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Biomedical Information Technology. Biomedical Engineering

  • Book

  • October 2007
  • Elsevier Science and Technology
  • ID: 1757578

The enormous growth in the field of biotechnology necessitates the utilization of information technology for the management, flow and organization of data. The field continues to evolve with the development of new applications to fit the needs of the biomedicine. From molecular imaging to healthcare knowledge management, the storage, access and analysis of data contributes significantly to biomedical research and practice.

All biomedical professionals can benefit from a greater understanding of how data can be efficiently managed and utilized through data compression, modelling, processing, registration, visualization, communication, and large-scale biological computing. In addition�Biomedical Information Technology�contains practical integrated clinical applications for disease detection, diagnosis, surgery, therapy, and biomedical knowledge discovery, including the latest advances in the field, such as ubiquitous M-Health systems and molecular imaging applications.

Please Note: This is an On Demand product, delivery may take up to 11 working days after payment has been received.

Table of Contents

Section I: Technological Fundamentals

Chapter 1 Medical Imaging
Dr. Xiaofeng Zhang, Dr. Nadine Smith and Prof. Andrew Webb

1.1 Introduction
1.2 Digital radiography
1.3 Computed tomography
1.4 Nuclear medicine
1.5 Ultrasonic imaging
1.6 Magnetic resonance imaging
1.7 Diffuse optical imaging
1.8 Biosignals
1.9 Appendix
1.10 Exercises
1.11 Bibliography
1.12 Index

Chapter 2 Electronic Medical Record (EMR)

Dr. Eugene,Y. S. Lim, Prof. Michael Fulham and Prof. David Dagan Feng

2.1 Introduction
2.2 Medical data and patient record
2.3 Terminology standards vocabulary and a clinical coding system1
2.4 Information exchange standards
2.5 Usability issues in EMR
2.6 User interface
2.7 Evaluation
2.8 EMR system a case study: a web-based imaging electronic patient history
2.9 Summary
2.10 Exercise
2.11 Bibliography and references
2.12 Index

Chapter 3 Image Data Compression and Storage

Prof. Hong Ren Wu, Dr. Damian M. Tan, Dr. Tom Weidong Cai and Prof. David Dagan Feng

3.1 Introduction
3.2 Picture compression
3.3 Compression in the dicom standard
3.4 Data compression for dynamic functional images
3.5 Summary
3.6 Exercises
3.7 References
3.8 Index


Chapter 4 Content-Based Medical Image Retrieval

Dr. Tom Weidong Cai, Dr. Jinman Kim and Prof. David Dagan Feng

4.1 Introduction
4.2 CBMIR by physical visual features
4.3 CBMIR by geometric spatial features
4.4 CBMIR by combination of semantic and visual features
4.5 CBMIR by physiological functional features
4.6 Summary
4.7 Exercises
4.8 Bibliography and references
4.9 Index

Chapter 5 Data Modeling and Simulation

Dr. Alessandra Bertoldo, Prof. Claudio Cobelli

5.1 Introduction
5.2 Compartmental models
5.3 Model identification
5.4 Model validation
5.5 Simulation
5.6 Case study
5.7 Quantification of medical images
5.8 Exercises
5.9 Bibliography and references

Chapter 6 Techniques for Parametric Imaging

Prof. David Dagan Feng, Dr. Lingfeng Wen and Dr. Stefan Eberl

6.1 Introduction
6.2 Parametric image estimation methods
6.3 Noninvasive methods
6.4 Clinical applications of parametric images
6.5 Summary
6.6 Exercise
6.7 Bibliography and references
6.8 Index

Chapter 7 Data Processing and Analysis

Prof. Chris Wyatt, Prof. Yu-Ping Wang, Prof. Matthew T. Freedman, Prof. Murray Loew and Prof. Yue Wang

7.1 Introduction
7.2 Medical image enhancement
7.3 Medical image segmentation
7.4 Medical image feature extraction
7.5 Medical image interpretation
7.6 Summary
7.7 Exercises
7.8 Bibliography
7.9 Index

Chapter 8 Data Registration and Fusion

Dr. Xiu Ying Wang, Dr. Stefan Eberl, Prof. Michael Fulham, Dr. Seu Som and Prof. David Dagan Feng


8.1 Introduction
8.2 Fundamentals of biomedical image registration and fusion
8.3 Feature-based medical image registration
8.4 Intensity-based registration
8.5 Hybrid registration and hierarchical registration
8.6 Hardware registration
8.7 Assessment of registration accuracy
8.8 Applications of biomedical image registration and fusion
8.9 Summary
8.10 Exercises
8.11 Bibliography and references
8.12 Index

Chapter 9 Data Visualization and Display
Dr. Jinman Kim, Dr. Tom Weidong Cai, Prof. Michael Fulham, Dr. Stefan Eberl and Prof. David Dagan Feng

