. More specifically, we show that activity within these regions was tuned for specific grasps well before movement onset and this early tuning was carried over--as evidenced by kinematic analysis--during the preshaping period of the task., Conclusions/significance: Data are discussed in terms of recent findings showing a marked differentiation across different grasps during premovement phases which was carried over into subsequent movement phases. These findings offer a substantial contribution to the current debate about the nature of the sensorimotor transformations underlying grasping. And provide new insights into the detailed movement information contained in the human preparatory activity for specific hand movements.

Published

2013

37. Motor resonance in left- and right-handers: evidence for effector-independent motor representations.

Author

Sartori L, Begliomini C, and Castiello U

Abstract

The idea of motor resonance was born at the time that it was demonstrated that cortical and spinal pathways of the motor system are specifically activated during both action-observation and execution. What is not known is if the human action observation-execution matching system simulates actions through motor representations specifically attuned to the laterality of the observed effectors (i.e., effector-dependent representations) or through abstract motor representations unconnected to the observed effector (i.e., effector-independent representations). To answer that question we need to know how the information necessary for motor resonance is represented or integrated within the representation of an effector. Transcranial magnetic stimulation (TMS)-induced motor evoked potentials (MEPs) were thus recorded from the dominant and non-dominant hands of left- and right-handed participants while they observed a left- or a right-handed model grasping an object. The anatomical correspondence between the effector being observed and the observer's effector classically reported in the literature was confirmed by the MEP response in the dominant hand of participants observing models with their same hand preference. This effect was found in both left- as well as in right-handers. When a broader spectrum of options, such as actions performed by a model with a different hand preference, was instead considered, that correspondence disappeared. Motor resonance was noted in the observer's dominant effector regardless of the laterality of the hand being observed. This would indicate that there is a more sophisticated mechanism which works to convert someone else's pattern of movement into the observer's optimal motor commands and that effector-independent representations specifically modulate motor resonance.

Published

2013

38. Social grasping: from mirroring to mentalizing.

Author

Becchio C, Cavallo A, Begliomini C, Sartori L, Feltrin G, and Castiello U

Subjects

Adult, Biomechanical Phenomena, Competitive Behavior, Cooperative Behavior, Female, Humans, Magnetic Resonance Imaging, Male, Models, Neurological, Social Environment, Stereotaxic Techniques, Young Adult, Hand Strength physiology, Mirror Neurons physiology, Social Behavior, Theory of Mind physiology

Abstract

Because the way we grasp an object varies depending on the intention with which the object is grasped, monitoring the properties of prehensile movements may provide access to a person's intention. Here we investigate the role of visual kinematics in the implicit coding of intention, by using functional brain imaging while participants observed grasping movements performed with social versus individual intents. The results show that activation within the mirror system is stronger during the observation of socially intended movements relative to individual movements. Moreover, areas that form the mentalizing system are more active during social grasping movements. These findings demonstrate that, in the absence of context information, social information conveyed by action kinematics modulates intention processing, leading to a transition from mirroring to mentalizing., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

39. Volitional control of anterior insula activity modulates the response to aversive stimuli. A real-time functional magnetic resonance imaging study.

Author

Caria A, Sitaram R, Veit R, Begliomini C, and Birbaumer N

Subjects

Data Collection methods, Humans, Neuropsychological Tests, Oxygen physiology, Oxygen Consumption, Psychology, Experimental, Time Factors, Brain Mapping methods, Cerebral Cortex physiology, Magnetic Resonance Imaging, Volition

