Abbildung von: Multiscale Modelling in Biomedical Engineering - Wiley

Multiscale Modelling in Biomedical Engineering

Dimitrios I. FotiadisAntonis I. SakellariosVassiliki T. Potsika(Autor*in)
Wiley (Verlag)
1. Auflage
Erschienen am 2. Mai 2023
400 Seiten
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978-1-119-51730-6 (ISBN)
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Multiscale Modelling in Biomedical Engineering

Discover how multiscale modeling can enhance patient treatment and outcomes

In Multiscale Modelling in Biomedical Engineering, an accomplished team of biomedical professionals delivers a robust treatment of the foundation and background of a general computational methodology for multi-scale modeling. The authors demonstrate how this methodology can be applied to various fields of biomedicine, with a particular focus on orthopedics and cardiovascular medicine.

The book begins with a description of the relationship between multiscale modeling and systems biology before moving on to proceed systematically upwards in hierarchical levels from the molecular to the cellular, tissue, and organ level. It then examines multiscale modeling applications in specific functional areas, like mechanotransduction, musculoskeletal, and cardiovascular systems.

Multiscale Modelling in Biomedical Engineering offers readers experiments and exercises to illustrate and implement the concepts contained within. Readers will also benefit from the inclusion of:
* A thorough introduction to systems biology and multi-scale modeling, including a survey of various multi-scale methods and approaches and analyses of theirapplication in systems biology
* Comprehensive explorations of biomedical imaging and nanoscale modeling at the molecular, cell, tissue, and organ levels
* Practical discussions of the mechanotransduction perspective, including recent progress and likely future challenges
* In-depth examinations of risk prediction in patients using big data analytics and data mining

Perfect for undergraduate and graduate students of bioengineering, biomechanics, biomedical engineering, and medicine, Multiscale Modelling in Biomedical Engineering will also earn a place in the libraries of industry professional and researchers seeking a one-stop reference to the basic engineering principles of biological systems.
Reihe
Auflage
1. Auflage
Sprache
Englisch
Verlagsort
Newark
USA
Produkt-Hinweis
Reflowable
Dateigröße
11,38 MB
ISBN-13
978-1-119-51730-6 (9781119517306)
Schlagworte
orthopedic multiscale modelingcardiovascular multiscale modelingmolecular multiscale modelingcell multiscale modelingorgan multiscale modelingmultiscale modeling textbookRechnergestütztes BioengineeringComputational BioengineeringBiomaterialienBiomedizintechnikTissue Multiscale ModelingbiomedicinebiomaterialsMechanotransductionBiomaterialBiomedizinische Technik
Schweitzer Klassifikation
Biologie
Biotechnik / Gentechnik
Medizin / Pharmazie
Allgemein / Grundlagen
Technik / Architektur
Biotechnik / Gentechnik
DNB DDC Sachgruppen
Medizin, Gesundheit
Technik
Dewey Decimal Classfication (DDC)
Technology
Medicine & health
Medicine & health
BISAC Klassifikation
Medical
Science
Biotechnology
Warengruppensystematik 2.0
Naturwissenschaften, Medizin, Informatik, Technik
Medizin