9.1 Introduction
9.2 Two-Dimensional (2D) visualization techniques
9.3 Three-Dimensional (3D) visualization techniques
9.4 Volume navigation interface
9.5 Volume enhancement and manipulation
9.6 Large data visualization and optimization
9.7 Dual-modality PET/CT visualization
9.8 Data display devices
9.9 Applications of biomedical visualization
9.10 Summary
9.11 Exercises
9.12 Bibliography and references
9.13 Index

Chapter 10 Data Communication and Network Infrastructue

Prof. Doan B. Hoang and Dr. Andrew J. Simmonds

10.1 Introduction
10.2 Transmission and communication technologies
10.3 The internet and World Wide Web
10.4 Wireless and mobile technologies in m-health
10.5 Sensor networks for health monitoring
10.6 Applications of wireless technologies in telemedicine
10.7 Summary
10.8 Exercises
10.9 Bibliography and references
10.10 Index

Chapter 11 Data Security and Protection for Medical Images

Dr. Eugene, Y. S. Lim

11.1 Introduction
11.2 Overview of cryptographic system
11.3 Digital watermarking
11.4 Medical image watermarking
11.5 Region-based reversible watermarking for secure pet image management
11.6 Summary
11.7 Exercise
11.8 Bibliography
11.8 Index

Chapter 12 Biological Computing

Prof. Eric P Hoffman, Erica Reeves, Dr. Yetrib Hathout, Dr. Zuyi Wang and
Josephine Chen

12.1 Introduction
12.2 Overview of genomic methods
12.3 Overview of proteomic methods
12.4 Bioinformatics and information infrastructure
12.5 Data mining and large-scale biological databases
12.6 Biological event-driven, time-driven and hybrid simulation techniques
12.7 Summary
12.8 Bibliography


Section II: Integrated Applications

Chapter 13 PACS and Medical Imaging Informatics (MII) for Filmless Hospitals


Prof. Brent J. Liu and Prof. H.K. Huang

13.1 Introduction
13.2 PACS infrastructure
13.3 PACS components and workflow
13.4 PACS controller and image archive
13.5 Large-scale PACS implementation
13.6 PACS clinical experiences
13.7 Summary
13.8 Exercises
13.9 Bibliography and references
13.9 Index

Chapter 14 KMeX: A Knowledge-Based Digital Library for Retrieving Scenario-Specific Medical Text Documents
Prof. Wesley W. Chu, Dr. Zhenyu Liu, Dr. Wenlei Mao and Dr. Qinghua Zou

14.1 Introduction
14.2 Extracting key concepts from documents
14.3 Transforming similar queries into query templates
14.4 Topic-oriented directory
14.5 Phrase-based vector space model for automatic document retrieval
14.6 Knowledge-based scenario-specific query expansion
14.7 A system architecture for retrieving scenario-specific free text documents
14.8 Summary
14.9 Exercises
14.10 Bibliography

Chapter 15 Integrated Multimedia Patient Record Systems
Dr. Ruth E. Dayhoff, Mr. Peter M. Kuzmak and Mr. Kevin Meldrum

15.1 Introduction
15.2 Multimedia patient record
15.3 Multimedia patient record system architecture components
15.4 Electronic medical chart components
15.5 Objects comprising the multimedia patient record
15.6 Capturing multimedia data at the source
15.7 DICOM image acquisition
15.8 Remote data and image viewing across the healthcare network
15.9 Impact on patient care
15.10 Summary
15.11 References

Chapter 16 Computer-Aided Diagnosis (CAD)
Prof. Maryellen L. Giger and Dr. Kenji Suzuki

16.1 Introduction
16.2 CAD
16.3 CAD for cancer screening
16.4 CAD for differential diagnosis
16.5 Intelligent CAD workstations indices of similarity and human/computer interfaces
16.6 Summary
16.7 Exercises
16.8 Bibliography
16.9 Index

Chapter 17 Clinical Decision Support Systems (CDSS)

Dr. Peter Weller, Dr. Abdul Roudsari and Prof. Ewart Carson

17.1 Introduction
17.2 Overview of CDSS
17.3 Human diagnostic reasoning
17.4 A structure for characterising CDSS
17.5 Decision support tools
17.6 Decision support systems in the hospital and other healthcare settings
17.7 Healthcare education applications
17.8 Verification, validation and evaluation
17.9 Summary
17.10 Exercises
17.11 References
17.12 Index

Chapter 18 Medical Robotics and Computer-Integrated Interventional Medicine

Prof. Russell H. Taylor and Dr. Peter Kazanzides

18.1 Introduction
18.2 Technology & Techniques
18.3 Surgical CAD/CAM
18.4 Surgical Assistance
18.5 Summary and conclusion
18.6 Exercises
18.7 References
18.8 Index

Chapter 19 Functional Techniques for Brain Magnetic Resonance Imaging
Dr. Sirong Chen, Dr. Kai-Ming Au Yeung and Dr. Gladys Goh Lo

