Task–specific impairments and enhancements induced by magnetic stimulation of human visual area V5

Walsh, Vincent; Ellison, Amanda; Battelli, Lorella; Cowey, Alan

doi:10.1098/rspb.1998.0328

Cited by 189 publications

(127 citation statements)

References 54 publications

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“…The time window (i.e., 60 -75 ms) of these effects is in line with previous studies revealing visual suppression by occipital TMS (Amassian et al, 1989), and is traditionally believed to correspond to the peak of the first volley of feedforward input in visual cortex (Martinez et al, 1999). Although transient disruption of brain function predominates in TMS research, there are also reports of functional improvements (Seyal et al, 1995;Walsh et al, 1998;Hilgetag et al, 2001;Paus, 2002, 2003;Kobayashi et al, 2004;Thut et al, 2005), similar to the RT facilitation we observed. Several studies further showed that stimulation of a given area can induce opposing (disruptive or facilitative) effects depending on task or behavioral context (Walsh et al, 1998;Paus, 2002, 2003).…”

Section: Discussionsupporting

confidence: 75%

“…Although transient disruption of brain function predominates in TMS research, there are also reports of functional improvements (Seyal et al, 1995;Walsh et al, 1998;Hilgetag et al, 2001;Paus, 2002, 2003;Kobayashi et al, 2004;Thut et al, 2005), similar to the RT facilitation we observed. Several studies further showed that stimulation of a given area can induce opposing (disruptive or facilitative) effects depending on task or behavioral context (Walsh et al, 1998;Paus, 2002, 2003). The mechanisms invoked to explain beneficial TMS-effects are a disinhibition of unstimulated brain areas whose function are normally suppressed by the TMS target site (Seyal et al, 1995;Walsh et al, 1998) or a neural priming effect caused by TMS before a critical period Paus, 2002, 2003).…”

Section: Discussionsupporting

confidence: 71%

See 1 more Smart Citation

Occipital Transcranial Magnetic Stimulation Has Opposing Effects on Visual and Auditory Stimulus Detection: Implications for Multisensory Interactions

Romei¹,

Murray²,

Merabet³

et al. 2007

J. Neurosci.

167

119

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Section: Discussionsupporting

confidence: 75%

Section: Discussionsupporting

confidence: 71%

Occipital Transcranial Magnetic Stimulation Has Opposing Effects on Visual and Auditory Stimulus Detection: Implications for Multisensory Interactions

Romei¹,

Murray²,

Merabet³

et al. 2007

J. Neurosci.

167

119

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show abstract

“…The effects of on-line TMS, as used here, can be thought of as transiently introducing neural "noise" into the area stimulated (for review, see Walsh and Cowey, 2000;Walsh and PascualLeone, 2003). Many TMS studies adopting this interference approach have created a variety of "virtual lesions"; that is, behavioral changes mimicking those produced by lesions involving the same region [suppression of visual detection (Amassian et al, 1989), visual extinction (Pascual-Leone et al, 1994), prolongation of visual search (Ashbridge et al, 1997), akinetopsia (Walsh et al, 1998), aspects of spatial neglect (Fierro et al, 2000), or acalculia (Gobel et al, 2001)], thereby allowing tests of functional localization. Note that TMS differs from other types of neural stimulation [e.g., with implanted electrodes (Moore and Armstrong, 2003)] in many respects but can nevertheless similarly modulate a given region transiently to allow inferences about its function.…”

Section: Methodsmentioning

confidence: 99%

Visual Selection and Posterior Parietal Cortex: Effects of Repetitive Transcranial Magnetic Stimulation on Partial Report Analyzed by Bundesen's Theory of Visual Attention

Hung¹,

Driver²,

Walsh³

2005

J. Neurosci.

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Posterior parietal cortex (PPC) may contribute to visual selection by exerting top-down influences on visual processing. To seek direct evidence for this, we used 10 Hz repetitive transcranial magnetic stimulation (rTMS) over right or left PPC in nine healthy volunteers during a partial (selective) report task that allows quantitative assessment of top-down control and other parameters. Participants reported digits in a relevant color ("targets") but not those in an irrelevant color ("nontargets") from a brief masked display, in which a target could appear alone or together with an accompanying item (nontarget or target) in the same or opposite hemifield. Generally, a given target is identified better when presented with a nontarget than with another target, indicating top-down selection of task-relevant targets; this applied here with no rTMS or left PPC rTMS. However, rTMS over the right PPC changed the performance pattern. A left target no longer impeded report of a right target more strongly than did a left nontarget, whereas the greater impact of a right target than a right nontarget in disrupting report of a left target was increased. Formal analysis in terms of Bundesen's (1990) theory of visual attention indicated that right PPC rTMS diminished top-down control for the left hemifield while enhancing this for the right hemifield, particularly for bilateral two-item displays. These findings indicate a role for right PPC in top-down spatial selection, which applies even when the target is defined by a nonspatial property (here color).

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“…Motion perception in particular has proven to be very amenable to study using TMS (Beckers and Hömberg, 1992;Hotson et al, 1994;Beckers and Zeki, 1995;Anand et al, 1998;Walsh et al, 1998;Cowey et al, 2006;Laycock et al, 2007). However, thus far, only one study has specifically examined the effects of TMS to human area V5/MTϩ on the perception of speed (Matthews et al, 2001) and demonstrated that the application of TMS to the lateral occipital cortex can impair performance on speed discrimination tasks.…”

Section: Introductionmentioning

confidence: 99%

Induced Deficits in Speed Perception by Transcranial Magnetic Stimulation of Human Cortical Areas V5/MT+ and V3A

McKeefry¹,

Burton²,

Vakrou³

et al. 2008

Journal of Neuroscience

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In this report, we evaluate the role of visual areas responsive to motion in the human brain in the perception of stimulus speed. We first identified and localized V1, V3A, and V5/MTϩ in individual participants on the basis of blood oxygenation level-dependent responses obtained in retinotopic mapping experiments and responses to moving gratings. Repetitive transcranial magnetic stimulation (rTMS) was then used to disrupt the normal functioning of the previously localized visual areas in each participant. During the rTMS application, participants were required to perform delayed discrimination of the speed of drifting or spatial frequency of static gratings. The application of rTMS to areas V5/MT and V3A induced a subjective slowing of visual stimuli and (often) caused increases in speed discrimination thresholds. Deficits in spatial frequency discrimination were not observed for applications of rTMS to V3A or V5/MTϩ. The induced deficits in speed perception were also specific to the cortical site of TMS delivery. The application of TMS to regions of the cortex adjacent to V5/MT and V3A, as well as to area V1, produced no deficits in speed perception. These results suggest that, in addition to area V5/MTϩ, V3A plays an important role in a cortical network that underpins the perception of stimulus speed in the human brain.

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Task–specific impairments and enhancements induced by magnetic stimulation of human visual area V5

Cited by 189 publications

References 54 publications

Occipital Transcranial Magnetic Stimulation Has Opposing Effects on Visual and Auditory Stimulus Detection: Implications for Multisensory Interactions

Occipital Transcranial Magnetic Stimulation Has Opposing Effects on Visual and Auditory Stimulus Detection: Implications for Multisensory Interactions

Visual Selection and Posterior Parietal Cortex: Effects of Repetitive Transcranial Magnetic Stimulation on Partial Report Analyzed by Bundesen's Theory of Visual Attention

Induced Deficits in Speed Perception by Transcranial Magnetic Stimulation of Human Cortical Areas V5/MT+ and V3A

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