Andere Ausgaben

Abbildung von: Multiscale Modelling in Biomedical Engineering - Wiley-Blackwell
Fotiadis
Multiscale Modelling in Biomedical Engineering
Buch
ca. 08/2023
1. Auflage
Wiley-Blackwell
139,00 €
Noch nicht erschienen
  • Cover
  • Title Page
  • Copyright Page
  • Contents
  • Author Biographies
  • Preface
  • List of Abbreviations
  • List of Terms
  • Chapter 1 Systems Biology and Multiscale Modeling
  • 1.1 Introduction
  • 1.2 Systems Biology
  • 1.3 Systems Biology Modeling Goals
  • 1.4 Systems Biology Modeling Approach
  • 1.5 Application of Multiscale Methods in Systems Biology
  • 1.5.1 Introduction
  • 1.6 The Use of Systems Biology and Multiscale Modeling in Biomedical and Medical Science
  • 1.7 Application of Computational Methods in Biomedical Engineering
  • 1.7.1 Fundamental Principles
  • 1.7.2 Finite Element Method
  • 1.7.3 Boundary Element Method
  • 1.7.4 Finite Differences Method
  • 1.8 Challenges
  • References
  • Chapter 2 Biomedical Imaging
  • 2.1 Introduction
  • 2.2 X-ray Radiography
  • 2.2.1 X-ray Interaction with Tissues
  • 2.2.2 Medical Applications of X-rays
  • 2.3 Computed Tomography
  • 2.3.1 The Principle of CT Imaging
  • 2.3.2 The Evolution of CT Scanners
  • 2.3.3 Medical Applications of CT Imaging
  • 2.3.3.1 Application of CT Imaging in Cancer
  • 2.3.3.2 Application of CT Imaging in Lungs
  • 2.3.3.3 Application of CT Imaging in Cardiovascular Disease
  • 2.3.3.4 Application of CT Imaging in Other Fields
  • 2.3.4 Radiation of CT Imaging
  • 2.4 Diagnostic Ultrasound
  • 2.4.1 The Principle of US
  • 2.4.2 Medical Applications of US
  • 2.5 Magnetic Resonance Imaging
  • 2.5.1 MRI Principle
  • 2.5.2 Medical Applications of MRI
  • 2.6 Positron Emission Tomography (PET)
  • 2.6.1 The Principle of PET
  • 2.6.2 Medical Applications of PET
  • 2.7 Single Photon Emission Computed Tomography
  • 2.7.1 The Principle of SPECT
  • 2.7.2 Medical Applications of SPECT
  • 2.8 Endoscopy
  • 2.8.1 Medical Applications of Endoscopy
  • 2.9 Elastography
  • 2.9.1 Elastographic Techniques
  • 2.9.2 Elastographic Medical Applications
  • 2.10 Conclusions and Future Trends
  • References
  • Chapter 3 Computational Modeling at Molecular Level
  • 3.1 Introduction
  • 3.2 Introduction to Molecular Mechanics
  • 3.2.1 Chemical Formulas
  • 3.2.2 Molecular Structure and Polarity
  • 3.2.2.1 Mathematical Modeling of Polarizing Biochemical Systems
  • 3.3 Molecular Bioengineering in Areas Critical to Human Health
  • 3.3.1 Cell Biology
  • 3.3.1.1 Biology of Growth Factor Systems
  • 3.3.2 Diagnostic Medicine
  • 3.3.2.1 Lab-on-a-Chip Devices
  • 3.3.2.2 Biosensors
  • 3.3.3 Preventive Medicine
  • 3.3.4 Therapeutic Medicine
  • 3.3.4.1 Drug Delivery
  • 3.3.4.2 Tissue Engineering
  • References
  • Chapter 4 Computational Modeling at Cell Level
  • 4.1 Introduction
  • 4.2 Introduction to Cell Mechanics
  • 4.2.1 Cell Material Properties
  • 4.2.2 Cell Composition and Structure
  • 4.3 Cellular Bioengineering in Areas Critical to Human Health
  • 4.3.1 Biology
  • 4.3.2 Diagnostic Medicine
  • 4.3.2.1 Organ Chip Technology
  • 4.3.2.2 Mechanosensors
  • 4.3.3 Therapeutic Medicine
  • 4.3.3.1 Drug Delivery
  • 4.3.3.2 Tissue Engineering
  • 4.3.4 P4 Medicine
  • References
  • Chapter 5 Computational Modeling at Tissue Level
  • 5.1 Introduction
  • 5.2 Epithelial Tissue
  • 5.2.1 Composition and Properties of Epithelial Tissue
  • 5.2.2 Computational Modeling of Epithelial Tissue
  • 5.3 Connective Tissue
  • 5.3.1 Composition and Properties of Connective Tissue
  • 5.3.2 Computational Modeling of Connective Tissue
  • 5.4 Muscle Tissue
  • 5.4.1 Composition and Properties of Muscle Tissue
  • 5.4.2 Computational Modeling of Muscle Tissue
  • 5.4.2.1 Computational Modeling of Skeletal Muscle Tissue
  • 5.4.2.2 Computational Modeling of Smooth Muscle Tissue
  • 5.4.2.3 Computational Modeling of Cardiac Muscle Tissue
  • 5.4.2.4 Musculotendon Models
  • 5.5 Nervous Tissue
  • 5.5.1 Computational Modeling of Brain Tissue
  • 5.5.2 Computational Modeling of the Spinal Cord Tissue
  • 5.5.3 Computational Modeling of Peripheral Nerves
  • 5.6 Conclusion
  • References
  • Chapter 6 Macroscale Modeling at the Organ Level
  • 6.1 Introduction
  • 6.2 The Respiratory System
  • 6.2.1 Computational Modeling of the Respiratory System
  • 6.3 The Digestive System
  • 6.3.1 Computational Modeling of the Digestive System
  • 6.4 The Cardiovascular System
  • 6.4.1 Computational Modeling of the Cardiovascular System
  • 6.5 The Urinary System
  • 6.5.1 Computational Modeling of the Urinary System
  • 6.6 The Integumentary System
  • 6.6.1 Computational Modeling of the Integumentary System
