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1. Design-development of an at-home modular brain–computer interface (BCI) platform in a case study of cervical spinal cord injury

   Objective

   The objective of this study was to develop a portable and modular brain–computer interface (BCI) software platform independent of input and...

   Kevin C. Davis, Benyamin Meschede-Krasa, ... Abhishek Prasad in Journal of NeuroEngineering and Rehabilitation

   Article Open access 03 June 2022
   

2. Potential of a Brain–Computer Interface for Correcting Poststroke Cognitive Impairments

   Brain–computer interfaces (BCI) are actively used in neurorehabilitation. Recent years have seen the accumulation of an extensive database of results...

   V. A. Borisova, E. V. Isakova, S. V. Kotov in Neuroscience and Behavioral Physiology

   Article 01 July 2023

3. The role of eye movement signals in non-invasive brain-computer interface ty** system

   Brain-Computer Interfaces (BCIs) have shown great potential in providing communication and control for individuals with severe motor disabilities....

   ** Liu, Bingliang Hu, ... Quan Wang in Medical & Biological Engineering & Computing

   Article 21 March 2024
   

4. Towards Improving Motor Imagery Brain–Computer Interface Using Multimodal Speech Imagery

   Purpose

   The brain–computer interface (BCI) based on motor imagery (MI) has attracted extensive interest due to its spontaneity and convenience....

   Jigang Tong, Zhengxing **ng, ... Cesar F. Caiafa in Journal of Medical and Biological Engineering

   Article Open access 21 June 2023
   

5. Simulation-Informed Power Budget Estimate of a Fully-Implantable Brain–Computer Interface

   This study aims to estimate the maximum power consumption that guarantees a thermally safe operation for a titanium-enclosed chest wall unit (CWU)...

   Claudia Serrano-Amenos, Frank Hu, ... Zoran Nenadic in Annals of Biomedical Engineering

   Article 16 May 2024
   

6. Brain-Computer Interface to Deliver Individualized Multisensory Intervention for Neuropathic Pain

   To unravel the complexity of the neuropathic pain experience, researchers have tried to identify reliable pain signatures (biomarkers) using...

   Giuseppe Valerio Aurucci, Greta Preatoni, ... Stanisa Raspopovic in Neurotherapeutics

   Article Open access 05 July 2023
   

7. Assessment of visual fatigue in SSVEP-based brain-computer interface: a comprehensive study

   Fatigue deteriorates the performance of a brain-computer interface (BCI) system; thus, reliable detection of fatigue is the first step to counter...

   Pablo Diez, Lorena Orosco, ... Luciano Carmona in Medical & Biological Engineering & Computing

   Article 25 January 2024
   

8. Effective 2-D cursor control system using hybrid SSVEP + P300 visual brain computer interface

   A cursor control system based on brain-computer interface (BCI) provides efficient computer access. These systems operate without any muscular...

   Deepak Kapgate in Medical & Biological Engineering & Computing

   Article 24 September 2022
   

9. Motor imagery-based brain–computer interface rehabilitation programs enhance upper extremity performance and cortical activation in stroke patients

   Background

   The most challenging aspect of rehabilitation is the repurposing of residual functional plasticity in stroke patients. To achieve this,...

   Zhen-Zhen Ma, Jia-Jia Wu, ... Jian-Guang Xu in Journal of NeuroEngineering and Rehabilitation

   Article Open access 29 May 2024
   

10. Rehabilitation of Patients with Post-Stroke Cognitive Impairments Using a P300-Based Brain–Computer Interface: Results of a Randomized Controlled Trial

    Objective . To study the effects of 10 days of cognitive training using brain–computer interface (BCI) technology based on the P300 wave on the...

    V. V. Fateeva, A. B. Kushnir, ... L. A. Mayorova in Neuroscience and Behavioral Physiology

    Article 01 May 2024

11. A P300 Brain-Computer Interface for Lower Limb Robot Control Based on Tactile Stimulation

    Purpose

    Tactile brain-computer interfaces can be used to express control intentions, avoiding motor imagery difficulties and visual fatigue. Tactile...

    **aoyu Duan, Shijie Guo, ... Mengge Wang in Journal of Medical and Biological Engineering

    Article 05 December 2022
    

12. Brain–Computer Interfaces

    In the past decades, brain–computer interfaces (BCIs) have been among the fastest-growing technologies and a very prolific research field. Typically,...

    Elena Sibilano, Vladimiro Suglia, ... Vitoantonio Bevilacqua in Psychophysiology Methods

    Protocol 2024
    

13. Upper Limb Recovery in Cervical Spinal Cord Injury After a Brain-Computer Interface Controlled Functional Electrical Stimulation Intervention

    Purpose

    Upper limb motor recovery is highly relevant for individuals with tetraplegia after spinal cord injury (SCI). Experimental interventions based...

    Jessica Cantillo-Negrete, Ruben I. Carino-Escobar, ... Javier M. Antelis in Journal of Medical and Biological Engineering

    Article 26 September 2023
    

14. Evaluation of the Effectiveness of Control Using a Brain–Computer Interface in Training to Upper and Lower Limb Motor Imagery

    The effectiveness of control using a brain–computer interface (BCI) and the success of motor imagery of the upper and lower limbs was assessed in...

    E. V. Bobrova, V. V. Reshetnikova, ... Yu. P. Gerasimenko in Neuroscience and Behavioral Physiology

    Article 01 June 2023

15. Brain-Computer Interaction and Neuroergonomics

    When studying human brains in relation with digital technologies, or digital brains, a relatively recent technology may prove particularly promising...

    Fabien Lotte, Camille Jeunet-Kelway in Mind, Body, and Digital Brains

    Chapter 2024
    

16. Brain computer interface training with motor imagery and functional electrical stimulation for patients with severe upper limb paresis after stroke: a randomized controlled pilot trial

    Background

    Restorative Brain–Computer Interfaces (BCI) that combine motor imagery with visual feedback and functional electrical stimulation (FES) may...

    Iris Brunner, Camilla Biering Lundquist, ... Andrej Savic in Journal of NeuroEngineering and Rehabilitation

    Article Open access 20 January 2024
    

17. Can vibrotactile stimulation and tDCS help inefficient BCI users?

    Brain-computer interface (BCI) has helped people by allowing them to control a computer or machine through brain activity without actual body...

    Kyungho Won, Heegyu Kim, ... Sung Chan Jun in Journal of NeuroEngineering and Rehabilitation

    Article Open access 04 May 2023
    

18. Boosting brain–computer interfaces with functional electrical stimulation: potential applications in people with locked-in syndrome

    Individuals with a locked-in state live with severe whole-body paralysis that limits their ability to communicate with family and loved ones. Recent...

    Evan Canny, Mariska J. Vansteensel, ... Julia Berezutskaya in Journal of NeuroEngineering and Rehabilitation

    Article Open access 18 November 2023
    

19. Fatigue in children using motor imagery and P300 brain-computer interfaces

    Background

    Brain-computer interface (BCI) technology offers children with quadriplegic cerebral palsy unique opportunities for communication,...

    Joanna RG. Keough, Brian Irvine, ... Adam Kirton in Journal of NeuroEngineering and Rehabilitation

    Article Open access 24 April 2024
    

20. Development of a humanoid robot control system based on AR-BCI and SLAM navigation

    Brain-computer interface (BCI)-based robot combines BCI and robotics technology to realize the brain’s intention to control the robot, which not only...

    Yao Wang, Mingxing Zhang, ... **aogang Chen in Cognitive Neurodynamics

    Article 18 May 2024