Machine Learning and Deep Learning Techniques for Medical Science

This document was uploaded by one of our users. The uploader already confirmed that they had the permission to publish it. If you are author/publisher or own the copyright of this documents, please report to us by using this DMCA report form.

Simply click on the Download Book button.

Yes, Book downloads on Ebookily are 100% Free.

Sometimes the book is free on Amazon As well, so go ahead and hit "Search on Amazon"

The application of machine learning is growing exponentially into every branch of business and science, including medical science. This book presents the integration of machine learning (ML) and deep learning (DL) algorithms that can be applied in the healthcare sector to reduce the time required by doctors, radiologists, and other medical professionals for analyzing, predicting, and diagnosing the conditions with accurate results. The book offers important key aspects in the development and implementation of ML and DL approaches toward developing prediction tools and models and improving medical diagnosis.

The contributors explore the recent trends, innovations, challenges, and solutions, as well as case studies of the applications of ML and DL in intelligent system-based disease diagnosis. The chapters also highlight the basics and the need for applying mathematical aspects with reference to the development of new medical models. Authors also explore ML and DL in relation to artificial intelligence (AI) prediction tools, the discovery of drugs, neuroscience, diagnosis in multiple imaging modalities, and pattern recognition approaches to functional magnetic resonance imaging images.

This book is for students and researchers of computer science and engineering, electronics and communication engineering, and information technology; for biomedical engineering researchers, academicians, and educators; and for students and professionals in other areas of the healthcare sector.

    • Presents key aspects in the development and the implementation of ML and DL approaches toward developing prediction tools, models, and improving medical diagnosis

    • Discusses the recent trends, innovations, challenges, solutions, and applications of intelligent system-based disease diagnosis

    • Examines DL theories, models, and tools to enhance health information systems

    • Explores ML and DL in relation to AI prediction tools, discovery of drugs, neuroscience, and diagnosis in multiple imaging modalities

    Dr. K. Gayathri Devi is a Professor at the Department of Electronics and Communication Engineering, Dr. N.G.P Institute of Technology, Tamil Nadu, India.

    Dr. Kishore Balasubramanian is an Assistant Professor (Senior Scale) at the Department of EEE at Dr. Mahalingam College of Engineering & Technology, Tamil Nadu, India.

    Dr. Le Anh Ngoc is a Director of Swinburne Innovation Space and Professor in Swinburne University of Technology (Vietnam).

    Author(s): K. Gayathri Devi, Kishore Balasubramanian, Le Anh Ngoc
    Series: Artificial Intelligence (AI): Elementary to Advanced Practices
    Publisher: CRC Press
    Year: 2022

