124 research outputs found
Artificial intelligence applied to neuroimaging data in Parkinsonian syndromes: Actuality and expectations
Idiopathic Parkinson's Disease (iPD) is a common motor neurodegenerative disorder. It affects more frequently the elderly population, causing a significant emotional burden both for the patient and caregivers, due to the disease-related onset of motor and cognitive disabilities. iPD's clinical hallmark is the onset of cardinal motor symptoms such as bradykinesia, rest tremor, rigidity, and postural instability. However, these symptoms appear when the neurodegenerative process is already in an advanced stage. Furthermore, the greatest challenge is to distinguish iPD from other similar neurodegenerative disorders, "atypical parkinsonisms", such as Multisystem Atrophy, Progressive Supranuclear Palsy and Cortical Basal Degeneration, since they share many phenotypic manifestations, especially in the early stages. The diagnosis of these neurodegenerative motor disorders is essentially clinical. Consequently, the diagnostic accuracy mainly depends on the professional knowledge and experience of the physician. Recent advances in artificial intelligence have made it possible to analyze the large amount of clinical and instrumental information in the medical field. The application machine learning algorithms to the analysis of neuroimaging data appear to be a promising tool for identifying microstructural alterations related to the pathological process in order to explain the onset of symptoms and the spread of the neurodegenerative process. In this context, the search for quantitative biomarkers capable of identifying parkinsonian patients in the prodromal phases of the disease, of correctly distinguishing them from atypical parkinsonisms and of predicting clinical evolution and response to therapy represent the main goal of most current clinical research studies. Our aim was to review the recent literature and describe the current knowledge about the contribution given by machine learning applications to research and clinical management of parkinsonian syndromes
EEG-based Brain-Computer Interfaces (BCIs): A Survey of Recent Studies on Signal Sensing Technologies and Computational Intelligence Approaches and Their Applications.
Brain-Computer interfaces (BCIs) enhance the capability of human brain activities to interact with the environment. Recent advancements in technology and machine learning algorithms have increased interest in electroencephalographic (EEG)-based BCI applications. EEG-based intelligent BCI systems can facilitate continuous monitoring of fluctuations in human cognitive states under monotonous tasks, which is both beneficial for people in need of healthcare support and general researchers in different domain areas. In this review, we survey the recent literature on EEG signal sensing technologies and computational intelligence approaches in BCI applications, compensating for the gaps in the systematic summary of the past five years. Specifically, we first review the current status of BCI and signal sensing technologies for collecting reliable EEG signals. Then, we demonstrate state-of-the-art computational intelligence techniques, including fuzzy models and transfer learning in machine learning and deep learning algorithms, to detect, monitor, and maintain human cognitive states and task performance in prevalent applications. Finally, we present a couple of innovative BCI-inspired healthcare applications and discuss future research directions in EEG-based BCI research
Intelligent Biosignal Analysis Methods
This book describes recent efforts in improving intelligent systems for automatic biosignal analysis. It focuses on machine learning and deep learning methods used for classification of different organism states and disorders based on biomedical signals such as EEG, ECG, HRV, and others
Deep Learning in EEG: Advance of the Last Ten-Year Critical Period
Deep learning has achieved excellent performance in a wide range of domains, especially in speech recognition and computer vision. Relatively less work has been done for EEG, but there is still significant progress attained in the last decade. Due to the lack of a comprehensive and topic widely covered survey for deep learning in EEG, we attempt to summarize recent progress to provide an overview, as well as perspectives for future developments. We first briefly mention the artifacts removal for EEG signal and then introduce deep learning models that have been utilized in EEG processing and classification. Subsequently, the applications of deep learning in EEG are reviewed by categorizing them into groups such as brain-computer interface, disease detection, and emotion recognition. They are followed by the discussion, in which the pros and cons of deep learning are presented and future directions and challenges for deep learning in EEG are proposed. We hope that this paper could serve as a summary of past work for deep learning in EEG and the beginning of further developments and achievements of EEG studies based on deep learning
Application of artificial intelligence in cognitive load analysis using functional near-infrared spectroscopy:A systematic review