19.1 Introduction
19.2 Diffusion-weighted MR imaging in brain
19.3 MR perfusion imaging in brain
19.4 Functional MRI (fMRI) using bold techniques
19.5 Clinical MR spectroscopy in brain
19.6 Summary
19.7 Exercises
19.8 Bibliography and references
19.9 Index

Chapter 20 Molecular Imaging in Cancer
Prof. Kristine Glunde, Dr. Catherine A. Foss and Prof. Zaver M. Bhujwalla

20.1 Introduction
20.2 Imaging of gene expression
20.3 Receptor imaging
20.4 Enzyme-activated probes
20.5 Metabolic imaging
20.6 Imaging of permeability, perfusion, and blood flow
20.7 Imaging of the tumor microenvironment
20.8 Multimodality imaging
20.9 Conclusion
20.10 Exercises
20.11 References
20.12 Index

Chapter 21 Molecular Imaging in Biology and Pharmacology
Prof. Sung-Cheng Huang, Prof. Anna M. Wu and Prof. Jorge R. Barrio

21.1 Introduction and background
21.2 Considerations for quantitative molecular imaging
21.3 Design/development of molecular imaging probes
21.4 Molecular imaging of beta-amyloid and NFT
21.5 Molecular imaging using antibody probes
21.6 Some other molecular imaging applications
21.7 Summary and future perspectives
21.8 Exercises
21.9 References
21.10 Index

Chapter 22 From Telemedicine to Ubiquitous M-Health: the Evolution of E Health Systems

Dr. Dejan Raskovi�, Dr. Aleksandar Milenkovi�, Prof. Piet C. De Groen and
Dr. Emil Jovanov

22.1 Introduction
22.2 Overview of m-health systems
22.3 M-health based on Wireless Body Area Networks (WBAN)
22.4 Wireless intelligent sensors for m-health
22.5 Wireless mobile devices for m-health
22.6 Next-generation m-health systems
22.7 Summary
22.8 Exercises
22.9 References
22.10 Index

Chapter 23 Multimedia for Future Health Smart Medical Home......1

Dr. Jinman Kim, Dr. Zhiyong Wang, Dr. Tom Weidong Cai and Prof. David Dagan Feng

23.1 Introduction
23.2 Multimedia for human-computer interaction
23.3 Multimedia content management
23.4 Multimedia delivery
23.5 Smart medical home
23.6 Telemedicine in the smart medical home
23.7 Sensory devices and health monitoring
23.8 Speech recognition and conversational systems
23.9 Multimedia technologies for patient education and care
23.10 Multimedia operating theater and Virtual Reality (VR)
23.11 Summary
23.12 Exercises
23.13 References
23.15 Index

Authors

David Dagan Feng Director, Biomedical & Multimedia Information Technology, School of Computer Science, University of Sydney, Sydney, Australia.. Professor David Dagan Feng is Founder and Director, Biomedical and Multimedia Information Technology (BMIT) Research Group, Funding Director, Institute of Biomedical Engineering & Technology (BMET), and Funding Head, School of Information Technology (recently renamed as School of Computer Science), the University of Sydney (USYD), as well as Academic Director, USYD-SJTU (Shanghai Jiao Tong University) Joint Research Alliance. He has been, Head of Department of Computer Science and Associate Dean, Faculty of Science, the University of Sydney; Honorary Research Consultant, Royal Prince Alfred Hospital, the largest hospital in Australia; Chair Professor of Information Technology, Hong Kong Polytechnic University; Scientific Advisor, the 3D Anatomical Human European Institute / Project involving 7 countries; Advisory Professor, Chief Scientist and Chair of the International Advisory Committee, Med-X Research Institute, Shanghai Jiao Tong University; Guest Professor for a number of universities, including Tsinghua University. He received his M.E. in Electrical Engineering & Computer Science (EECS) from Shanghai Jiao Tong University in 1982, M.Sc. in Biocybernetics and Ph.D. in Computer Science from the University of California, Los Angeles (UCLA) in 1985 and 1988, respectively, where he received the Crump Prize for Excellence in Medical Engineering. In conjunction with his team members and students, he has been responsible for more than 50 key research projects, published over 900 scholarly research papers, pioneered several new research directions, and made a number of landmark contributions in his field. He has served as Chair of the International Federation of Automatic Control (IFAC) Technical Committee on Biological and Medical Systems, Special Area Editor / Associate Editor / Editorial Board Member for a dozen of core journals in his area, and Scientific Advisor for a number of prestigious organizations. He has been invited to give over 100 keynote presentations in 23 countries and regions, and has organized / chaired over 100 major international conferences / symposia / workshops. Professor Feng is Fellow of ACS, HKIE, IET, IEEE, and Australian Academy of Technological Sciences and Engineering.