    Language: English
    Pages: 412
    City: Boca Raton

    Cover
    Half Title
    Series Page
    Title Page
    Copyright Page
    Contents
    Editor Biographies
    Contributors
    1. A Comprehensive Study on MLP and CNN, and the Implementation of Multi-Class Image Classification using Deep CNN
    1.1 Introduction
    1.2 The Processes of the Neural Network
    1.2.1 Basics of Neural Network
    1.2.1.1 Architecture of Neural Network
    1.2.1.2 Working Principles of Neural Network
    1.2.1.3 Learning Methods of Neural Network
    1.2.1.4 Drawbacks of Neural Network
    1.2.2 Convolutional Neural Network (CNN) Algorithm
    1.2.2.1 Merits of CNN over MLP
    1.2.2.2 Contents of CNN
    1.2.2.3 Working of CNN Algorithm
    1.2.2.3.1 Convolution Layer
    Padding
    Striding
    1.2.2.3.2 Pooling Layer
    Pooling Layer Types
    1.2.2.3.3 Fully Connected Layer (FC)
    1.2.2.3.4 Dropout
    1.2.2.3.5 Activation Functions
    1.2.2.4 Deep CNN
    1.3 Experimental Procedure
    1.3.1 Preparing the Dataset
    1.3.2 Model Training and Testing
    1.4 Results and Discussion
    1.4.1 MNIST Dataset Image Classifications
    1.4.2 CIFAR-10 Dataset Image Classifications
    1.5 Conclusion
    References
    2. An Efficient Technique for Image Compression and Quality Retrieval in Diagnosis of Brain Tumour Hyper Spectral Image
    2.1 Introduction
    2.2 Literature Survey
    2.2.1 Proposed System
    2.2.2 Data Latches with D-flip Flops
    2.2.3 Discussion and Results of the Simulation
    2.3 Conclusion
    References
    3. Classification of Breast Thermograms using a Multi-layer Perceptron with Back Propagation Learning
    3.1 Introduction
    3.2 Related Works
    3.3 Methods & Materials
    3.3.1 Pre-processing of Thermograms & Region of Interest (ROI) Segmentation
    3.3.2 Feature Extraction & Selection
    3.3.3 Designing Steps of a Multi-Layer Perceptron with Back Propagation Learning
    3.3.3.1 Phase I: Feedforward Computations
    3.3.3.2 Phase II: Back Propagation of the Error
    3.3.3.3 Phase III: Update Weights and Error in the Output and Hidden Units
    3.4 Performance Evaluation Parameters
    3.5 Classification Results & Discussion
    3.5.1 ANN Model with 5 Neurons in Hidden Layer
    3.5.2 ANN Model with 10 Neurons in Hidden Layer
    3.5.3 ANN Model with 15 Neurons in Hidden Layer
    3.6 Conclusion & Future Work
    References
    4. Neural Networks for Medical Image Computing
    4.1 Introduction
    4.2 Structure of Neural Network
    4.3 Learning Process in Neural Networks
    4.3.1 Supervised Learning
    4.3.1.1 An Overview of Supervised Learning
    4.3.1.2 Supervised Learning in Medical Image Processing
    4.3.2 Unsupervised Learning
    4.3.2.1 Unsupervised Learning
    4.3.2.2 Overview of Competitive Learning
    4.3.2.3 Medical Analysis using Unsupervised Learning
    4.3.3 Reinforcement Learning
    4.3.3.1 Reinforcement Learning
    4.3.3.2 Overview of Q-Learning
    4.3.3.3 Adopting Reinforcement Learning in Health Sector
    4.4 Types of Neural Networks
    4.4.1 Perceptron
    4.4.1.1 Perceptron
    4.4.1.2 Perceptron in Medical Image Analysis
    4.4.2 Radial Basis Function Network
    4.4.2.1 Architecture of Radial Basis Function Network
    4.4.2.2 Implementing Radial Basis Function in Medical Analysis
    4.4.3 Convolutional Neural Network
    4.4.3.1 Architecture of Convolutional Neural Network
    4.4.3.2 Convolutional Neural Networks in Medical Diagnosis
    4.4.4 Recurrent Neural Network
    4.4.4.1 Introduction to Recurrent Neural Network
    4.4.4.2 Types of Recurrent Neural Network
    4.4.4.3 Medical Analysis using Recurrent Neural Network
    4.4.5 Hopfield Neural Network
    4.4.5.1 Overview of Hopfield Neural Network
    4.4.5.2 Hopfield Neural Network in Medical Diagnosis
    4.5 Conclusion
    References
    5. Recent Trends in Bio-Medical Waste, Challenges and Opportunities
    5.1 Introduction
    5.2 Waste Disposal
    5.3 Health Care Industries
    5.4 Conclusion
    References