  • 6.7 The Musculoskeletal System
  • 6.7.1 Introduction to the Skeletal System
  • 6.7.2 Introduction to the Muscular System
  • 6.7.3 Computational Modeling of the Muscular-Skeletal System
  • 6.8 The Endocrine System
  • 6.8.1 Computational Modeling of the Endocrine System
  • 6.9 The Lymphatic System
  • 6.9.1 Computational Modeling of the Lymphatic System
  • 6.10 The Nervous System
  • 6.10.1 Computational Modeling of the Nervous System
  • 6.11 The Reproductive System
  • 6.11.1 Computational Modeling of the Reproductive System
  • 6.12 Conclusion
  • References
  • Chapter 7 Mechanotransduction Perspective, Recent Progress and Future Challenges
  • 7.1 Introduction
  • 7.2 Methods for Studying Mechanotransduction
  • 7.2.1 How Mechanical Forces Are Detected
  • 7.2.2 Transmission of Mechanical Forces
  • 7.2.3 Conversion of Mechanical Forces to Signals
  • 7.3 Mathematical Models of Mechanotransduction
  • 7.3.1 ODE Based Computational Model
  • 7.3.2 PDE Based Computational Model
  • 7.3.2.1 Mechanical Factors that Affect Cell Differentiation and Proliferation
  • 7.3.2.2 A Case Example of Multi-Scale Modeling Cell Differentiation and Proliferation
  • 7.3.3 Methodology of a Hybrid Multi-Scale Approach
  • 7.3.3.1 The Agent-Based Model (ABM)
  • 7.3.3.2 Mechanical Model
  • 7.4 Challenges
  • References
  • Chapter 8 Multiscale Modeling of the Musculoskeletal System
  • 8.1 Introduction
  • 8.2 Structure of the Musculoskeletal System
  • 8.2.1 Structure of the Skeletal System Components
  • 8.2.2 Structure of the Muscular System Components
  • 8.3 Elasticity
  • 8.4 Mechanical Characteristics of Muscles
  • 8.5 Multiscale Modeling Approaches of the Musculoskeletal System
  • 8.5.1 Multiscale Modeling of Bones
  • 8.5.2 Multiscale Modeling of Articular Cartilage
  • 8.5.3 Multiscale Modeling of Tendons and Ligaments
  • 8.5.3.1 Advances in Multiscale Modeling of Tendons
  • 8.5.3.2 Advances in Multiscale Modeling of Ligaments
  • 8.5.4 Multiscale Modeling of the Skeletal Muscle
  • 8.5.5 Multiscale Modeling of the Smooth Muscle
  • 8.6 Conclusion
  • References
  • Chapter 9 Multiscale Modeling of Cardiovascular System
  • 9.1 Introduction
  • 9.2 Cardiovascular Mechanics
  • 9.2.1 Visualization of the Cardiovascular System and 3D Arterial Reconstruction
  • 9.2.2 Blood Flow Modeling
  • 9.2.2.1 Steady and Pulsatile Flow of Blood
  • 9.2.2.2 Computational Fluid Dynamics Modeling
  • 9.2.2.3 Newtonian and Non-Newtonian Behavior of Blood
  • 9.2.3 Plaque Growth Modeling
  • 9.2.4 Agent-Based Modeling
  • 9.2.4.1 Key Components of Agent-Based Modelling
  • 9.2.4.2 Agent-Based Modelling and Simulation Approach
  • 9.2.4.3 Problem Definition
  • 9.2.4.4 ABM Applications in Cardiovascular Systems
  • 9.2.5 Discrete Particle Dynamics
  • 9.2.6 Multiscale Model of Drug Delivery/Restenosis
  • 9.2.6.1 Benefits of Multiscale Model of Drug Delivery/Restenosis
  • 9.3 Conclusions
  • References
  • Chapter 10 Risk Prediction
  • 10.1 Introduction
  • 10.2 Medical Data Preprocessing
  • 10.2.1 Data Sharing
  • 10.2.2 Data Harmonization
  • 10.3 Machine Learning and Data Mining
  • 10.3.1 Supervised Learning Algorithms
  • 10.3.1.1 Regression Analysis
  • 10.3.1.2 Support Vector Machines
  • 10.3.1.3 Naïve Bayes
  • 10.3.1.4 Decision Trees
  • 10.3.1.5 Ensemble Classifiers
  • 10.3.1.6 Artificial Neural Networks
  • 10.3.1.7 K-Means
  • 10.3.1.8 Spectral Clustering
  • 10.3.1.9 Hierarchical Clustering
  • 10.4 Explainable Machine Learning
  • 10.4.1 Transparency
  • 10.4.2 Evaluation and Types of Explanation
  • 10.5 Example of Predictive Models in Cardiovascular Disease
  • 10.6 Conclusion
  • References
  • Chapter 11 Future Trends
  • 11.1 Virtual Populations
  • 11.1.1 Methods for Virtual Population Generation
  • 11.1.2 A Methodological Approach for a Virtual Population
  • 11.1.2.1 Multivariate Log-Normal Distribution (log-MVND)
  • 11.1.2.2 Supervised Tree Ensembles
  • 11.1.2.3 Unsupervised Tree Ensembles
  • 11.1.2.4 Radial Basis Function-Based Artificial Neural Networks
  • 11.1.2.5 Bayesian Networks
  • 11.1.2.6 Performance Evaluation of the Quality of the Generated Virtual Patient Data
  • 11.1.3 A Novel Approach for a Virtual Population Combining Multiscale Modeling
  • 11.2 Digital Twins
  • 11.2.1 Ecosystem of the Digital Twin for Health
  • 11.2.2 An Example Workflow of a Digital Twin
  • 11.3 Integrating Multiscale Modeling and Machine Learning
  • 11.3.1 Physics-Informed NN (PINN)
  • 11.3.2 Deep NN Algorithms Inspired by Statistical Physics and Information Theory
  • 11.4 Conclusion and Future Trends
  • References
  • Index
  • EULA

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