Neural predictors of gait stability when walking freely in the real-world

Neural predictors of gait stability when walking freely in the real-world

Abstract Background Gait impairments during real-world locomotion are common in neurological diseases. However, very little is currently known about the neural correlates of walking in the real world and on which regions of the brain are involved in regulating gait stability and performance. As a fi...

Full description

Bibliographic Details
Main Authors: Sara Pizzamiglio, Hassan Abdalla, Usman Naeem, Duncan L. Turner
Format: Article
Language:English
Published: BMC 2018-02-01
Series:Journal of NeuroEngineering and Rehabilitation
Subjects:
Mobile brain/body imaging (MOBI)
EEG
Gait
Acceleration
RMSR
Urban environment
Online Access:http://link.springer.com/article/10.1186/s12984-018-0357-z
id doaj-f52babda3cf54c2c81e79ea32153a8a4
record_format Article
spelling doaj-f52babda3cf54c2c81e79ea32153a8a42020-11-24T20:45:04ZengBMCJournal of NeuroEngineering and Rehabilitation1743-00032018-02-0115111110.1186/s12984-018-0357-zNeural predictors of gait stability when walking freely in the real-worldSara Pizzamiglio0Hassan Abdalla1Usman Naeem2Duncan L. Turner3Neuroplasticity and Neurorehabilitation Doctoral Training Programme, Neurorehabilitation Unit, School of Health, Sport and Bioscience, College of Applied Health, University of East LondonSchool of Architecture, Computing and Engineering, University of East London, University WaySchool of Architecture, Computing and Engineering, University of East London, University WayNeuroplasticity and Neurorehabilitation Doctoral Training Programme, Neurorehabilitation Unit, School of Health, Sport and Bioscience, College of Applied Health, University of East LondonAbstract Background Gait impairments during real-world locomotion are common in neurological diseases. However, very little is currently known about the neural correlates of walking in the real world and on which regions of the brain are involved in regulating gait stability and performance. As a first step to understanding how neural control of gait may be impaired in neurological conditions such as Parkinson’s disease, we investigated how regional brain activation might predict walking performance in the urban environment and whilst engaging with secondary tasks in healthy subjects. Methods We recorded gait characteristics including trunk acceleration and brain activation in 14 healthy young subjects whilst they walked around the university campus freely (single task), while conversing with the experimenter and while texting with their smartphone. Neural spectral power density (PSD) was evaluated in three brain regions of interest, namely the pre-frontal cortex (PFC) and bilateral posterior parietal cortex (right/left PPC). We hypothesized that specific regional neural activation would predict trunk acceleration data obtained during the different walking conditions. Results Vertical trunk acceleration was predicted by gait velocity and left PPC theta (4–7 Hz) band PSD in single-task walking (R-squared = 0.725, p = 0.001) and by gait velocity and left PPC alpha (8–12 Hz) band PSD in walking while conversing (R-squared = 0.727, p = 0.001). Medio-lateral trunk acceleration was predicted by left PPC beta (15–25 Hz) band PSD when walking while texting (R-squared = 0.434, p = 0.010). Conclusions We suggest that the left PPC may be involved in the processes of sensorimotor integration and gait control during walking in real-world conditions. Frequency-specific coding was operative in different dual tasks and may be developed as biomarkers of gait deficits in neurological conditions during performance of these types of, now commonly undertaken, dual tasks.http://link.springer.com/article/10.1186/s12984-018-0357-zMobile brain/body imaging (MOBI)EEGGaitAccelerationRMSRUrban environment
collection DOAJ
language English
format Article
sources DOAJ
author Sara Pizzamiglio
Hassan Abdalla
Usman Naeem
Duncan L. Turner
spellingShingle Sara Pizzamiglio
Hassan Abdalla
Usman Naeem
Duncan L. Turner
Neural predictors of gait stability when walking freely in the real-world
Journal of NeuroEngineering and Rehabilitation
Mobile brain/body imaging (MOBI)
EEG
Gait
Acceleration
RMSR
Urban environment
author_facet Sara Pizzamiglio
Hassan Abdalla
Usman Naeem
Duncan L. Turner
author_sort Sara Pizzamiglio
title Neural predictors of gait stability when walking freely in the real-world
title_short Neural predictors of gait stability when walking freely in the real-world
title_full Neural predictors of gait stability when walking freely in the real-world
title_fullStr Neural predictors of gait stability when walking freely in the real-world
title_full_unstemmed Neural predictors of gait stability when walking freely in the real-world
title_sort neural predictors of gait stability when walking freely in the real-world
publisher BMC
series Journal of NeuroEngineering and Rehabilitation
issn 1743-0003
publishDate 2018-02-01
description Abstract Background Gait impairments during real-world locomotion are common in neurological diseases. However, very little is currently known about the neural correlates of walking in the real world and on which regions of the brain are involved in regulating gait stability and performance. As a first step to understanding how neural control of gait may be impaired in neurological conditions such as Parkinson’s disease, we investigated how regional brain activation might predict walking performance in the urban environment and whilst engaging with secondary tasks in healthy subjects. Methods We recorded gait characteristics including trunk acceleration and brain activation in 14 healthy young subjects whilst they walked around the university campus freely (single task), while conversing with the experimenter and while texting with their smartphone. Neural spectral power density (PSD) was evaluated in three brain regions of interest, namely the pre-frontal cortex (PFC) and bilateral posterior parietal cortex (right/left PPC). We hypothesized that specific regional neural activation would predict trunk acceleration data obtained during the different walking conditions. Results Vertical trunk acceleration was predicted by gait velocity and left PPC theta (4–7 Hz) band PSD in single-task walking (R-squared = 0.725, p = 0.001) and by gait velocity and left PPC alpha (8–12 Hz) band PSD in walking while conversing (R-squared = 0.727, p = 0.001). Medio-lateral trunk acceleration was predicted by left PPC beta (15–25 Hz) band PSD when walking while texting (R-squared = 0.434, p = 0.010). Conclusions We suggest that the left PPC may be involved in the processes of sensorimotor integration and gait control during walking in real-world conditions. Frequency-specific coding was operative in different dual tasks and may be developed as biomarkers of gait deficits in neurological conditions during performance of these types of, now commonly undertaken, dual tasks.
topic Mobile brain/body imaging (MOBI)
EEG
Gait
Acceleration
RMSR
Urban environment
url http://link.springer.com/article/10.1186/s12984-018-0357-z
work_keys_str_mv AT sarapizzamiglio neuralpredictorsofgaitstabilitywhenwalkingfreelyintherealworld
AT hassanabdalla neuralpredictorsofgaitstabilitywhenwalkingfreelyintherealworld
AT usmannaeem neuralpredictorsofgaitstabilitywhenwalkingfreelyintherealworld
AT duncanlturner neuralpredictorsofgaitstabilitywhenwalkingfreelyintherealworld
_version_ 1716815583847120896

Similar Items