    6. Teager-Kaiser Boost Clustered Segmentation of Retinal Fundus Images for Glaucoma Detection
    6.1 Preamble
    6.2 Methodology
    6.2.1 Nonlinear Teager-Kaiser Filtering Technique
    6.2.2 Teager-Kaiser Boost Clustered Segmentation
    6.2.3 Clinical Feature Extraction
    6.3 Results and Discussion
    6.3.1 Quantitative Analysis
    6.4 Conclusion
    References
    7. IoT-Based Deep Neural Network Approach for Heart Rate and SpO2 Prediction
    7.1 Introduction
    7.1.1 Related Work
    7.1.2 Motivations
    7.2 Materials and Methods
    7.2.1 Complete DNN-based System
    7.2.2 Principal Component Analysis (PCA)
    7.2.3 DNN Model
    7.2.4 Cloud Computing
    7.3 Results
    7.3.1 DNN Model Accuracy Performance
    7.3.2 System Validation
    7.3.2.1 Bland-Altman Analysis
    7.3.2.2 R2 (Coefficient of Determination) Regression Score Function
    7.3.3 Performance Analysis Criteria
    7.4 Discussion
    7.5 Conclusion
    References
    8. An Intelligent System for Diagnosis and Prediction of Breast Cancer Malignant Features using Machine Learning Algorithms
    8.1 Introduction
    8.2 Machine Learning Technologies
    8.2.1 Naïve Bayes
    8.2.2 K-Nearest Neighbor
    8.2.3 Random Forest
    8.2.4 Support Vector Machine
    8.3 Related Work
    8.4 Proposed Methodology
    8.4.1 Experimental Results and Discussions
    8.4.1.1 Efficiency
    8.5 Conclusion
    References
    9. Medical Image Classification with Artificial and Deep Convolutional Neural Networks: A Comparative Study
    9.1 Introduction
    9.2 Machine and Deep Learning Methods
    9.2.1 Machine Learning Techniques
    9.2.1.1 Supervised Learning
    9.2.1.2 Unsupervised Learning
    9.2.1.3 Semi-Supervised Learning
    9.2.1.4 Reinforcement Learning
    9.2.1.5 Deep Learning
    9.2.2 Deep Learning Techniques
    9.2.2.1 DL Definitions
    9.2.2.2 DL Class
    9.2.2.3 Deep Architectures
    9.3 Comprehensive Study
    9.3.1 Concept of Brain MRI Data
    9.3.2 Image Classification for Medical Disease Diagnosis
    9.3.3 Medical Image Classification for Machine and Deep Learning
    9.4 Comparative Study
    9.5 Artificial and Convolutional Deep Neural Networks based on Medical Image Classification for Alzheimer Disease
    9.5.1 Brain MRI Datasets
    9.5.2 MRI Data Pre-processing
    9.5.3 Features Extraction and Selection from Brain MRI Datasets
    9.5.4 Classification Methods
    9.5.5 Proposed Machine-Deep Model
    9.6 Discussion and Conclusion
    References
    10. Convolutional Neural Network for Classification of Skin Cancer Images
    10.1 Introduction
    10.2 State-of-the-Art
    10.3 Materials and Methods
    10.3.1 Data Preprocessing and Augmentation
    10.3.2 Data Augmentation
    10.3.3 Classification Models
    10.3.3.1 Convolutional Neural Network (CNN)
    10.3.3.2 Transfer Learning and Pre-trained Models
    10.3.3.3 Pre-trained Xception Model
    10.3.3.4 Xception Model Fine-tuning
    10.3.3.5 Evaluation Metrics
    10.4 Experimental Results
    10.4.1 Learning Performance
    10.4.2 Classification Results
    10.4.3 Comparative Study
    10.5 Conclusion and Perspectives
    References
    11. Application of Artificial Intelligence in Medical Imaging
    11.1 Introduction
    11.2 Machine Learning
    11.2.1 Supervised Learning
    11.2.2 Unsupervised Learning
    11.2.3 Semi-supervised Learning
    11.2.4 Active Learning
    11.2.5 Reinforcement Learning
    11.2.6 Evolutionary Learning
    11.2.7 Deep Learning
    11.3 Use of Machine Learning for Medical Imaging
    11.4 Deep Learning in Medical Imaging
    11.4.1 Image Categorisation
    11.4.2 Object Classification
    11.4.3 Organ or Region Detection
    11.4.4 Data Mining
    11.4.5 The Sign-up Process
    11.5 Summary
    References
    12. Machine Learning Algorithms Used in Medical Field with a Case Study
    12.1 Introduction
    12.2 Machine Learning Algorithms
    12.2.1 Supervised Learning
    12.2.2 Unsupervised Learning
    12.2.3 Reinforcement Learning
    12.2.4 Semi-Supervised Learning
    12.2.5 Regression Algorithms
    12.2.6 Instance-based Algorithms
