Right frontal eye field has perceptual and oculomotor functions during optokinetic stimulation and nystagmus

Mastropasqua, Angela; Dowsett, James; Dieterich, Marianne; Taylor, Paul C.J.

doi:10.1152/jn.00468.2019

Cited by 8 publications

(12 citation statements)

References 114 publications

(161 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The right hemisphere -in right handers, as in the present study-specializes in vestibular processing, which allows an individual to orient themselves in space based on visual and proprioceptive cues (e.g., body posture and orientation; Mast et al, 2014;Besnard et al, 2015;Dieterich and Brandt, 2015). Within this context, the right frontal eye field (implicated in the present study) has been uniquely identified as important to visuospatial perception (Mastropasqua et al, 2020). Collectively, the preference for right-hemisphere activation in these brain areas suggest an increased emphasis on regulating visuomotor expressions, likely facilitated by repeated deployment of reactive control mechanisms in response to spontaneously evolving situations on stage.…”

Section: Bx Reaction Timementioning

confidence: 49%

“…Both BA6 and BA8 have been directly implicated in reactive control processes (Brass et al, 2005;Forstmann et al, 2008;Braver et al, 2009). Both areas have also been associated with orchestrating complex visuomotor interactions (Mastropasqua et al, 2020), which are characteristic of the reactive control aspect of active experiencing. Integrating these viewpoints together, it is likely that BA6 and BA8 facilitate deployment of reactive control.…”

Section: Bx Reaction Timementioning

confidence: 99%

See 1 more Smart Citation

Can a Theater Acting Intervention Enhance Inhibitory Control in Older Adults? A Brain-Behavior Investigation

Rajesh

Noice

et al. 2021

Front. Hum. Neurosci.

View full text Add to dashboard Cite

Purpose: Studies of reactive and proactive modes of inhibitory control tend to show age-related declines and are accompanied by abnormalities in the prefrontal cortex. We explored which mode of inhibitory control would be more amenable to change and accrue greater benefits following engagement in a 4-week theater acting intervention in older adults. These gains were evaluated by performance on the AX-CPT task. We hypothesized that an increase in proactive control would relate to an increase in AY errors and a decrease in BX errors. In contrast, an increase in reactive control would be associated with a decrease in AY errors, no change in AY reaction time, and an increase in BX response time. Further, we posited that an increase in behavioral proactive control would accompany greater cue versus probe activity for previously identified regions in the prefrontal cortex. In contrast, an increase in behavioral reactive control would be accompanied by greater probe activation in these identified brain areas.Materials and Methods: The participants were 179 community-dwelling adults aged 60–89 years who were on average, college-educated. Participants were pseudo-randomly assigned to either an active-experiencing acting intervention condition (n = 93) or the active control condition (n = 86); participant assignment was subject to time of enrollment. Participants in both groups were trained by theater-actor researchers with expertise in acting interventions. In contrast to the active control participants who attended a course on theater acting, the acting-intervention group was required to consistently deploy proactive and reactive control mechanisms. Both groups met two times/week for 75-min for 4 weeks. Participant brain-behavioral performance on the AX-CPT task was evaluated prior to and after this four-week period.Results: No intervention effects were found in favor of proactive control. Behavioral evidence in favor of reactive control was weak. Brain-related benefits to reactive control was illustrated by greater probe-activation in Brodmann areas 6 and 8, relative to controls and pre-intervention.Conclusion: We found some evidence for improvements in reactive control via brain measures, attributed to engagement in the acting intervention.

show abstract

Section: Bx Reaction Timementioning

confidence: 49%

Section: Bx Reaction Timementioning

confidence: 99%

Can a Theater Acting Intervention Enhance Inhibitory Control in Older Adults? A Brain-Behavior Investigation

Rajesh

Noice

et al. 2021

Front. Hum. Neurosci.

