Prefrontal cortex and basal ganglia contributions to visual working memory

Voytek, Bradley; Knight, Robert T.

doi:10.1073/pnas.1007277107

Cited by 171 publications

(132 citation statements)

References 55 publications

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“…The bottleneck begins in posterior cortex where neural receptive fields are more restricted to one hemifield than in prefrontal cortex. Human studies report varying degrees of hemifield independence (24)(25)(26)(27). In our task, the need to localize the changed object may emphasize this independence.…”

Section: Discussionmentioning

confidence: 99%

Neural substrates of cognitive capacity limitations

Buschman

Siegel

Roy

et al. 2011

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

283

305

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Cognition has a severely limited capacity: Adult humans can retain only about four items "in mind". This limitation is fundamental to human brain function: Individual capacity is highly correlated with intelligence measures and capacity is reduced in neuropsychiatric diseases. Although human capacity limitations are well studied, their mechanisms have not been investigated at the single-neuron level. Simultaneous recordings from monkey parietal and frontal cortex revealed that visual capacity limitations occurred immediately upon stimulus encoding and in a bottom-up manner. Capacity limitations were found to reflect a dual model of working memory. The left and right halves of visual space had independent capacities and thus are discrete resources. However, within each hemifield, neural information about successfully remembered objects was reduced by adding further objects, indicating that resources are shared. Together, these results suggest visual capacity limitation is due to discrete, slot-like, resources, each containing limited pools of neural information that can be divided among objects.slot model | interference model | attention | hemisphere D espite the remarkable power and flexibility of human cognition, our working memory-the "online" workspace that most cognitive mechanisms depend upon-is surprisingly limited. An average adult human has a capacity to retain only four items at a given time (1-3). This capacity is fundamental to cognition: Individual variability in capacity is highly correlated with fluid intelligence (4-6) and patients with neuropsychiatric disorders often have a reduced capacity (7,8). Because it is so basic to cognition, capacity limitation has been well studied in humans (9), particularly the capacity limitation of visual shortterm working memory (for reviews see refs. 1 and 4). This work has led to several competing theories about the neural basis of capacity limitations. "Discrete" models suggest that capacity limitations reflect a limit in the number of objects that can be simultaneously represented (3, 10, 11). "Flexible resource" models predict that only the total amount of information available is limited, with information divided among all represented objects (12)(13)(14). It is also not clear whether the limitation is in stimulus encoding or in maintenance (15).To better understand the neural basis of capacity limitations we simultaneously recorded from single neurons in the prefrontal and parietal cortex of two monkeys trained to perform a typical human test of cognitive capacity: change localization (Fig. 1A). Two arrays of objects (colored squares) were separated by a short memory delay. In the second array, the color of a randomly chosen object (the target) was changed. Monkeys were trained to detect this change and make a saccade to it. Cognitive load was increased by varying the number of objects in the arrays from two to five. We recorded simultaneously from multiple electrodes in the frontal cortex [lateral prefrontal cortex (LPFC) and frontal eye fields (FEF)] and ...

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Section: Discussionmentioning

confidence: 99%

Neural substrates of cognitive capacity limitations

Buschman

Siegel

Roy

et al. 2011

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

283

305

View full text Add to dashboard Cite

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“…The observation that this "filter activity" was associated with interindividual differences in WM capacity suggests that frontal areas and basal ganglia exert top-down control over WM representations. Evidence from recent clinical studies further underlines the relevance of an intact PFC and basal ganglia for WM performance (Baier et al, 2010;Voytek and Knight, 2010). Thus, top-down control over information selectively encoded and maintained seems to be closely related to a fronto-parietal and fronto-striatal network.…”

Section: Functional Neuroanatomy Of the Working Memory Networkmentioning

confidence: 99%

“…In a recent study investigating patients with unilateral PFC lesions, load modulations of the CDA were only observed ipsilesional, but not contralesional (Voytek and Knight, 2010). The authors suggested that PFC lesions lead to a loss in top-down facilitation contributing to WM performance.…”

Section: The Interplay Of the Two Components Across The Lifespan Reflmentioning

confidence: 99%

Lifespan age differences in working memory: A two-component framework

Sander

Lindenberger

Werkle‐Bergner

2012

Neuroscience & Biobehavioral Reviews

134

101

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a b s t r a c tWe suggest that working memory (WM) performance can be conceptualized as the interplay of low-level feature binding processes and top-down control, relating to posterior and frontal brain regions and their interaction in a distributed neural network. We propose that due to age-differential trajectories of posterior and frontal brain regions top-down control processes are not fully mature until young adulthood and show marked decline with advancing age, whereas binding processes are relatively mature in children, but show senescent decline in older adults. A review of the literature spanning from middle childhood to old age shows that binding and top-down control processes undergo profound changes across the lifespan. We illustrate commonalities and dissimilarities between children, younger adults, and older adults reflecting the change in the two components' relative contribution to visual WM performance across the lifespan using results from our own lab. We conclude that an integrated account of visual WM lifespan changes combining research from behavioral neuroscience and cognitive psychology of child development as well as aging research opens avenues to advance our understanding of cognition in general.

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“…It, in turn, gets input from the cerebral cortex (42). Striatum is best known for its role in the planning and modulation of movement pathways but is also potentially involved in a wide variety of cognitive processes including executive function, such as working memory, cognitive flexibility, and habit formation (43).…”

Section: Striatummentioning

confidence: 99%

Understanding the mechanisms of cognitive impairments in developmental coordination disorder

Deng

Ding

et al. 2013

Pediatr Res

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Developmental coordination disorder (DCD), a neurodevelopmental disability in which a child's motor coordination difficulties significantly interfere with activities of daily life or academic achievement, together with additional symptoms of diseases with childhood sensorimotor impairments, increases the risk of many cognitive problems. This exhibits the dynamic interplay between sensorimotor and cognition systems. However, the brain structures and pathways involved have remained unknown over the past decades. Here, we review developments in recent years that elucidate the neural mechanisms involved in the sensorimotor-cognitive difficulties. First, we briefly address the clinical and epidemiological discoveries in DCD as well as its comorbidities. Subsequently, we group the growing evidence including our findings that support the notion that sensorimotor manipulation indeed affects the cognition development at systematic, circuitry, cellular, and molecular levels. This corresponds to changes in diverse brain regions, synaptic plasticity, and neurotransmitter and receptor activity during development under these effects. Finally, we address the treatment potentials of task-oriented sensorimotor enhancement, as a new therapeutic strategy for cognitive rehabilitation, based on our current understanding of the neurobiology of cognitive-sensorimotor interaction.

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Prefrontal cortex and basal ganglia contributions to visual working memory

Cited by 171 publications

References 55 publications

Neural substrates of cognitive capacity limitations

Neural substrates of cognitive capacity limitations

Lifespan age differences in working memory: A two-component framework

Understanding the mechanisms of cognitive impairments in developmental coordination disorder

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