Cognitive load theory suggests that overloading of working memory may negatively affect the performance of human in cognitively demanding tasks. Evaluation of cognitive load is a difficult task; it is often assessed through feedback and evaluation from experts. Cognitive load classification based on Functional Near-InfraRed Spectroscopy (fNIRS) is now one of the key research areas in recent years, due to its resistance of artefacts, cost-effectiveness, and portability. To make fNIRS more practical in various applications, it is necessary to develop robust algorithms that can automatically classify fNIRS signals and less reliant on trained signals. Many of the analytical tools used in cognitive sciences have used Deep Learning (DL) modalities to uncover relevant information for mental workload classification. This review investigates the research questions on the design and overall effectiveness of DL as well as its key characteristics. We have identified 45 studies published between 2011 and 2023, that specifically proposed Machine Learning (ML) models for classifying cognitive load using data obtained from fNIRS devices. Those studies were analyzed based on type of feature selection methods, input, and DL model architectures. Most of the existing cognitive load studies are based on ML algorithms, which follow signal filtration and hand-crafted features. It is observed that hybrid DL architectures that integrate convolution and LSTM operators performed significantly better in comparison with other models. However, DL models especially hybrid models have not been extensively investigated for the classification of cognitive load captured by fNIRS devices. The current trends and challenges are highlighted to provide directions for the development of DL models pertaining to fNIRS research
Complex network modelling of EEG band coupling in dyslexia: An exploratory analysis of auditory processing and diagnosis
Complex network analysis has an increasing relevance in the study of neurological disorders,
enhancing the knowledge of brain’s structural and functional organization. Network structure
and efficiency reveal different brain states along with different ways of processing the informa-
tion. This work is structured around the exploratory analysis of the brain processes involved
in low-level auditory processing. A complex network analysis was performed on the basis of
brain coupling obtained from electroencephalography (EEG) data, while different auditory stim-
uli were presented to the subjects. This coupling is inferred from the Phase-Amplitude coupling
(PAC) from different EEG electrodes to explore differences between control and dyslexic sub-
jects. Coupling data allows the construction of a graph, and then, graph theory is used to study
the characteristics of the complex networks throughout time for control and dyslexic subjects.
This results in a set of metrics including clustering coefficient, path length and small-worldness.
From this, different characteristics linked to the temporal evolution of networks and coupling are
pointed out for dyslexics. Our study revealed patterns related to Dyslexia as losing the small-
world topology. Finally, these graph-based features are used to classify between control and
dyslexic subjects by means of a Support Vector Machine (SVM).This work was supported by projects PGC2018-098813-B-C32 (Spanish “Ministerio de Cien-
cia, InnovaciĂłn y Universidades”), UMA20-FEDERJA-086 (ConsejerĂa de econnomĂa y conocimiento,
Junta de AndalucĂa) and by European Regional Development Funds (ERDF). We gratefully ac-
knowledge the support of NVIDIA Corporation with the donation of one of the GPUs used for
this research. Work by F.J.M.M. was supported by the MICINN “Juan de la Cierva - Incorpo-
raciĂłn” Fellowship. We also thank the Leeduca research group and Junta de AndalucĂa for the
data supplied and the support. Funding for open access charge: Universidad de Málaga / CBU
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Development of machine learning-based open-source tools for processing and analysis of extracellular neuronal signals to facilitate disease monitoring
Neuronal signals are recordings of the electrical activity of the brain, which allow gaining insight into a diverse range of information. Like other physiological signals, extensive processing and analysis must be carried out in order to extract useful information. In this context, the neuroscience community has developed different open-access tools and pipelines for the different steps involved to facilitate the studies and make more advancements in the field. The aim of the research reported in this thesis is the development of tools and pipelines to facilitate the use of machine learning techniques in chronically recorded invasive signals for early disease detection. This includes the selection of the state-of-the-art for artefact detection and removal, the processing of the signal to feed the models, and lastly a robust machine learning based classifier. The main contributions of this thesis to the application of machine learning in neuronal signal processing include an open-access tool for benchmarking the performance of artefact detection and removal with ML with over 120 articles, the creation of a toolbox with novel methods to detect and remove artefacts from extracellular neuronal signals recorded in the form of local field potentials, a novel channel independent artefact removal method based on the forecasting of normal activity to replace affected segments, an innovative ML pipeline to detect and classify brain states from the processed local field potentials, and lastly finding novel biomarkers from these models and properly assess them against the existing literature
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