Traditionally the motor system was thought of as a movement output device that, after brain damage, can impede patients from correctly planning and executing an action. In the last 20 years neuropsychological observations have contributed to the development of a new view that attributes higher-level functions to this system. Rapidly, this area of investigation has grown very popular, with motor representations being considered critical for action and object recognition, imagery and even language understanding. At present, we can distinguish between embodied and disembodied theories. The former predominantly are built on associations of deficits in these abilities whereas the latter rely on dissociations between deficits. Neuroimaging research has also showed that different action-related functions activate either overlapping or discrete regions, thus sustaining either association-based or dissociation-based models. Although no convincing theory is, to date, available to explain both sets of observations, cognitive neuroscientists have begun to explore this intermediate hypothesis space. Here we suggest that concepts like strategy and simulation seem promising in explaining how the cognitive system alternates between action-related functions.
Higher-level motor processes / Rumiati, Raffaella Ida; Papeo, Liuba; Corradi-Dell'Acqua, Corrado. - In: ANNALS OF THE NEW YORK ACADEMY OF SCIENCES. - ISSN 0077-8923. - 1191:1(2010), pp. 219-241. [10.1111/j.1749-6632.2010.05442.x]
Higher-level motor processes
Papeo, LiubaSecondo
;Corradi-Dell'Acqua, CorradoUltimo
2010-01-01
Abstract
Traditionally the motor system was thought of as a movement output device that, after brain damage, can impede patients from correctly planning and executing an action. In the last 20 years neuropsychological observations have contributed to the development of a new view that attributes higher-level functions to this system. Rapidly, this area of investigation has grown very popular, with motor representations being considered critical for action and object recognition, imagery and even language understanding. At present, we can distinguish between embodied and disembodied theories. The former predominantly are built on associations of deficits in these abilities whereas the latter rely on dissociations between deficits. Neuroimaging research has also showed that different action-related functions activate either overlapping or discrete regions, thus sustaining either association-based or dissociation-based models. Although no convincing theory is, to date, available to explain both sets of observations, cognitive neuroscientists have begun to explore this intermediate hypothesis space. Here we suggest that concepts like strategy and simulation seem promising in explaining how the cognitive system alternates between action-related functions.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione
