Synchronization of Neurophysiological and Biomechanical Data in a Real-Time Virtual Gait Analysis System (GRAIL): A Proof-of-Principle Study [Synchronisation von neurophysiologischen und biomechanischen Daten in einem virtuellen Echtzeit-Ganganalysesystem (GRAIL): Eine Proof-of-Principle-Studie]

Maas, Stefan; Göcking, Tim; Stojan, Robert; Voelcker-Rehage, Claudia; Kutz, Dieter Friedhelm

Research article (journal) | Peer reviewed

Abstract

The investigation of gait and its neuronal correlates under more ecologically valid conditions as well as real-time feedback visualization is becoming increasingly important in neuro-motor rehabilitation research. The Gait Real-time Analysis Interactive Lab (GRAIL) offers advanced opportunities for gait and gait-related research by creating more naturalistic yet controlled environments through immersive virtual reality. Investigating the neuronal aspects of gait requires parallel recording of brain activity, such as through mobile electroencephalography (EEG) and/or mobile functional near-infrared spectroscopy (fNIRS), which must be synchronized with the kinetic and /or kinematic data recorded while walking. This proof-of-concept study outlines the required setup by use of the lab streaming layer (LSL) ecosystem for real-time, simultaneous data collection of two independently operating multi-channel EEG and fNIRS measurement devices and gait kinetics. In this context, a customized approach using a photodiode to synchronize the systems is described. This study demonstrates the achievable temporal accuracy of synchronous data acquisition of neurophysiological and kinematic and kinetic data collection in the GRAIL. By using event-related cerebral hemodynamic activity and visually evoked potentials during a start-to-go task and a checkerboard test, we were able to confirm that our measurement system can replicate known physiological phenomena with latencies in the millisecond range and relate neurophysiological and kinetic data to each other with sufficient accuracy.

Details about the publication

JournalSensors
Volume24
Issue12
Article number3779
StatusPublished
Release year2024 (11/06/2024)
Language in which the publication is writtenEnglish
DOI: 10.3390/s24123779
Keywords ecological validity; instrumented treadmill; neuroimaging; neurorehabilitation; neuroergonomics;

Authors from the University of Münster

Göcking, Tim
Professorship of Neuromotor Behavior and Exercise (Prof. Voelcker-Rehage)
Kutz, Dieter Friedhelm
Professorship of Neuromotor Behavior and Exercise (Prof. Voelcker-Rehage)
Maas, Stefan Andreas
Professorship of Neuromotor Behavior and Exercise (Prof. Voelcker-Rehage)
Stojan, Robert
Professorship of Neuromotor Behavior and Exercise (Prof. Voelcker-Rehage)
Voelcker-Rehage, Claudia
Professorship of Neuromotor Behavior and Exercise (Prof. Voelcker-Rehage)