Inhibition of Return Arises from Inhibition of Response Processes: An Analysis of Oscillatory Beta Activity

In the orienting of attention paradigm, inhibition of return (IOR) refers to slowed responses to targets presented at the same location as a preceding stimulus. No consensus has yet been reached regarding the stages of information processing underlying the inhibition. We report the results of an electro-encephalogram experiment designed to examine the involvement of response inhibition in IOR. Using a cue-target design and a target-target design, we addressed the role of response inhibition in a location discrimination task. Event-related changes in beta power were measured because oscillatory beta activity has been shown to be related to motor activity. Bilaterally located sources in the primary motor cortex showed event-related beta desynchronization (ERD) both at cue and target presentation and a rebound to event-related beta synchronization (ERS) after movement execution. In both designs, IOR arose from an enhancement of beta synchrony. IOR was related to an increase of beta ERS in the target-target design and to a decrease of beta ERD in the cue-target design. These results suggest an important role of response inhibition in IOR.

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Cortical and Striatal Electroencephalograms and Apomorphine Effects in the FUS Mouse Model of Amyotrophic Lateral Sclerosis

Journal of Alzheimer s Disease ◽

10.3233/jad-201472 ◽

2021 ◽

pp. 1-15

Author(s):

Vasily Vorobyov ◽

Alexander Deev ◽

Frank Sengpiel ◽

Vladimir Nebogatikov ◽

Aleksey A. Ustyugov

Keyword(s):

Amyotrophic Lateral Sclerosis ◽

Motor Neurons ◽

Cortical Neurons ◽

Primary Motor Cortex ◽

Beta Activity ◽

Systemic Injection ◽

Eeg Spectra ◽

Electroencephalogram Eeg ◽

Lateral Sclerosis

Background: Amyotrophic lateral sclerosis (ALS) is characterized by degeneration of motor neurons resulting in muscle atrophy. In contrast to the lower motor neurons, the role of upper (cortical) neurons in ALS is yet unclear. Maturation of locomotor networks is supported by dopaminergic (DA) projections from substantia nigra to the spinal cord and striatum. Objective: To examine the contribution of DA mediation in the striatum-cortex networks in ALS progression. Methods: We studied electroencephalogram (EEG) from striatal putamen (Pt) and primary motor cortex (M1) in ΔFUS(1–359)-transgenic (Tg) mice, a model of ALS. EEG from M1 and Pt were recorded in freely moving young (2-month-old) and older (5-month-old) Tg and non-transgenic (nTg) mice. EEG spectra were analyzed for 30 min before and for 60 min after systemic injection of a DA mimetic, apomorphine (APO), and saline. Results: In young Tg versus nTg mice, baseline EEG spectra in M1 were comparable, whereas in Pt, beta activity in Tg mice was enhanced. In older Tg versus nTg mice, beta dominated in EEG from both M1 and Pt, whereas theta and delta 2 activities were reduced. In younger Tg versus nTg mice, APO increased theta and decreased beta 2 predominantly in M1. In older mice, APO effects in these frequency bands were inversed and accompanied by enhanced delta 2 and attenuated alpha in Tg versus nTg mice. Conclusion: We suggest that revealed EEG modifications in ΔFUS(1–359)-transgenic mice are associated with early alterations in the striatum-cortex interrelations and DA transmission followed by adaptive intracerebral transformations.

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The Role of Primary Motor Cortex: More Than Movement Execution

Journal of Motor Behavior ◽

10.1080/00222895.2020.1738992 ◽

2020 ◽

pp. 1-17

Author(s):

Sagarika Bhattacharjee ◽

Rajan Kashyap ◽

Turki Abualait ◽

Shen-Hsing Annabel Chen ◽

Woo-Kyoung Yoo ◽

...