Abstract

Background: A promising new approach to cognitive neuroscience based on real-time functional magnetic resonance imaging (rtfMRI) demonstrated that the learned regulation of the neurophysiological activity in circumscribed brain regions can be used as an independent variable to observe its effects on behavior. Here, for the first time, we investigated the modulatory effect of learned regulation of blood oxygenation level-dependent (BOLD) response in the left anterior insula on the perception of visual emotional stimuli., Methods: Three groups of participants (n = 27) were tested: two underwent four rtfMRI training sessions receiving either specific (n = 9) or unspecific feedback (n = 9) of the insula's BOLD response, respectively, and one group used emotional imagery alone (n = 9) without rtfMRI feedback. During training, all groups were required to assess aversive and neutral pictures., Results: Participants able to significantly increase BOLD signal in the target region rated the aversive pictures more negatively. We measured a significant correlation between enhanced left anterior insula activity and increased negative valence ratings of the aversive stimuli. Control groups performing either rtfMRI training with unspecific feedback or an emotional imagery training alone were not able to significantly enhance activity in the left anterior insula and did not show changes in subjective emotional responses., Conclusions: This study corroborates traditional neuroimaging studies demonstrating a critical role of the anterior insula in the explicit appraisal of emotional stimuli and indicates the adopted approach as a potential tool for clinical applications in emotional disorders., (Copyright 2010 Society of Biological Psychiatry. Published by Elsevier Inc. All rights reserved.)

Published

2010

40. When ears drive hands: the influence of contact sound on reaching to grasp.

Author

Castiello U, Giordano BL, Begliomini C, Ansuini C, and Grassi M

Subjects

Adult, Biomechanical Phenomena, Female, Fingers physiology, Humans, Male, Photic Stimulation, Ear, Hand physiology, Hand Strength physiology, Sound

Abstract

Background: Most research on the roles of auditory information and its interaction with vision has focused on perceptual performance. Little is known on the effects of sound cues on visually-guided hand movements., Methodology/principal Findings: We recorded the sound produced by the fingers upon contact as participants grasped stimulus objects which were covered with different materials. Then, in a further session the pre-recorded contact sounds were delivered to participants via headphones before or following the initiation of reach-to-grasp movements towards the stimulus objects. Reach-to-grasp movement kinematics were measured under the following conditions: (i) congruent, in which the presented contact sound and the contact sound elicited by the to-be-grasped stimulus corresponded; (ii) incongruent, in which the presented contact sound was different to that generated by the stimulus upon contact; (iii) control, in which a synthetic sound, not associated with a real event, was presented. Facilitation effects were found for congruent trials; interference effects were found for incongruent trials. In a second experiment, the upper and the lower parts of the stimulus were covered with different materials. The presented sound was always congruent with the material covering either the upper or the lower half of the stimulus. Participants consistently placed their fingers on the half of the stimulus that corresponded to the presented contact sound., Conclusions/significance: Altogether these findings offer a substantial contribution to the current debate about the type of object representations elicited by auditory stimuli and on the multisensory nature of the sensorimotor transformations underlying action.

Published

2010

41. Coding observed motor acts: different organizational principles in the parietal and premotor cortex of humans.

Author

Jastorff J, Begliomini C, Fabbri-Destro M, Rizzolatti G, and Orban GA

Subjects

Adult, Data Interpretation, Statistical, Female, Foot physiology, Functional Laterality physiology, Hand physiology, Hand Strength physiology, Hemodynamics physiology, Humans, Linear Models, Magnetic Resonance Imaging, Male, Mouth physiology, Movement, Nerve Net physiology, Photic Stimulation, Young Adult, Motor Cortex physiology, Parietal Lobe physiology, Visual Perception physiology

Abstract

Understanding actions of conspecifics is a fundamental social ability depending largely on the activation of a parieto-frontal network. Using functional MRI (fMRI), we studied how goal-directed movements (i.e., motor acts) performed by others are coded within this network. In the first experiment, we presented volunteers with video clips showing four different motor acts (dragging, dropping, grasping, and pushing) performed with different effectors (foot, hand, and mouth). We found that the coding of observed motor acts differed between premotor and parietal cortex. In the premotor cortex, they clustered according to the effector used, and in the inferior parietal lobule (IPL), they clustered according to the type of the observed motor act, regardless of the effector. Two subsequent experiments in which we directly contrasted these four motor acts indicated that, in IPL, the observed motor acts are coded according to the relationship between agent and object: Movements bringing the object toward the agent (grasping and dragging) activate a site corresponding approximately to the ventral part of the putative human AIP (phAIP), whereas movements moving the object away from the agent (pushing and dropping) are clustered dorsally within this area. These data provide indications that the phAIP region plays a role in categorizing motor acts according to their behavioral significance. In addition, our results suggest that in the case of motor acts typically done with the hand, the representations of such acts in phAIP are used as templates for coding motor acts executed with other effectors.

