Computational Intelligence and Deep Learning Methods for Neuro-Rehabilitation Applications
Computational Intelligence and Deep Learning Methods for Neuro-rehabilitation Applications explores the different possibilities of providing AI based neuro-rehabilitation methods to treat neurological disorders. This book provides in-depth knowledge on the challenges and solutions associated with th...
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| Format: | eBook |
| Language: | Inglés |
| Published: |
San Diego :
Elsevier Science & Technology
2023.
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| Edition: | 1st ed |
| Subjects: | |
| See on Biblioteca Universitat Ramon Llull: | https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009835420506719 |
Table of Contents:
- Front Cover
- Computational Intelligence and Deep Learning Methods for Neuro-rehabilitation Applications
- Computational Intelligence and Deep Learning Methods for Neuro-rehabilitation Applications
- Copyright
- Contents
- Contributors
- Preface
- 1 - AI-based technologies, challenges, and solutions for neurorehabilitation: A systematic mapping
- 1. Introduction
- 1.1 Artificial intelligence
- 1.2 Neurological disorders
- 2. Recent developments and involvement of artificial intelligence in healthcare and neurorehabilitation
- 3. Clinical challenges and robotic rehabilitation applications
- 3.1 Clinical challenges
- 3.2 Robotic rehabilitation applications
- 4. High-tech collaborations driving neural rehabilitation
- 4.1 Human-robot control interfaces
- 4.1.1 Digital-neural interfaces
- 4.1.2 Electromyography
- 4.1.3 Brain-computer interfaces
- 4.2 Neurorobotics
- 4.2.1 Neuroexoskeletons
- 4.2.2 Neuroprosthetics
- 4.3 Virtual and augmented reality
- 4.4 AI algorithms
- 5. Selection of AI-based supportive technologies and tools for instigating neurorehabilitation
- 6. Conclusions and future directions
- References
- Further reading
- 2 - Complex approaches for gait assessment in neurorehabilitation
- 1. Introduction
- 2. Theoretical approach of gait analysis
- 3. Gait pattern-theoretical and practical framing
- 4. Clinical applications of gait analysis in neurorehabilitation
- 4.1 Multiple sclerosis
- 4.2 Hemiparesis
- 4.3 Paraparesis postchemotherapy (postchemotherapy polyneuropathy CIPN)
- 5. Case studies
- 5.1 Case study 1
- 5.2 Case study 2
- 5.3 Case study 3
- 6. Conclusions
- References
- 3 - Deep learning method for adult patients with neurological disorders under remote monitoring
- 1. Introduction
- 2. Related works
- 2.1 Modern artificial intelligence
- 2.2 Deep learning.
- 2.3 Convolutional neural networks
- 2.4 Data source
- 2.5 Image classification
- 3. Proposed methodology
- 3.1 Image classification
- 3.2 Object detection
- 3.3 Recognition of human activity
- 3.4 System architecture
- 3.5 Monitoring application
- 4. Discussions
- 5. Conclusion
- 6. Future scope
- References
- 4 - Rehabilitation for individuals with autism spectrum disorder using mixed reality virtual assistants
- 1. Introduction
- 2. Related work
- 2.1 Common interventions in rehabilitation of ASD
- 3. Exploring the virtual world with Microsoft HoloLens
- 3.1 Microsoft HoloLens, a wearable mixed reality device
- 3.2 HoloLearn: Unpacking the mechanics of mixed reality learning
- 3.3 Exploring the world of autism: A HoloLearn activity
- 3.3.1 Setting the table activity
- 3.3.2 HoloLearn's garbage collection efforts
- 3.3.3 HoloLearn memory activity
- 3.3.4 Virtual assistant
- 3.3.5 Dress-up activity
- 4. ASD pathways: Tools for rehabilitation and progress
- 4.1 Autism XR
- 4.2 Real social skills
- 4.3 PRISMA
- 4.4 Discussions
- 5. Challenges faced
- 6. Future directions
- 7. Conclusion
- References
- 5 - Wearable sleeve for physiotherapy assessment using ESP32 and IMU sensor
- 1. Introduction
- 1.1 Existing methods
- 1.2 Scope and objectives
- 2. Literature survey
- 3. Proposed system: Materials and methodology
- 3.1 IMU sensor
- 3.2 System architecture
- 3.3 System implementation
- 3.4 Installation of mircopython on ESP32
- 3.5 Interfacing MPU9250 with ESP32
- 3.6 Graphical user interface
- 3.7 Updating the database on the server end
- 3.8 Detecting the angle of the set
- 3.9 Graphical report
- 4. Experimental results and discussion
- 4.1 Quantitative measures
- 4.2 Quality measures
- 5. Conclusion and future scope
- References.
