K A Mamun1, M Mace, M E Lutman, J Stein, X Liu, T Aziz, R Vaidyanathan, S Wang. 1. Institute of Sound and Vibration Research, University of Southampton, Southampton, UK. Institute of Biomaterials and Biomedical Engineering, University of Toronto and Bloorview Research Institute, Holland Bloorview Kids Rehabilitation Hospital, Toronto, Canada. Department of Computer Science and Engineering, United International University, Dhaka, Bangladesh.
Abstract
OBJECTIVE: Correlating electrical activity within the human brain to movement is essential for developing and refining interventions (e.g. deep brain stimulation (DBS)) to treat central nervous system disorders. It also serves as a basis for next generation brain-machine interfaces (BMIs). This study highlights a new decoding strategy for capturing movement and its corresponding laterality from deep brain local field potentials (LFPs). APPROACH: LFPs were recorded with surgically implanted electrodes from the subthalamic nucleus or globus pallidus interna in twelve patients with Parkinson's disease or dystonia during a visually cued finger-clicking task. We introduce a method to extract frequency dependent neural synchronization and inter-hemispheric connectivity features based upon wavelet packet transform (WPT) and Granger causality approaches. A novel weighted sequential feature selection algorithm has been developed to select optimal feature subsets through a feature contribution measure. This is particularly useful when faced with limited trials of high dimensionality data as it enables estimation of feature importance during the decoding process. MAIN RESULTS: This novel approach was able to accurately and informatively decode movement related behaviours from the recorded LFP activity. An average accuracy of 99.8% was achieved for movement identification, whilst subsequent laterality classification was 81.5%. Feature contribution analysis highlighted stronger contralateral causal driving between the basal ganglia hemispheres compared to ipsilateral driving, with causality measures considerably improving laterality discrimination. SIGNIFICANCE: These findings demonstrate optimally selected neural synchronization alongside causality measures related to inter-hemispheric connectivity can provide an effective control signal for augmenting adaptive BMIs. In the case of DBS patients, acquiring such signals requires no additional surgery whilst providing a relatively stable and computationally inexpensive control signal. This has the potential to extend invasive BMI, based on recordings within the motor cortex, by providing additional information from subcortical regions.
OBJECTIVE: Correlating electrical activity within the human brain to movement is essential for developing and refining interventions (e.g. deep brain stimulation (DBS)) to treat central nervous system disorders. It also serves as a basis for next generation brain-machine interfaces (BMIs). This study highlights a new decoding strategy for capturing movement and its corresponding laterality from deep brain local field potentials (LFPs). APPROACH: LFPs were recorded with surgically implanted electrodes from the subthalamic nucleus or globus pallidus interna in twelve patients with Parkinson's disease or dystonia during a visually cued finger-clicking task. We introduce a method to extract frequency dependent neural synchronization and inter-hemispheric connectivity features based upon wavelet packet transform (WPT) and Granger causality approaches. A novel weighted sequential feature selection algorithm has been developed to select optimal feature subsets through a feature contribution measure. This is particularly useful when faced with limited trials of high dimensionality data as it enables estimation of feature importance during the decoding process. MAIN RESULTS: This novel approach was able to accurately and informatively decode movement related behaviours from the recorded LFP activity. An average accuracy of 99.8% was achieved for movement identification, whilst subsequent laterality classification was 81.5%. Feature contribution analysis highlighted stronger contralateral causal driving between the basal ganglia hemispheres compared to ipsilateral driving, with causality measures considerably improving laterality discrimination. SIGNIFICANCE: These findings demonstrate optimally selected neural synchronization alongside causality measures related to inter-hemispheric connectivity can provide an effective control signal for augmenting adaptive BMIs. In the case of DBS patients, acquiring such signals requires no additional surgery whilst providing a relatively stable and computationally inexpensive control signal. This has the potential to extend invasive BMI, based on recordings within the motor cortex, by providing additional information from subcortical regions.
Authors: Andrea A Kühn; R Mark Richardson; Wolf-Julian Neumann; Robert S Turner; Benjamin Blankertz; Tom Mitchell Journal: Neurotherapeutics Date: 2019-01 Impact factor: 7.620
Authors: Huiling Tan; Jean Debarros; Shenghong He; Alek Pogosyan; Tipu Z Aziz; Yongzhi Huang; Shouyan Wang; Lars Timmermann; Veerle Visser-Vandewalle; David J Pedrosa; Alexander L Green; Peter Brown Journal: Brain Stimul Date: 2019-02-21 Impact factor: 8.955
Authors: Mario Stanziano; Nico Golfrè Andreasi; Giuseppe Messina; Sara Rinaldo; Sara Palermo; Mattia Verri; Greta Demichelis; Jean Paul Medina; Francesco Ghielmetti; Salvatore Bonvegna; Anna Nigri; Giulia Frazzetta; Ludovico D'Incerti; Giovanni Tringali; Francesco DiMeco; Roberto Eleopra; Maria Grazia Bruzzone Journal: Front Neurol Date: 2022-01-12 Impact factor: 4.003
Authors: Maxime Verwoert; Maarten C Ottenhoff; Sophocles Goulis; Albert J Colon; Louis Wagner; Simon Tousseyn; Johannes P van Dijk; Pieter L Kubben; Christian Herff Journal: Sci Data Date: 2022-07-22 Impact factor: 8.501
Authors: Saed Khawaldeh; Gerd Tinkhauser; Syed Ahmar Shah; Katrin Peterman; Ines Debove; T A Khoa Nguyen; Andreas Nowacki; M Lenard Lachenmayer; Michael Schuepbach; Claudio Pollo; Paul Krack; Mark Woolrich; Peter Brown Journal: Brain Date: 2020-02-01 Impact factor: 13.501