Early coding of reaching: frontal and parietal association connections of parieto‐occipital cortex

Caminiti, Roberto; Genovesio, Aldo; Marconi, Barbara; Battaglia-Mayer, Alexandra; Onorati, Paolo; Ferraina, Stefano; Mitsuda, Takashi; Giannetti, Stefano; Squatrito, Salvatore; Maioli, Maria Grazia; Molinari, Marco

doi:10.1046/j.1460-9568.1999.00801.x

Cited by 94 publications

(64 citation statements)

References 26 publications

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“…LDs of several tens of milliseconds, as seen here and also in previous studies (Riehle, 1991;Kalaska and Crammond, 1992;Johnson et al, 1996;Pesaran et al, 2008), seem rather long to be attributable to transmission delays between the monosynaptically connected areas PMd and PRR (Pandya and Kuypers, 1969;Jones and Powell, 1970;Kurata, 1991;Johnson et al, 1996;Caminiti et al, 1999;Marconi et al, 2001;Tanné-Gariépy et al, 2002;BattagliaMayer et al, 2003). Instead, we prefer to attribute the observed large frontoparietal LDs to the dynamic reorganization of network activity, which is required in visuospatially organized areas like PRR in the case of spatial remapping.…”

Section: Shorter Motor-goal Latencies In Pmd Than Prr In Remapping Cosupporting

confidence: 86%

The Cortical Timeline for Deciding on Reach Motor Goals

Westendorff

Klaes²,

Gail³

2010

J. Neurosci.

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Flexible sensorimotor planning is the basis for goal-directed behavior. We investigated the integration of visuospatial information with context-specific transformation rules during reach planning. We were especially interested in the relative timing of motor-goal decisions in monkey dorsal premotor cortex (PMd) and parietal reach region (PRR). We used a rule-based mapping task with different cueing conditions to compare task-dependent motor-goal latencies. The task allowed us a separation of cue-related from motor-related activity, and a separation of activity related to motor planning from activity related to motor initiation or execution. The results show that selectivity for the visuospatial goal of a pending movement occurred earlier in PMd than PRR whenever the task required spatial remapping. Such remapping was needed if the spatial representation of a cue or of a default motor plan had to be transformed into a spatially incongruent representation of the motor goal. In contrast, we did not find frontoparietal latency differences if the spatial representation of the cue or the default plan was spatially congruent with the motor goal. The fact that frontoparietal latency differences occurred only in conditions with spatial remapping was independent of the subjects' partial a priori knowledge about the pending goal. Importantly, frontoparietal latency differences existed for motor-goal representations during movement planning, without immediate motor execution. We interpret our findings as being in support of the hypothesis that latency differences reflect a dynamic reorganization of network activity in PRR, and suggest that the reorganization is contingent on frontoparietal projections from PMd.

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Section: Shorter Motor-goal Latencies In Pmd Than Prr In Remapping Cosupporting

confidence: 86%

The Cortical Timeline for Deciding on Reach Motor Goals

Westendorff

Klaes²,

Gail³

2010

J. Neurosci.

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“…These and other similarities raise the possibility of a number of homologous areas in PPC of prosimian and anthropoid primates. However, visual inputs to PPC in galagos seem to be largely limited to cortex caudal to the complex movement zones, whereas movement-related zones of VIP, LIP, and PRR of macaques all get inputs from subdivisions of visual cortex (8,10,13,14). Thus, the large posterior parietal region of macaques is also likely to differ in organization in some respects from the much smaller posterior parietal region of galagos.…”

Section: Discussionmentioning

confidence: 99%

“…Because VIP has interconnections with ventral premotor cortex (9)(10)(11)(12), possibly including cortex where the defensive zone of frontal cortex is located, the VIP region and part of premotor cortex may be critical nodes in a network mediating defensive behaviors (2). Furthermore, because PPC, including the intraparietal region, contains a number of proposed subdivisions with differing connection patterns with motor and premotor cortex (9)(10)(11)(12)(13)(14)(15), other parts of PPC might interact with parts of frontal cortex as nodes in systems for various biologically relevant complex behaviors.…”

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confidence: 99%

Microstimulation reveals specialized subregions for different complex movements in posterior parietal cortex of prosimian galagos

Stepniewska

Fang²,

Kaas³

2005

Proc. Natl. Acad. Sci. U.S.A.

176

134

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Posterior parietal cortex of prosimian galagos consists of a caudal half characterized by connections with visual cortex and a rostral half connected with motor, premotor, and visuomotor areas of frontal cortex. When 500-ms trains of electrical pulses were used to stimulate microelectrode sites throughout posterior parietal cortex, movements were elicited only from the rostral half. The movement zone reflected an overall pattern of somatotopy, from eye and face movements most ventrally to hindlimb movements most dorsally. In addition, subregions or zones of this movement cortex seemed to be devoted to components of different, ethologically significant behaviors. Thus, microstimulation within separate zones of cortex elicited reaching, hand-to-mouth, defensive, or aggressive movements. The finding of similar classes of elicited movement patterns from frontal and more recently intraparietal cortex of macaques suggests that multiareal circuits for biologically significant behaviors are components of all primate brains and that these circuits can be activated by long trains of current pulses at rostral locations in posterior parietal cortex.cortical connections ͉ intraparietal cortex ͉ motor cortex ͉ visual cortex

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“…The early learning period was associated with activation of the dorsal and ventral visual streams and the dorsal premotor cortex (Burnod et al 1999;Caminiti and Johnson 1992;Caminiti et al 1996Caminiti et al , 1998Caminiti et al , 1999Lacquaniti et al 1995), and it may reflect the tuning of sensorimotor transformations that map, for example, visuospatial signals into motor commands. The important role of the superior parietal lobule in this graphomotor sequence task is consonant with earlier studies involving graphomotor learning (Seitz et al 1994(Seitz et al , 1997.…”

Section: Successive Recruitment Of Cortical Basal Ganglia and Cerebementioning

confidence: 99%

Neural Substrates of Graphomotor Sequence Learning: A Combined fMRI and Kinematic Study

Swett

Contreras-Vidal

Birn

et al. 2010

Journal of Neurophysiology

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Early coding of reaching: frontal and parietal association connections of parieto‐occipital cortex

Cited by 94 publications

References 26 publications

The Cortical Timeline for Deciding on Reach Motor Goals

The Cortical Timeline for Deciding on Reach Motor Goals

Microstimulation reveals specialized subregions for different complex movements in posterior parietal cortex of prosimian galagos

Neural Substrates of Graphomotor Sequence Learning: A Combined fMRI and Kinematic Study

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