    12.2.7 Regularization Algorithms
    12.2.8 Decision Tree Algorithms
    12.2.9 Bayesian Algorithms
    12.2.10 Clustering Algorithms
    12.2.11 Association Rule Learning Algorithms
    12.2.12 Artificial Neural Network Algorithms
    12.2.13 Deep Learning Algorithms
    12.2.14 Dimensionality Reduction Algorithms
    12.2.15 Ensemble Algorithms
    12.3 ML Algorithms in Medical Diagnosis
    12.4 ML Classifiers in Breast Cancer Diagnosis
    12.4.1 Logistic Regression
    12.4.2 K-Nearest Neighbor (k-NN) Algorithm
    12.4.3 Support Vector Machine
    12.4.4 Random Forest Classifier
    12.4.5 Naive Bayes Classifier
    12.4.6 Decision Tree Classifiers
    12.4.7 Dimensionality Reduction Algorithms
    12.5 Materials and Methods
    12.6 Conclusion
    References
    13. Dual Customized U-Net-based Automated Diagnosis of Glaucoma
    13.1 Introduction
    13.2 Literature Review
    13.3 Proposed Work
    13.4 Performance Measures
    13.5 Simulation Results
    13.5.1 Optic Disc Segmentation
    13.6 Conclusion
    References
    14. MuSCF-Net: Multi-scale, Multi-Channel Feature Network Using Resnet-based Attention Mechanism for Breast Histopathological Image Classification
    14.1 Introduction
    14.2 Related Studies
    14.3 Contribution
    14.4 Material and Methods
    14.4.1 BREAKHIS Database
    14.4.2 Methodology
    14.4.3 Preprocessing
    14.4.3.1 Patch Creation
    14.4.3.2 Augmentation
    14.4.3.3 MuSCF-Net Mechanism
    14.4.3.3.1 Convolution of filter bank for feature extraction
    14.4.3.3.2 Convolution Block Attention Module (CBMA) Integrated with ResBlock in ResNet
    14.4.3.3.2.1 CBMA Integrated with ResBlockin Resnet
    14.4.3.3.2.2 Channel Attention (CA) Module
    14.4.3.3.2.3 Spatial Attention (SA) Module
    14.4.3.3.2.4 ResBlock in Resnet [24]
    14.4.3.3.2.5 Global Average Pooling Layer
    14.4.3.3.2.6 Dropout Layer
    14.4.3.3.2.7 Dense Block
    14.4.4 Training Details
    14.4.4.1 Adam Optimizer [37]
    14.4.4.2 Activation Function
    14.4.4.3 ReLU
    14.4.4.4 Softmax Activation Function
    14.4.4.5 Loss
    14.5 Results and Discussion
    14.6 Conclusion
    References
    15. Artificial Intelligence is Revolutionizing Cancer Research
    15.1 Introduction
    15.2 Development of Artificial Intelligence in Medical Research
    15.3 AI in Different Cancer Treatment Modalities
    15.3.1 Drug Development
    15.3.2 Chemotherapy
    15.3.3 Radiotherapy
    15.3.4 Immunotherapy
    15.3.5 Identifying Drug Targets
    15.4 AI in Cancer Prediction at an Early Stage
    15.5 Future Perspective in AI
    15.6 Conclusion
    References
    16. Deep Learning to Diagnose Diseases and Security in 5G Healthcare Informatics
    16.1 Introduction
    16.2 Key Types of Learning Methods Used to Solve 5G Problems
    16.2.1 Supervised Learning
    16.2.2 Unsupervised Learning
    16.2.3 Reinforcement Learning
    16.3 Main Deep Learning Techniques Used in 5G Scenarios
    16.3.1 Fully Connected Models
    16.3.2 Recurrent Neural Networks
    16.3.3 CNN
    16.3.4 DBN
    16.3.5 Autoencoder
    16.3.6 Combining Models
    16.4 Most Common Scenarios Used for 5G Assessment and Deep Learning Integration
    16.5 Applications of Machine Learning and Deep Learning for 5G Security
    16.6 Blockchain Technology in Healthcare
    16.7 Evolution of Machine Learning in Disease Detection
    16.7.1 Supervised Learning
    16.7.1.1 K-Nearest Neighbour (KNN)
    16.7.1.2 Support Vector Machine (SVM)
    16.7.1.3 Decision Trees (DTs)
    16.7.1.4 Classification and Regression Trees (CARTs)
    16.7.1.5 Logistic Regression (LR)
    16.7.1.6 Random Forest Algorithm (RFA)
    16.7.1.7 Naive Bayes (NB)
    16.7.1.8 Artificial Neural Network (ANN)
    16.7.2 Unsupervised Learning
    16.7.3 Semi-supervised Learning
    16.7.4 Evolutionary Learning
    16.7.5 Active Learning
    16.7.6 Reinforcement Learning
    16.7.7 Ensemble Learning
    16.7.8 Deep Learning
    16.7.9 Transfer Learning
    16.7.9.1 Feature Extraction
    16.7.9.2 Fine-tuning
