Mobile Electroencephalography for Studying Neural Control of Human Locomotion

Song, Shin‐Min; Nordin, Andrew D.

doi:10.3389/fnhum.2021.749017

Cited by 9 publications

(6 citation statements)

References 165 publications

(235 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…We suppose that greater spatial coverage, as well as digitized electrode locations and subject-specific structural MRI, would improve artifact attenuation further. To understand neural correlates of gait further, studies including these additional measures will be of great significance, however, in line with previous studies ( 6 , 7 , 92 ), our approach demonstrates that gait-related neural activity can be investigated with small setups [for system recommendation see e.g., ( 93 )] with measurements from few additional sensors. These studies using less equipment are needed to investigate possible translations into clinical practice, where less-costly and time-consuming setups are of relevance.…”

Section: Discussionsupporting

confidence: 67%

Mobile electroencephalography captures differences of walking over even and uneven terrain but not of single and dual-task gait

Jacobsen

Blum²,

Scanlon³

et al. 2022

Front. Sports Act. Living

View full text Add to dashboard Cite

Walking on natural terrain while performing a dual-task, such as typing on a smartphone is a common behavior. Since dual-tasking and terrain change gait characteristics, it is of interest to understand how altered gait is reflected by changes in gait-associated neural signatures. A study was performed with 64-channel electroencephalography (EEG) of healthy volunteers, which was recorded while they walked over uneven and even terrain outdoors with and without performing a concurrent task (self-paced button pressing with both thumbs). Data from n = 19 participants (M = 24 years, 13 females) were analyzed regarding gait-phase related power modulations (GPM) and gait performance (stride time and stride time-variability). GPMs changed significantly with terrain, but not with the task. Descriptively, a greater beta power decrease following right-heel strikes was observed on uneven compared to even terrain. No evidence of an interaction was observed. Beta band power reduction following the initial contact of the right foot was more pronounced on uneven than on even terrain. Stride times were longer on uneven compared to even terrain and during dual- compared to single-task gait, but no significant interaction was observed. Stride time variability increased on uneven terrain compared to even terrain but not during single- compared to dual-tasking. The results reflect that as the terrain difficulty increases, the strides become slower and more irregular, whereas a secondary task slows stride duration only. Mobile EEG captures GPM differences linked to terrain changes, suggesting that the altered gait control demands and associated cortical processes can be identified. This and further studies may help to lay the foundation for protocols assessing the cognitive demand of natural gait on the motor system.

show abstract

Section: Discussionsupporting

confidence: 67%

Mobile electroencephalography captures differences of walking over even and uneven terrain but not of single and dual-task gait

Jacobsen

Blum²,

Scanlon³

et al. 2022

Front. Sports Act. Living

View full text Add to dashboard Cite

show abstract

“…One can include common preprocessing choices in P3 analysis which can be identified with the shiny app. Moreover, recommendations can help identify suitable and preprocessing approaches, as well as set-up procedures and EEG systems (Gorjan et al, 2022; Gramann, 2024; Reis et al, 2014; Song & Nordin, 2021; Wascher et al, 2021). If a scaffolding of steps exists, employing a multiverse analysis using data that will not undergo statistical evaluation can determine appropriate options for specific steps.…”

Section: Discussionmentioning

confidence: 99%

Preprocessing Choices for P3 Analyses with Mobile EEG: A Systematic Literature Review and Interactive Exploration

Jacobsen,

Kristanto,

Welp

et al. 2024

Preprint

View full text Add to dashboard Cite

Preprocessing is necessary to extract meaningful results from electroencephalography (EEG) data. With many possible preprocessing choices, their impact on outcomes is fundamental. While previous studies have explored the effects of preprocessing on stationary EEG data, this research delves into mobile EEG, where complex processing is necessary to address motion artifacts. Specifically, we describe the preprocessing choices studies reported for analyzing the P3 event-related potential (ERP) during walking and standing. A systematic review of 258 studies (Scopus, Web of Science, PubMed) of the P3 during walking, identified 27 studies meeting the inclusion criteria (empirical study, EEG data of healthy humans, P3 during a gait and non-movement condition). Two independent coders extracted preprocessing choices reported in each study. Analysis of preprocessing choices revealed commonalities and differences, such as widespread use of offline filters but limited application of line noise correction (3 out of 27 studies). Notably, 63% of studies involved manual processing steps, and 52% omitted reporting critical parameters for at least one step. All studies employed unique preprocessing strategies. These findings align with stationary EEG preprocessing results, emphasizing the necessity for standardized reporting in mobile EEG research. We implemented an interactive visualization tool (Shiny app) to aid the exploration of the preprocessing landscape. The Shiny app allows users to structure the literature regarding different processing steps and processing combinations, thereby providing a meaningful overview. It is also possible to enter planned or preferred processing methods and compare own choices with the literature. The app thus helps to identify defensible preprocessing choices, specifically with a focus on P3 ERP analyses during standing and walking. It could be utilized to examine how these choices impact P3 results and understand the robustness of various processing options. We hope to increase awareness regarding the potential influence of preprocessing decisions and advocate for comprehensive reporting standards to foster reproducibility in mobile EEG research.

show abstract

“…However, the recent findings in Noor et al [40] showed that the artifacts rejection by the automatic continuous rejection and experts confirmation provided promising results in predicting TBI outcomes of specific frequency bands. Although an automated artifacts rejection can help isolate between the neural or non-neural source components from ICA decomposition, subjective method (i.e., visual classification by experts) is still typically advisable [33,70].…”

Section: Discussionmentioning

confidence: 99%

Prediction of Recovery from Traumatic Brain Injury with EEG Power Spectrum in Combination of Independent Component Analysis and RUSBoost Model

et al. 2022

View full text Add to dashboard Cite

The computational electroencephalogram (EEG) is recently garnering significant attention in examining whether the quantitative EEG (qEEG) features can be used as new predictors for the prediction of recovery in moderate traumatic brain injury (TBI). However, the brain’s recorded electrical activity has always been contaminated with artifacts, which in turn further impede the subsequent processing steps. As a result, it is crucial to devise a strategy for meticulously flagging and extracting clean EEG data to retrieve high-quality discriminative features for successful model development. This work proposed the use of multiple artifact rejection algorithms (MARA), which is an independent component analysis (ICA)-based algorithm, to eliminate artifacts automatically, and explored their effects on the predictive performance of the random undersampling boosting (RUSBoost) model. Continuous EEG were acquired using 64 electrodes from 27 moderate TBI patients at four weeks to one-year post-accident. The MARA incorporates an artifact removal stage based on ICA prior to RUSBoost, SVM, DT, and k-NN classification. The area under the curve (AUC) of RUSBoost was higher in absolute power spectral density (PSD) in AUCδ = 0.75, AUC α = 0.73 and AUCθ = 0.71 bands than SVM, DT, and k-NN. The MARA has provided a good generalization performance of the RUSBoost prediction model.

show abstract

Mobile Electroencephalography for Studying Neural Control of Human Locomotion

Cited by 9 publications

References 165 publications

Mobile electroencephalography captures differences of walking over even and uneven terrain but not of single and dual-task gait

Mobile electroencephalography captures differences of walking over even and uneven terrain but not of single and dual-task gait

Preprocessing Choices for P3 Analyses with Mobile EEG: A Systematic Literature Review and Interactive Exploration

Prediction of Recovery from Traumatic Brain Injury with EEG Power Spectrum in Combination of Independent Component Analysis and RUSBoost Model

Contact Info

Product

Resources

About