A hierarchical architecture for recognising intentionality in mental tasks on a brain-computer interface

A brain-computer interface (BCI), based on motor imagery EEG, uses information extracted from the electroencephalography signals generated by a person who intends to perform any action. One of the most important issues of current research is how to detect automatically whether the user intends to send some message to a certain device. This study presents a proposal, based on a hierarchical structured system, for recognising intentional and non-intentional mental tasks on a BCI system by applying machine learning techniques to the EEG signals. First-level clustering is performed to distinguish between intentional control (IC) and non-intentional control (NC) state patterns. Then, the patterns recognised as IC are passed on to a second stage where supervised learning techniques are used to classify them. In BCI applications, it is critical to correctly classify NC states with a low false positive rate (FPR) to avoid undesirable effects. According to the literature, we selected a maximum FPR of 10%. Under these conditions, our proposal achieved an average test accuracy of 66.6%, with an 8.2% FPR, for the BCI competition IIIa dataset. The main contribution of this paper is the hierarchical approach, based on machine learning paradigms, which performs intentional and non-intentional discrimination and, depending on the case, classifies the intended command selected by the user.This work was partially supported by the ERDF/Spanish Ministry of Science, Innovation and Universities - National Research Agency/PhysComp project, TIN2017-85409-P and by the Department of Education, Universities and Research of the Basque Government (ADIAN research group, grant IT980-16)

MODIFICATION AND EVALUATION OF A BRAIN COMPUTER INTERFACE SYSTEM TO DETECT MOTOR INTENTION

It is widely understood that neurons within the brain produce electrical activity, and electroencephalography—a technique used to measure biopotentials with electrodes placed upon the scalp—has been used to observe it. Today, scientists and engineers work to interface these electrical neural signals with computers and machines through the field of Brain-Computer Interfacing (BCI). BCI systems have the potential to greatly improve the quality of life of physically handicapped individuals by replacing or assisting missing or debilitated motor functions. This research thus aims to further improve the efficacy of the BCI based assistive technologies used to aid physically disabled individuals. This study deals with the testing and modification of a BCI system that uses the alpha and beta bands to detect motor intention by weighing online EEG output against a calibrated threshold

Brain enhancement through cognitive training: A new insight from brain connectome

Owing to the recent advances in neurotechnology and the progress in understanding of brain cognitive functions, improvements of cognitive performance or acceleration of learning process with brain enhancement systems is not out of our reach anymore, on the contrary, it is a tangible target of contemporary research. Although a variety of approaches have been proposed, we will mainly focus on cognitive training interventions, in which learners repeatedly perform cognitive tasks to improve their cognitive abilities. In this review article, we propose that the learning process during the cognitive training can be facilitated by an assistive system monitoring cognitive workloads using electroencephalography (EEG) biomarkers, and the brain connectome approach can provide additional valuable biomarkers for facilitating leaners' learning processes. For the purpose, we will introduce studies on the cognitive training interventions, EEG biomarkers for cognitive workload, and human brain connectome. As cognitive overload and mental fatigue would reduce or even eliminate gains of cognitive training interventions, a real-time monitoring of cognitive workload can facilitate the learning process by flexibly adjusting difficulty levels of the training task. Moreover, cognitive training interventions should have effects on brain sub-networks, not on a single brain region, and graph theoretical network metrics quantifying topological architecture of the brain network can differentiate with respect to individual cognitive states as well as to different individuals' cognitive abilities, suggesting that the connectome is a valuable approach for tracking the learning progress. Although only a few studies have exploited the connectome approach for studying alterations of the brain network induced by cognitive training interventions so far, we believe that it would be a useful technique for capturing improvements of cognitive function

Brain-Computer Interfaces and its Place in the Management of Disorders of Consciousness

editorial reviewedBrain-computer interfaces (BCI) constitute a growing and constantly evolving field of study showing promising applications that span a multitude of potential disciplines. In this chapter, we will introduce BCIs and the roles that different technologies and paradigms play specifically for the management of patients with a disorder of consciousness (DoC). We will provide an overview of the state of the art concerning BCI research in the field of DoC by highlighting some of the most paramount works in the current literature. Contrasting the advances in research with current recommendations and applications in clinical practice exposes the severe lack of recognition that BCI usage receives in routine care for patients with a DoC. To conclude, we mention some potentially interesting future perspectives to further develop this domain