Keyword(s):

Motor Cortex ◽

Primary Motor Cortex ◽

Movement Execution

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Inhibition of Return in a Discrimination Task

PsycEXTRA Dataset ◽

10.1037/e537272012-245 ◽

1994 ◽

Cited By ~ 1

Author(s):

Marylou Cheal

Keyword(s):

Discrimination Task ◽

Inhibition Of Return

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The Role of Primary Motor Cortex as a Marker for and Modulator of Pain Control and Emotional-Affective Processing

10.3389/978-2-88945-261-3 ◽

2017 ◽

Keyword(s):

Motor Cortex ◽

Pain Control ◽

Primary Motor Cortex ◽

Affective Processing

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Cortical silent period reflects individual differences in action stopping performance

Scientific Reports ◽

10.1038/s41598-021-94494-w ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Mario Paci ◽

Giulio Di Cosmo ◽

Mauro Gianni Perrucci ◽

Francesca Ferri ◽

Marcello Costantini

Keyword(s):

Individual Differences ◽

Response Inhibition ◽

Primary Motor Cortex ◽

Silent Period ◽

Intracortical Inhibition ◽

Stop Signal ◽

Stop Signal Task ◽

Behavioral Differences ◽

Cortical Silent Period ◽

Stop Signal Reaction Time

AbstractInhibitory control is the ability to suppress inappropriate movements and unwanted actions, allowing to regulate impulses and responses. This ability can be measured via the Stop Signal Task, which provides a temporal index of response inhibition, namely the stop signal reaction time (SSRT). At the neural level, Transcranial Magnetic Stimulation (TMS) allows to investigate motor inhibition within the primary motor cortex (M1), such as the cortical silent period (CSP) which is an index of GABAB-mediated intracortical inhibition within M1. Although there is strong evidence that intracortical inhibition varies during action stopping, it is still not clear whether differences in the neurophysiological markers of intracortical inhibition contribute to behavioral differences in actual inhibitory capacities. Hence, here we explored the relationship between intracortical inhibition within M1 and behavioral response inhibition. GABABergic-mediated inhibition in M1 was determined by the duration of CSP, while behavioral inhibition was assessed by the SSRT. We found a significant positive correlation between CSP’s duration and SSRT, namely that individuals with greater levels of GABABergic-mediated inhibition seem to perform overall worse in inhibiting behavioral responses. These results support the assumption that individual differences in intracortical inhibition are mirrored by individual differences in action stopping abilities.

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The impact of body posture on intrinsic brain activity: The role of beta power at rest

PLoS ONE ◽

10.1371/journal.pone.0218977 ◽

2020 ◽

Vol 15 (1) ◽

pp. e0218977

Author(s):

Brunella Donno ◽

Daniele Migliorati ◽

Filippo Zappasodi ◽

Mauro Gianni Perrucci ◽

Marcello Costantini

Keyword(s):

Brain Activity ◽

Body Posture ◽

Beta Power ◽

Intrinsic Brain Activity ◽

The Impact

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A Direct Assessment of the Role of Expectation in Inhibition of Return

Psychological Science ◽

10.1111/j.1467-9280.2007.01979.x ◽

2007 ◽

Vol 18 (9) ◽

pp. 783-787 ◽

Cited By ~ 6

Author(s):

Thomas M. Spalek

Keyword(s):

Inhibition Of Return ◽

Response Times ◽

Direct Measure ◽

Imaginary Circle ◽

Direct Assessment ◽

Relevant Evidence ◽

Indirect Measures

An object hidden among distractors can be found more efficiently if previously searched locations are not reinspected. The inhibition-of-return (IOR) phenomenon indexes the tendency to avoid reinspections. Two accounts of IOR, that it is due to inhibition and that it is due to expectation, are generally regarded as incompatible. The relevant evidence to date, however, has been indirect: Inhibition or expectation has been inferred from response times or similar indirect measures. This article reports the first direct measure of IOR, obtained by asking observers to predict the location of the next target in a display containing eight possible locations on an imaginary circle. On any given trial, the previously cued location was chosen less frequently (impairment)—and the opposite location was chosen more frequently (facilitation)—than chance (choice of all other locations was at chance). The impairment is consistent with both inhibition and expectation accounts; the facilitation is consistent only with expectation accounts. This work also shows that inhibition and expectation are not necessarily incompatible: Implementing expectations may entail inhibiting previously cued locations.

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Demand on skillfulness modulates interhemispheric inhibition of motor cortices

Journal of Neurophysiology ◽

10.1152/jn.01076.2015 ◽

2016 ◽

Vol 115 (6) ◽

pp. 2803-2813 ◽

Cited By ~ 11

Author(s):

Miles Wischnewski ◽

Greg M. Kowalski ◽

Farrah Rink ◽

Samir R. Belagaje ◽

Marc W. Haut ◽

...

