Cortical connectivity after subcortical stroke assessed with functional magnetic resonance imaging

Grefkes, Christian; Nowak, Dennis A.; Eickhoff, Simon B.; Dafotakis, Manuel; Küst, Jutta; Karbe, H.; Fink, Gereon R.

doi:10.1002/ana.21228

Cited by 524 publications

(513 citation statements)

References 35 publications

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“…Alterations in down-stream, higher cortical areas, not directly affected by the lesion, were already demonstrated by gene expression studies [42] and single-unit recordings in animal models [43,44], as well as MEG [45] and fMRI studies in humans [20,[46][47][48][49][50][51][52]. This is in line with findings from motor [53,54] and attentional systems [55] where lesion-induced network modifications have been increasingly recognized and appreciated. However, the behavioral correlates of network alterations are still poorly understood in all systems.…”

Section: Global Effect Of Visual System Lesionssupporting

confidence: 77%

The second face of blindness: Processing speed deficits in the intact visual field after pre- and post-chiasmatic lesions

Bola

Gall

Sabel

2013

Journal of the Neurological Sciences

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Purpose: Damage along the visual pathway results in a visual field defect (scotoma), which retinotopically corresponds to the damaged neural tissue. Other parts of the visual field, processed by the uninjured tissue, are considered to be intact. However, perceptual deficits have been observed in the ''intact'' visual field, but these functional impairments are poorly understood. We now studied temporal processing deficits in the intact visual field of patients with either pre-or postchiasmatic lesions to better understand the functional consequences of partial blindness.Methods: Patients with pre-(n = 53) or post-chiasmatic lesions (n = 98) were tested with high resolution perimetry -a method used to map visual fields with supra-threshold light stimuli. Reaction time of detections in the intact visual field was then analyzed as an indicator of processing speed and correlated with features of the visual field defect.

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Section: Global Effect Of Visual System Lesionssupporting

confidence: 77%

The second face of blindness: Processing speed deficits in the intact visual field after pre- and post-chiasmatic lesions

Bola

Gall

Sabel

2013

Journal of the Neurological Sciences

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“…We demonstrate state-dependent and timing-dependent, topographically specific bidirectional Hebbian-like associative plasticity in the SMA-M1 network. Recent studies showed a significant role of effective coupling of neuronal activity in the SMA-M1 network for motor outcome in patients after stroke (Grefkes et al, 2008(Grefkes et al, , 2010. In this context, the present study may signify therapeutic potential to support purposeful modification of coupling in the SMA-M1 network in neurological disorders in which dysfunction of this network contributes to the clinical impairment.…”

Section: Introductionmentioning

confidence: 53%

State-Dependent and Timing-Dependent Bidirectional Associative Plasticity in the Human SMA-M1 Network

Arai¹,

Müller‐Dahlhaus²,

Murakami³

et al. 2011

J. Neurosci.

116

111

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The supplementary motor area (SMA-proper) plays a key role in the preparation and execution of voluntary movements. Anatomically, SMA-proper is densely reciprocally connected to primary motor cortex (M1), but neuronal coordination within the SMA-M1 network and its modification by external perturbation are not well understood. Here we modulated the SMA-M1 network using MR-navigated multicoil associative transcranial magnetic stimulation in healthy subjects. Changes in corticospinal excitability were assessed by recording motor evoked potential (MEP) amplitude bilaterally in a hand muscle. We found timing-dependent bidirectional Hebbian-like MEP changes during and for at least 30 min after paired associative SMA-M1 stimulation. MEP amplitude increased if SMA stimulation preceded M1 stimulation by 6 ms, but decreased if SMA stimulation lagged M1 stimulation by 15 ms. This associative plasticity in the SMA-M1 network was highly topographically specific because paired associative stimulation of pre-SMA and M1 did not result in any significant MEP change. Furthermore, associative plasticity in the SMA-M1 network was strongly state-dependent because it required priming by near-simultaneous M1 stimulation to occur. We conclude that timing-dependent bidirectional associative plasticity is demonstrated for the first time at the systems level of a human corticocortical neuronal network. The properties of this form of plasticity are fully compatible with spike-timing-dependent plasticity as defined at the cellular level. The necessity of priming may reflect the strong interhemispheric connectivity of the SMA-M1 network. Findings are relevant for better understanding reorganization and potentially therapeutic modification of neuronal coordination in the SMA-M1 network after cerebral lesions such as stroke.

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“…The dynamic causal modeling (DCM) is a hypothesis-driven approach, which was specifically designed to evaluate the intrinsic and task-dependent influences that a particular brain area exerts over the activity of another area (Friston, 2003;Stephan et al, 2004;Grefkes et al, 2008). The DCM treats the brain as a deterministic system, in which external input causes changes in neural activity that, in turn, lead to changes in the fMRI signal.…”

Section: Methodological Considerations For the Evaluation Of Effectivmentioning

confidence: 99%

Asymmetric control mechanisms of bimanual coordination: An application of directed connectivity analysis to kinematic and functional MRI data

Maki¹,

Wong²,

Sugiura³

et al. 2008

NeuroImage

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Mirror-symmetrical bimanual movement is more stable than parallel bimanual movement. This is well established at the kinematic level. I used functional MRI (fMRI) to evaluate the neural substrates of the stability of mirror-symmetrical bimanual movement. Right-handed participants (n = 17) rotated disks with their index fingers bimanually, both in mirror-symmetrical and asymmetrical parallel modes. I applied the Akaike causality model to both kinematic and fMRI time-series data. I hypothesized that kinematic stability is represented by the extent of neural "cross-talk": as the fraction of signals that are common to controlling both hands increases, the stability also increases. The standard deviation of the phase difference for the mirror mode was significantly smaller than that for the parallel mode, confirming that the former was more stable. I used the noise-contribution ratio (NCR), which was computed using a multivariate autoregressive model with latent variables, as a direct measure of the cross-talk between both the two hands and the bilateral primary motor cortices (M1s). The mode-by-direction interaction of the NCR was significant in both the kinematic and fMRI data. Furthermore, in both sets of data, the NCR from the right hand to the left was more prominent than vice versa during the mirror-symmetrical mode, whereas no difference was observed during parallel movement or rest. The asymmetric interhemispheric interaction from the left M1 to the right M1 during symmetric bimanual movement might represent cortical-level cross-talk, which contributes to the stability of symmetric bimanual movements.4

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Cortical connectivity after subcortical stroke assessed with functional magnetic resonance imaging

Cited by 524 publications

References 35 publications

The second face of blindness: Processing speed deficits in the intact visual field after pre- and post-chiasmatic lesions

The second face of blindness: Processing speed deficits in the intact visual field after pre- and post-chiasmatic lesions

State-Dependent and Timing-Dependent Bidirectional Associative Plasticity in the Human SMA-M1 Network

Asymmetric control mechanisms of bimanual coordination: An application of directed connectivity analysis to kinematic and functional MRI data

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