View full text Add to dashboard Cite

show abstract

“…One candidate would be the dorsal attentional network, key parts of which are activated during OKN, such as the frontal eye fields (FEF; Ruehl et al, 2019). In a recent TMS study, disrupting the FEF during OKN slowed the eye movement (Mastropasqua et al, 2020). Here we can apply the same logic in the opposite direction: if intensive hand gripping facilitated the dorsal attentional network, this could account for the speeding of slow phase velocity of OKN.…”

Section: Discussionmentioning

confidence: 99%

“…Future event-related studies relying on time-frequency analysis (but forfeiting frequency precision for greater time precision) will be necessary to investigate the time-course of the inhibitory effects produced over the visual cortex after each handgrip, or those over the motor cortex during OKS. A recent study reported that frontal eye field TMS during OKS modulated the anterior-posterior alpha EEG balance, the OKN slow phase velocity, and simultaneous perceptual processing, interestingly with no effects of TMS over primary motor cortex (Mastropasqua et al 2020). It would also be important to determine which other cortical and subcortical areas are modulated after each handgrip, which may contribute to the currently observed acceleration of the slow-phase velocity of OKN.…”

Section: Discussionmentioning

confidence: 99%

Interactions between the visual and motor systems during optokinetic stimulation and simultaneous dynamic handgrip exercise: an EEG study

Villasana¹,

Dowsett

Mastropasqua

et al. 2020

Preprint

Self Cite

View full text Add to dashboard Cite

Highlights• Motor activation can inhibit the visual system even during continuous visual stimulation.• Continual visual input produces sustained inhibitory influence on the motor system.• EEG can be reliably assessed during nystagmus. AbstractObjectives: Inhibitory interactions between the visual and motor systems have been observed during transient stimulation of either system. However, it is unknown how inhibition operates during simultaneous and continuous engagement of both systems. Methods: We presented right-handed participants (n = 14) with optokinetic stimulation (OKS), with and without a simultaneous dynamic handgrip exercise. We assessed the EEG upper-alpha band (10-12 Hz) to investigate inhibitory interactions, and explored their effect on optokinetic nystagmus (OKN). Results: OKS + handgrip simultaneously produced motor activation and visual inhibition, compared to OKS alone. Meanwhile, the velocity of OKN increased, selectively during left handgrips. OKS without handgrip produced simultaneous visual activation and motor inhibition compared to an open-eyes baseline. The open-eyes baseline itself increased motor peak-frequency towards the inhibitory upper-alpha range compared to closed eyes. Conclusions: Motor activation inhibited the visual system even during visual stimulation. This inhibition likely disrupted visual processing, triggering an OKN speed-up to relocate the OKS. Increasing visual input produces increasing motor inhibition. Significance: These observations extend previous results in standard settings and confirm the reliability of EEG in conditions involving nystagmus, important in clinical vestibular research. Visual inhibition through handgrip could be a candidate for developing rehabilitation from visually induced dizziness.

show abstract

“…Combined transcranial magnetic stimulation and electroencephalography and an optokinetic-stimulation motion-discrimination task revealed multiple related yet dissociable roles within the FEF, which included perceptual processing during optokinetic simulation, generation of OKN, and maintenance of alpha oscillations. 74 …”

Section: Triggered Nystagmusmentioning

confidence: 99%

Update on Nystagmus and Other Ocular Oscillations

Jeong

Kim

2021

J Clin Neurol

View full text Add to dashboard Cite

This review reports on recent advances in understanding nystagmus and other involuntary eye movements. Advances in quantitative evaluations of eye movements using oculography, computational model simulations, genetics, and imaging technologies have markedly improved our understanding of the pathophysiology of involuntary eye movements, as well as their diagnosis and management. Patient-initiated capture of eye movements, especially when paroxysmal, and the online transfer of these data to clinicians would further enhance the ability to diagnose involuntary eye movements.

show abstract

Right frontal eye field has perceptual and oculomotor functions during optokinetic stimulation and nystagmus

Cited by 8 publications

References 114 publications

Can a Theater Acting Intervention Enhance Inhibitory Control in Older Adults? A Brain-Behavior Investigation

Can a Theater Acting Intervention Enhance Inhibitory Control in Older Adults? A Brain-Behavior Investigation

Interactions between the visual and motor systems during optokinetic stimulation and simultaneous dynamic handgrip exercise: an EEG study

Update on Nystagmus and Other Ocular Oscillations

Contact Info

Product

Resources

About