Keyword(s):

Primary Motor Cortex ◽

Motor Task ◽

Conditioning Stimulus ◽

Motor Evoked Potential ◽

Inhibitory Effect ◽

Left Hand ◽

The Mean ◽

Small Targets ◽

Healthy Participants

The role of primary motor cortex (M1) in the control of hand movements is still unclear. Functional magnetic resonance imaging (fMRI) studies of unimanual performance reported a relationship between level of precision of a motor task and additional ipsilateral M1 (iM1) activation. In the present study, we determined whether the demand on accuracy of a movement influences the magnitude of the inhibitory effect between primary motor cortices (IHI). We used transcranial magnetic stimulation (TMS) to measure active IHI (aIHI) of the iM1 on the contralateral M1 (cM1) in the premovement period of a left-hand motor task. Ten healthy participants manipulated a joystick to point to targets of two different sizes. For aIHI, the conditioning stimulus (CS) was applied to iM1, and the test stimulus (TS) to cM1, with an interstimulus interval of 10 ms. The amount of the inhibitory effect of the CS on the motor-evoked potential (MEP) of the subsequent TS was expressed as percentage of the mean MEP amplitude evoked by the single TS. Across different time points of aIHI measurements in the premovement period, there was a significant effect for target size on aIHI. Preparing to point to small targets was associated with weaker aIHI compared with pointing to large targets. The present findings suggest that, during the premovement period, aIHI from iM1 on cM1 is modulated by the demand on accuracy of the motor task. This is consistent with task fMRI findings showing bilateral M1 activation during high-precision movements but only unilateral M1 activity during low-precision movements.

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Corticospinal Tract Microstructure Correlates With Beta Oscillatory Activity in the Primary Motor Cortex After Stroke

Stroke ◽

10.1161/strokeaha.121.034344 ◽

2021 ◽

Author(s):

Robert Schulz ◽

Marlene Bönstrup ◽

Stephanie Guder ◽

Jingchun Liu ◽

Benedikt Frey ◽

...

Keyword(s):

Motor Cortex ◽

Fractional Anisotropy ◽

Primary Motor Cortex ◽

Supplementary Motor Area ◽

Premotor Cortex ◽

Motor Impairment ◽

Motor Area ◽

Oscillatory Activity ◽

Premotor Area ◽

Beta Power

Background and Purpose: Cortical beta oscillations are reported to serve as robust measures of the integrity of the human motor system. Their alterations after stroke, such as reduced movement-related beta desynchronization in the primary motor cortex, have been repeatedly related to the level of impairment. However, there is only little data whether such measures of brain function might directly relate to structural brain changes after stroke. Methods: This multimodal study investigated 18 well-recovered patients with stroke (mean age 65 years, 12 males) by means of task-related EEG and diffusion-weighted structural MRI 3 months after stroke. Beta power at rest and movement-related beta desynchronization was assessed in 3 key motor areas of the ipsilesional hemisphere that are the primary motor cortex (M1), the ventral premotor area and the supplementary motor area. Template trajectories of corticospinal tracts (CST) originating from M1, premotor cortex, and supplementary motor area were used to quantify the microstructural state of CST subcomponents. Linear mixed-effects analyses were used to relate tract-related mean fractional anisotropy to EEG measures. Results: In the present cohort, we detected statistically significant reductions in ipsilesional CST fractional anisotropy but no alterations in EEG measures when compared with healthy controls. However, in patients with stroke, there was a significant association between both beta power at rest ( P =0.002) and movement-related beta desynchronization ( P =0.003) in M1 and fractional anisotropy of the CST specifically originating from M1. Similar structure-function relationships were neither evident for ventral premotor area and supplementary motor area, particularly with respect to their CST subcomponents originating from premotor cortex and supplementary motor area, in patients with stroke nor in controls. Conclusions: These data suggest there might be a link connecting microstructure of the CST originating from M1 pyramidal neurons and beta oscillatory activity, measures which have already been related to motor impairment in patients with stroke by previous reports.

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