    16.8 Applications of Deep Learning in Disease Diagnosis
    16.8.1 ML/DL in Healthcare: The Large Picture
    16.8.2 A Look at the Healthcare Applications of ML and DL
    16.9 Deep Learning in Disease Diagnosis: To Save Lives and Cuts Treatment Costs
    16.9.1 Breast Cancer
    16.9.2 Early Detection of Melanoma: Skin Cancer
    16.9.3 Lung Cancer
    16.9.4 Testing for Diabetic Retinopathy
    16.9.5 Assessment of Cardiac Hazard from ECG Data
    16.9.6 Using CT Scans of the Head to Detect Strokes Early
    16.10 Benefits of Deep Learning
    16.11 Scope of Deep Learning Techniques for Disease Diagnosis
    16.12 A Deep Learning-Based Approach to Detect Neurodegenerative Diseases: Multiclass Classification (Case Study-1)
    16.12.1 Material and Methods
    16.12.1.1 ADPP Dataset Description
    16.12.1.2 VGG 19 Architecture
    16.12.2 Results and Discussion of the Above Discussed Framework
    16.13 Pneumonia Detection using Deep Learning (Case Study-2)
    16.13.1 Methodology
    16.13.1.1 Structural Units
    16.13.1.2 Architecture of CovXNet
    16.13.1.3 Stacking of Multiple Networks
    16.13.1.4 Transfer Learning Method of CovXNet for New Corona Virus Data
    16.13.1.5 Network Training and Optimisation
    16.13.2 Results and Discussions
    16.13.2.1 Datasets
    16.13.2.2 Evaluation of Performance
    16.14 Early Detection of Deep Learning-based Diabetic Retinopathy (Case Study-3)
    16.14.1 Datasets Used
    16.14.2 Metric Assessment
    16.14.2.1 Quadratic Weighted Kappa (QWK)
    16.14.2.2 Intuition of Cohen's Kappa
    16.14.2.3 Quadratic Weight Intuition in Ordinary Classes — Quadratic Weighted Kappa (QWK)
    16.14.3 Method
    16.14.3.1 Image Pre-processing and Augmentations
    16.14.3.2 Network Architecture
    16.14.3.3 Training Process
    16.14.4 Results
    16.14.4.1 Model Evaluation on Test Data
    16.14.4.2 Other Transfer Learning Models
    16.15 Conclusion
    References
    17. New Approaches in Machine-based Image Analysis for Medical Oncology
    17.1 Introduction
    17.2 Classical Methods
    17.3 Machine Learning Methods in Oncology
    17.3.1 Supervised Learning
    17.3.1.1 Support Vector Machine
    17.3.1.2 Logistic or Linear Regression (LR)
    17.3.1.3 Decision Tree
    17.3.1.4 Random Forest Algorithm (RF)
    17.3.1.5 Naive Bayes
    17.3.1.6 K-Nearest Neighbour
    17.3.1.7 Artificial Neural Network
    17.3.2 Unsupervised Learning
    17.3.2.1 K-means Clustering
    17.3.2.2 Principle Component Analysis
    17.3.2.3 Independent Component Analysis
    17.3.2.4 Autoencoders
    17.3.2.5 Singular Value Decomposition
    17.3.3 Reinforcement Learning (RL)
    17.4 Application of ML in Oncology
    17.4.1 Brain Oncology
    17.4.2 Skin Oncology
    17.4.3 Breast Cancer Prognosis Prediction
    17.4.4 ML in Lung Oncology
    17.4.5 Gastric Oncology
    17.5 Discussion
    17.5.1 ML Program Performance Analysis
    17.5.2 Pros and Cons of ML Algorithm
    17.5.3 ML in Cancer Staging
    17.5.4 Predicting and Evaluating Treatment Response
    17.6 Conclusion
    References
    18. Performance Analysis of Deep Convolutional Neural Networks for Diagnosing COVID-19: Data to Deployment
    18.1 Introduction
    18.2 Literature Review
    18.3 The Attributes of the Dataset and Visualizations to Interpret the Data
    18.4 The Model Formulation to Classify the Data to Diagnose COVID-19
    18.4.1 InceptionResNetV2
    18.4.2 ResNet152V2
    18.4.3 Xception
    18.4.4 DenseNet201
    18.5 Loss Function: Categorical Cross Entropy
    18.6 Evaluation Metrics and Results
    18.7 Model Deployment
    18.7.1 Designing the Website
    18.7.2 An Overview of Deployment
    18.7.3 Working of Website
    18.8 Conclusion
    References
    19. Stacked Auto Encoder Deep Neural Network with Principal Components Analysis for Identification of Chronic Kidney Disease
    19.1 Introduction
    19.2 Methodology
    19.2.1 Stacked Auto-encoder Deep Neural Network
    19.2.2 Principal Component Analysis (PCA)
    19.3 Result and Discussion
    19.4 Conclusion
    References
    Index