- 6 - Machine learning for Developing neurorehabilitation-aided assistive devices
- 1. Introduction
- 1.1 Neurological disorders
- 1.2 Neurorehabilitation and assistive technology
- 2. Machine learning as a tool in assistive technology for neurorehabilitation
- 2.1 Integration of ML in assistive technology and its applications
- 3. Applications of ML-integrated assistive technology in neurorehabilitation
- 3.1 Prosthetics and orthotics
- 3.2 Augmentative and alternative communication devices
- 3.3 Adaptive computer technology
- 3.4 Mobility aids
- 3.5 Sensory aids
- 3.6 Cognitive aids
- 3.7 Environmental control
- 4. Conclusion
- References
- 7 - Deep learning and machine learning methods for patients with language and speech disorders
- 1. Introduction
- 1.1 Language and speech disorders: Types, diagnosis, and treatment
- 1.1.1 Fluency speech disorders
- 1.1.2 Resonance disorders
- 1.1.3 Voice disorders
- 1.1.4 Motor speech disorders
- 1.1.5 Language disorders
- 1.1.6 Acquired language disorders
- 1.1.7 Speech sound disorders
- 1.1.7.1 Deep learning and machine learning in AI
- 1.1.7.1 Deep learning and machine learning in AI
- 2. Research methodology
- 2.1 Research questions
- 2.2 Data collection and data analysis process
- 3. DL and ML methods for patients with SLD
- References
- 8 - Machine learning for cognitive treatment planning in patients with neurodisorder and trauma injuries
- 1. Introduction
- 1.1 Multiple sclerosis
- 1.1.1 Multiple sclerosis signs and symptoms
- 1.1.2 Treatment of multiple sclerosis
- 1.2 Parkinson's disease
- 1.2.1 Signs and symptoms of Parkinson's disease
- 1.2.2 Treatment process of Parkinson's disease
- 1.2.3 Exercise and alternative treatments
- 1.3 Importance of artificial intelligence in healthcare
- 2. Related work
- 3. Proposed methodology.
- 3.1 Methodology for predicting stroke in patients who have already had one
- 4. Results and discussion
- 5. Conclusion
- References
- 9 - Artifacts removal techniques in EEG data for BCI applications: A survey
- 1. Introduction
- 1.1 Signal capturing block
- 1.2 Processing of signals block
- 1.3 Signal preprocessing
- 1.4 Feature extraction
- 1.5 Classification
- 1.6 Application interface
- 1.7 Applications
- 1.8 Feedback
- 2. Artifacts removal techniques
- 3. Conclusion
- References
- Further reading
- 10 - Deep learning system of naturalistic communication in brain-computer interface for quadriplegic patient
- 1. Introduction
- 2. Related works
- 3. Dataset
- 4. Methodology
- 4.1 Convolutional neural network
- 4.1.1 CNN layers
- 4.1.2 Pooling layer
- 4.1.3 Fully connected layer
- 4.2 AlexNet
- 4.2.1 Softmax
- 4.2.2 ReLU
- 4.2.3 Data augmentation
- 4.2.4 Dropout
- 4.3 Computer vision
- 4.4 Image recognition
- 5. Experimental results
- 6. Discussion
- 7. Conclusion
- References
- 11 - Motor imaginary tasks-based EEG signals classification using continuous wavelet transform and LSTM network
- 1. Introduction
- 2. Material and methodology
- 2.1 Dataset (PhysioNet)
- 2.2 EEG preprocessing and feature extraction
- 2.2.1 Continuous wavelet transform
- 2.2.2 Features
- 2.2.2.1 Entropy features
- 2.2.2.1 Entropy features
- 2.2.2.1.1 Shannon Entropy
- 2.2.2.1.1 Shannon Entropy
- 2.2.2.1.2 Sure entropy
- 2.2.2.1.2 Sure entropy
- 2.2.2.2 Statistical features
- 2.2.2.2 Statistical features
- 2.2.2.2.1 Mean
- 2.2.2.2.1 Mean
- 2.2.2.2.2 Standard deviation
- 2.2.2.2.2 Standard deviation
- 2.2.2.2.3 Skewness
- 2.2.2.2.3 Skewness
- 2.2.2.2.4 Normalized standard deviation
- 2.2.2.2.4 Normalized standard deviation
- 2.2.2.2.5 Kurtosis
- 2.2.2.2.5 Kurtosis
- 2.2.2.2.6 Energy
- 2.2.2.2.6 Energy.
- 2.2.2.2.7 Normalized energy
- 2.2.2.2.7 Normalized energy
- 2.2.2.3 Fractal dimension
- 2.2.2.3 Fractal dimension
- 2.2.2.3.1 Higuchi fractal dimension
- 2.2.2.3.1 Higuchi fractal dimension
- 2.2.2.3.2 Katz fractal dimension
- 2.2.2.3.2 Katz fractal dimension
- 2.3 Classification
- 2.3.1 Long short-term memory technique
- 2.3.1.1 Results and discussions
- 2.3.1.1 Results and discussions
- 2.4 Performance measures
- 2.5 Classification performance evaluation
- 3. Conclusion
- References
- Further reading
- 12 - Enhancing human brain activity through a systematic study conducted using graph theory and probability concept ...
- 1. Introduction
- 2. Methodology
- 2.1 Bayesian inference
- 2.2 Probability density
- 3. Hydar influence in brain activity
- 3.1 Movement of actual robot
- 4. Artificial intelligence framework
- 5. Experiments conducted using Hydar
- 5.1 Experiment-The first
- 5.2 Experiment-Observe what is expected
- 5.3 Experiment-Different forward models
- 5.4 Experiment-Higher embedding orders
- 5.5 Experiment-Colored noise
- 5.6 Experiment-White noise
- 5.7 Plotting 4D probabilistic atlas maps
- 5.8 Plotting a statistical map
- 5.9 Glass brain visualization
- 6. Survey on impact of technology in mental health
- 6.1 Have/had mental health disorder
- 6.2 Companies taking mental health seriously
- 6.3 Discussing mental health at work
- 6.4 Mental health having consequences on career
- 6.5 Being open about mental health with friends and family
- 6.6 Percentages of people with mental health disorders out of all respondents in the United States
- 7. Conclusion
- References
- Index
- Back Cover.