Published

2010

42. The motor somatotopy of speech perception.

Author

D'Ausilio A, Pulvermüller F, Salmas P, Bufalari I, Begliomini C, and Fadiga L

Subjects

Humans, Lip, Magnetic Resonance Imaging, Motor Cortex anatomy & histology, Tongue, Transcranial Magnetic Stimulation, Brain Mapping, Motor Cortex physiology, Speech physiology, Speech Perception physiology

Abstract

Listening to speech recruits a network of fronto-temporo-parietal cortical areas. Classical models consider anterior (motor) sites to be involved in speech production whereas posterior sites are considered to be involved in comprehension. This functional segregation is challenged by action-perception theories suggesting that brain circuits for speech articulation and speech perception are functionally dependent. Although recent data show that speech listening elicits motor activities analogous to production, it's still debated whether motor circuits play a causal contribution to the perception of speech. Here we administered transcranial magnetic stimulation (TMS) to motor cortex controlling lips and tongue during the discrimination of lip- and tongue-articulated phonemes. We found a neurofunctional double dissociation in speech sound discrimination, supporting the idea that motor structures provide a specific functional contribution to the perception of speech sounds. Moreover, our findings show a fine-grained motor somatotopy for speech comprehension. We discuss our results in light of a modified "motor theory of speech perception" according to which speech comprehension is grounded in motor circuits not exclusively involved in speech production.

Published

2009

43. The cortical control of visually guided grasping.

Author

Castiello U and Begliomini C

Subjects

Animals, Brain Mapping, Humans, Photic Stimulation, Psychomotor Performance, Attention physiology, Cerebral Cortex physiology, Hand Strength physiology, Visual Perception physiology

Abstract

People have always been fascinated by the exquisite precision and flexibility of the human hand. When hand meets object, we confront the overlapping worlds of sensorimotor and cognitive functions. The complex apparatus of the human hand is used to reach for objects, grasp and lift them, manipulate them, and use them to act on other objects. This review examines what is known about the control of the hand by the cerebral cortex. It compares and summarizes results from behavioral neuroscience, electrophysiology, and neuroimaging to provide a detailed description of the neural circuits that facilitate the formation of grip patterns in human and nonhuman primates.

Published

2008

44. Cortical activations in humans grasp-related areas depend on hand used and handedness.

Author

Begliomini C, Nelini C, Caria A, Grodd W, and Castiello U

Subjects

Adult, Analysis of Variance, Animals, Behavior physiology, Brain Mapping, Cerebellum physiology, Female, Humans, Magnetic Resonance Imaging, Male, Primates, Cerebral Cortex anatomy & histology, Cerebral Cortex physiology, Functional Laterality physiology, Hand physiology

Abstract

Background: In non-human primates grasp-related sensorimotor transformations are accomplished in a circuit involving the anterior intraparietal sulcus (area AIP) and both the ventral and the dorsal sectors of the premotor cortex (vPMC and dPMC, respectively). Although a human homologue of such a circuit has been identified whether activity within this circuit varies depending on handedness has yet to be investigated., Methodology/principal Findings: We used functional magnetic resonance imaging (fMRI) to explicitly test how handedness modulates activity within human grasping-related brain areas. Right- and left-handers subjects were requested to reach towards and grasp an object with either the right or the left hand using a precision grip while scanned. A kinematic study was conducted with similar procedures as a behavioral counterpart for the fMRI experiment. Results from a factorial design revealed significant activity within the right dPMC, the right cerebellum and AIP bilaterally. The pattern of activity within these areas mirrored the results found for the behavioral study., Conclusion/significance: Data are discussed in terms of an handedness-independent role for the right dPMC in monitoring hand shaping, the need for bilateral AIP activity for the performance of precision grip movements which varies depending on handedness and the involvement of the cerebellum in terms of its connections with AIP. These results provide the first compelling evidence of specific grasping related neural activity depending on handedness.

