Functional clusters in the human parietal cortex as revealed by an observer-independent meta-analysis of functional activation studies

Nickel, Janpeter; Seitz, Rüdiger J.

doi:10.1007/s00429-005-0037-1

Cited by 35 publications

(23 citation statements)

References 65 publications

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“…The apraxia after left parietal damage is often present when using either hand (Alexander et al, 1992;Haaland and Harrington, 1996;Leiguarda and Marsden, 2000;Halsband et al, 2001). Additionally, our results seem to be consistent with a meta-analysis of parietal activation studies (Nickel and Seitz, 2005), which suggests that the left IPL is involved in the handobject interaction, and with Heilman et al (1982), who, based on an analysis of human lesion data, suggested that the inferior parietal lobule (supramarginal gyrus) contains visuokinesthetic representations (i.e., perceptual representations related to the motor performances with objects and tools). The clinical observation that apraxia often coexists with aphasia (De Renzi et al, 1980;Haaland and Flaherty, 1984;Kertesz et al, 1984;Papagno et al, 1993) may reflect that both hand-object interaction and language (Binder et al, 1997;Vikingstad et al, 2000) are lateralized to the left hemisphere.…”

Section: Dominance Of the Left Hemisphere For The Sensation Of Hand-osupporting

confidence: 90%

Somatic Sensation of Hand-Object Interactive Movement Is Associated with Activity in the Left Inferior Parietal Cortex

Naito¹,

Ehrsson²

2006

J. Neurosci.

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Manipulation of objects and tool-use are known to be controlled by a network of frontal motor and parietal areas. Here, we investigate which of these areas are associated with the somatic sensation of hand-object interactive movement using functional magnetic resonance imaging.To dissociate the sensation of movement from the motor control commands, we used a new kinesthetic illusion. Twelve blindfolded right-handed participants placed the palm of their right or left hand on an object (a ball). Simultaneously, we vibrated the tendon of the wrist extensor muscle. This elicited the illusion that the wrist is flexing and the touched object is also moving along with the hand (hand-object illusion). As controls, we vibrated the skin surface over the nearby bone, which does not elicit any illusions, or we vibrated the tendon when the hand did not touch the object, which only generates the illusory flexion of the hand.We found that the hand-object illusion specifically activated the left inferior parietal lobule (IPL) (supramarginal gyrus and parietal operculum, including cytoarchitectonic areas ip1 and op1) and area 44. The left IPL was activated both during the hand-object illusions with the right and left hands, and the activity was greater than in the right corresponding parietal region, suggesting a dominant role of the left hemisphere.We conclude that the left IPL is involved in the somatic perception of hand-object interactive movement and suggest that the underlying mechanism is the somatic integration of internal information about the body and external information about the object.

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Section: Dominance Of the Left Hemisphere For The Sensation Of Hand-osupporting

confidence: 90%

Somatic Sensation of Hand-Object Interactive Movement Is Associated with Activity in the Left Inferior Parietal Cortex

Naito¹,

Ehrsson²

2006

J. Neurosci.

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“…These two suggestions are consistent with the literature. The superior PPC has been shown to be involved in reconfiguring and updating task-set information immediately following a switch in task (Braver et al, 2003) as well as in shifting attention (Andersen and Buneo, 2002;Behrmann et al, 2004;Cavanna and Trimble, 2006;Corbetta and Shulman, 2002), whereas a recent meta-analysis showed consistent right inferior parietal lobule involvement in tasks of working memory and sustained attention (Nickel and Seitz, 2005). The positive correlation between late cue-locked differential positivity and PPC activation is therefore consistent with our argument that, given an informative cue and sufficient time to prepare, C-R rules can be activated prior to stimulus onset.…”

Section: Informatively Cued Switch N Repeat Contrastmentioning

confidence: 97%

The spatial and temporal dynamics of anticipatory preparation and response inhibition in task-switching

et al. 2010

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We investigated ERP and fMRI correlates of anticipatory preparation and response inhibition in a cued task-switching paradigm with informatively cued, non-informatively cued and no-go trials. Cue-locked ERPs showed evidence for a multicomponent preparation process. An early cue-locked differential positivity was larger for informative vs. non-informative cues and its amplitude correlated with differential activity for informatively vs. non-informatively cued trials in the dorsolateral prefrontal cortex (DLPFC), consistent with a goal activation process. A later differential positivity was larger for informatively cued switch vs. repeat trials and its amplitude correlated with informatively cued switch vs. repeat activity in the posterior parietal cortex (PPC), compatible with a category-response (C-R) rule activation process. No-go trials elicited a frontal P3, whose amplitude was negatively correlated with activity in the ventrolateral prefrontal cortex (VLPFC) and basal ganglia motor network, suggesting that a network responsible for response execution was inhibited in the course of a no-go trial. These findings indicate that anticipatory preparation in task-switching is comprised of at least two processes: goal activation and C-R rule activation. They also support a functional dissociation between DLPFC and VLPFC, with the former involved in top-down biasing and the latter involved in response inhibition.

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“…This large variability in the AG may potentially reflect the existence of multiple subdivisions within the AG. Indeed, an increasing literature has defined the AG as an aggregate of multiple subdivisions where each subdivision can be characterized by specific functional and connectivity patterns (e.g., Andrews-Hanna and others 2010; Bahnemann and others 2010; Brownsett and Wise 2010; Caspers and others 2008; Eidelberg and Galaburda 1984; Kim 2010; Mars and others 2011; Naidich and others 1995; Nelson and others 2010; Nickel and Seitz 2005; Price GR and Ansari 2011; Rushworth and others 2006; Seghier and others 2010; Seghier and Price 2009; Sharp and others 2010; Uddin and others 2010; Vandenberghe and Gillebert 2009; Yeo and others 2011). This literature has provided an interesting framework for reporting and interpreting AG activations with greater definition, where each subdivision is allowed to have distinct contributions in a given task.…”

Section: Multiple Subdivisionsmentioning

confidence: 99%

The Angular Gyrus

2012

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There is considerable interest in the structural and functional properties of the angular gyrus (AG). Located in the posterior part of the inferior parietal lobule, the AG has been shown in numerous meta-analysis reviews to be consistently activated in a variety of tasks. This review discusses the involvement of the AG in semantic processing, word reading and comprehension, number processing, default mode network, memory retrieval, attention and spatial cognition, reasoning, and social cognition. This large functional neuroimaging literature depicts a major role for the AG in processing concepts rather than percepts when interfacing perception-to-recognition-to-action. More specifically, the AG emerges as a cross-modal hub where converging multisensory information is combined and integrated to comprehend and give sense to events, manipulate mental representations, solve familiar problems, and reorient attention to relevant information. In addition, this review discusses recent findings that point to the existence of multiple subdivisions in the AG. This spatial parcellation can serve as a framework for reporting AG activations with greater definition. This review also acknowledges that the role of the AG cannot comprehensibly be identified in isolation but needs to be understood in parallel with the influence from other regions. Several interesting questions that warrant further investigations are finally emphasized.

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Functional clusters in the human parietal cortex as revealed by an observer-independent meta-analysis of functional activation studies

Cited by 35 publications

References 65 publications

Somatic Sensation of Hand-Object Interactive Movement Is Associated with Activity in the Left Inferior Parietal Cortex

Somatic Sensation of Hand-Object Interactive Movement Is Associated with Activity in the Left Inferior Parietal Cortex

The spatial and temporal dynamics of anticipatory preparation and response inhibition in task-switching

The Angular Gyrus

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