Brain-machine interfaces for rehabilitation in stroke: A review

BACKGROUND: Motor paralysis after stroke has devastating consequences for the patients, families and caregivers. Although therapies have improved in the recent years, traditional rehabilitation still fails in patients with severe paralysis. Brain-machine interfaces (BMI) have emerged as a promising tool to guide motor rehabilitation interventions as they can be applied to patients with no residual movement. OBJECTIVE: This paper reviews the efficiency of BMI technologies to facilitate neuroplasticity and motor recovery after stroke. METHODS: We provide an overview of the existing rehabilitation therapies for stroke, the rationale behind the use of BMIs for motor rehabilitation, the current state of the art and the results achieved so far with BMI-based interventions, as well as the future perspectives of neural-machine interfaces. RESULTS: Since the first pilot study by Buch and colleagues in 2008, several controlled clinical studies have been conducted, demonstrating the efficacy of BMIs to facilitate functional recovery in completely paralyzed stroke patients with noninvasive technologies such as the electroencephalogram (EEG). CONCLUSIONS: Despite encouraging results, motor rehabilitation based on BMIs is still in a preliminary stage, and further improvements are required to boost its efficacy. Invasive and hybrid approaches are promising and might set the stage for the next generation of stroke rehabilitation therapies.This study was funded by the Bundesministerium für Bildung und Forschung BMBF MOTORBIC (FKZ13GW0053)andAMORSA(FKZ16SV7754), the Deutsche Forschungsgemeinschaft (DFG), the fortüne-Program of the University of Tübingen (2422-0-0 and 2452-0-0), and the Basque GovernmentScienceProgram(EXOTEK:KK2016/00083). NIL was supported by the Basque Government’s scholarship for predoctoral students

Contributions to physiological computing by means of automatic learning.

169 p.El trabajo presentado en esta tesis se enmarca dentro de dos áreas dentro de la computación fisiológica, que a su vez forma parte de las ciencias de la computación. La primera área trabajada corresponde a la de la detección de fenómenos psicológicos y estados mentales mediante la monitorización de las variables fisiológicas de las personas. La segunda área que se estudia en esta tesis forma parte del estudio de formas alternativas de interacción: los interfaces cerebro-computador.La primera contribución mejora un sistema de lógica difusa que, mediante la monitorización de las señales fisiológicas, es capaz de dar una estimación continuada en el tiempo del nivel del estrés mental. La segunda contribución continua con esta línea y estudia la detección de las respuestas fisiológicas del fenómeno opuesto al estrés: la relajación. En esta contribución se presentan características innovadoras que facilitan dicha detección y la pone en práctica con métodos de aprendizaje automático.Finalmente, la tercera contribución estudia diferentes técnicas de aprendizaje para distinguir entre cuatro clases de movimiento más una quinta clase de no intencionalidad de movimiento en un problema de BCI

Reading Your Own Mind: Dynamic Visualization of Real-Time Neural Signals

Brain Computer Interfaces: BCI) systems which allow humans to control external devices directly from brain activity, are becoming increasingly popular due to dramatic advances in the ability to both capture and interpret brain signals. Further advancing BCI systems is a compelling goal both because of the neurophysiology insights gained from deriving a control signal from brain activity and because of the potential for direct brain control of external devices in applications such as brain injury recovery, human prosthetics, and robotics. The dynamic and adaptive nature of the brain makes it difficult to create classifiers or control systems that will remain effective over time. However it is precisely these qualities that offer the potential to use feedback to build on simple features and create complex control features that are robust over time. This dissertation presents work that addresses these opportunities for the specific case of Electrocorticography: ECoG) recordings from clinical epilepsy patients. First, queued patient tasks were used to explore the predictive nature of both local and global features of the ECoG signal. Second, an algorithm was developed and tested for estimating the most informative features from naive observations of ECoG signal. Third, a software system was built and tested that facilitates real-time visualizations of ECoG signal patients and allows ECoG epilepsy patients to engage in an interactive BCI control feature screening process

Endogenicity and awareness in voluntary action

The idea that we can trigger and control our actions at will is central to our experience as agents. Here, we investigated different cognitive mechanisms involved in voluntary action control. In the first part of the thesis, we investigated the relationship between motor preparation and awareness of intention. To do so, we used spontaneous action paradigms and combined them with novel random and real-time EEG probing techniques. We investigated two main questions. First, do people know that they are about to do something before they do it? Second, to what extent are delayed intention judgements informed by prospective motor preparation rather than retrospective reconstruction? Our findings suggest that people have some feeling of motor intention before acting and can use it to voluntarily control action initiation in real-time. However, their recall-based intention judgements are strongly influenced by overt events happening after the time of probing. Because most daily-life voluntary actions occur in interaction with the environment, in the second part of the thesis we embedded self-paced actions in a decision-making context. We investigated two ways in which endogenous factors can contribute to action selection. First, as a symmetry-breaking mechanism in contexts of external ambiguity. Second, by top-down modulating decision-making processes. We identified the neural correlates of an internal decision-variable that tracks perceptual decisions and also indexes dynamic changes in endogenous goals. Further, we show that the readiness potential can be found not only preceding spontaneous actions, but also in contexts where actions are informed by evidence but preserve a self-paced nature. In sum, this thesis provides new insights into the cognitive mechanisms underlying conscious experience of intention and provides new tools to investigate voluntary control over action initiation and selection processes