Published

2008

45. Comparing natural and constrained movements: new insights into the visuomotor control of grasping.

Author

Begliomini C, Caria A, Grodd W, and Castiello U

Subjects

Adult, Biomechanical Phenomena, Brain Mapping methods, Female, Hand, Humans, Magnetic Resonance Imaging, Male, Models, Biological, Motor Cortex, Motor Skills, Visual Perception, Hand Strength, Movement, Neurophysiology methods

Abstract

Background: Neurophysiological studies showed that in macaques, grasp-related sensorimotor transformations are accomplished in a circuit connecting the anterior intraparietal sulcus (area AIP) with premotor area F5. Single unit recordings of macaque indicate that activity of neurons in this circuit is not simply linked to any particular object. Instead, responses correspond to the final hand configuration used to grasp the object. Although a human homologue of such a circuit has been identified, its role in planning and controlling different grasp configurations has not been decisively shown. We used functional magnetic resonance imaging to explicitly test whether activity within this network varies depending on the congruency between the adopted grasp and the grasp called by the stimulus., Methodology/principal Findings: Subjects were requested to reach towards and grasp a small or a large stimulus naturally (i.e., precision grip, involving the opposition of index finger and thumb, for a small size stimulus and a whole hand grasp for a larger stimulus) or with an constrained grasp (i.e., a precision grip for a large stimulus and a whole hand grasp for a small stimulus). The human anterior intraparietal sulcus (hAIPS) was more active for precise grasping than for whole hand grasp independently of stimulus size. Conversely, both the dorsal premotor cortex (dPMC) and the primary motor cortex (M1) were modulated by the relationship between the type of grasp that was adopted and the size of the stimulus., Conclusions/significance: The demonstration that activity within the hAIPS is modulated according to different types of grasp, together with the evidence in humans that the dorsal premotor cortex is involved in grasp planning and execution offers a substantial contribution to the current debate about the neural substrates of visuomotor grasp in humans.

Published

2007

46. Differential cortical activity for precision and whole-hand visually guided grasping in humans.

Author

Begliomini C, Wall MB, Smith AT, and Castiello U

Subjects

Adult, Cerebral Cortex blood supply, Female, Humans, Image Processing, Computer-Assisted, Magnetic Resonance Imaging methods, Male, Motor Cortex blood supply, Motor Cortex physiology, Oxygen metabolism, Photic Stimulation, Somatosensory Cortex blood supply, Somatosensory Cortex physiology, Attention physiology, Brain Mapping, Cerebral Cortex physiology, Hand Strength physiology, Motor Skills physiology

Abstract

Effective grasping involves the remarkable ability to implement multiple grasp configurations such as precision grip (PG; opposition between the index finger and thumb) and whole-hand grasp (WHG), depending on the properties of the object grasped (e.g. size, shape and weight). In the monkey brain, different groups of cells in the anterior-lateral bank of the intraparietal sulcus (area AIP) are differentially active for various hand configurations during grasping of differently shaped objects. Visually guided grasping studies in humans suggest the anterior intraparietal sulcus (aIPS) as the homologue of macaque area AIP, but leave unresolved the question of whether activity in human aIPS reflects the relationship between object size and grasp configuration, as in macaques. To address this issue, a human fMRI study was conducted in which objects were grasped with the right hand while object size was varied. The results indicated that the left aIPS was active when the subjects naturally adopted a PG to grasp the small object but showed a much weaker response when subjects naturally adopted a WHG to grasp the large object. The primary motor cortex and somatosensory cortices were active for both PG and WHG. Our results suggest that, in humans, the aIPS is centrally involved in determining the type of grasp.

Published

2007