1 option
Medical image recognition, segmentation and parsing : machine learning and multiple object approaches / edited by S. Kevin Zhou.
- Format:
- Book
- Series:
- The Elsevier and MICCAI Society Book Series
- Language:
- English
- Subjects (All):
- Imaging systems in medicine--Evaluation.
- Imaging systems in medicine.
- Imaging systems in medicine--Equipment and supplies.
- Physical Description:
- 1 online resource (548 p.)
- Place of Publication:
- London, England : Academic Press, 2016.
- Language Note:
- English
- Summary:
- This book describes the technical problems and solutions for automatically recognizing and parsing a medical image into multiple objects, structures, or anatomies. It gives all the key methods, including state-of- the-art approaches based on machine learning, for recognizing or detecting, parsing or segmenting, a cohort of anatomical structures from a medical image.Written by top experts in Medical Imaging, this book is ideal for university researchers and industry practitioners in medical imaging who want a complete reference on key methods, algorithms and applications in medical image recognition, segmentation and parsing of multiple objects.Learn:- Research challenges and problems in medical image recognition, segmentation and parsing of multiple objects- Methods and theories for medical image recognition, segmentation and parsing of multiple objects- Efficient and effective machine learning solutions based on big datasets- Selected applications of medical image parsing using proven algorithms- Provides a comprehensive overview of state-of-the-art research on medical image recognition, segmentation, and parsing of multiple objects- Presents efficient and effective approaches based on machine learning paradigms to leverage the anatomical context in the medical images, best exemplified by large datasets- Includes algorithms for recognizing and parsing of known anatomies for practical applications
- Contents:
- Front Cover; Medical Image Recognition, Segmentation and Parsing: Machine Learning and Multiple Object Approaches; Copyright; Contents; Foreword; Acknowledgments; Contributors; Chapter 1: Introduction to Medical Image Recognition; 1.1 Introduction; 1.2 Challenges and Opportunities; 1.3 Rough-to-Exact Object Representation; 1.4 Simple-to-Complex Probabilistic Modeling; 1.4.1 Chain Rule; 1.4.2 Bayes' Rule and the Equivalence of Probabilistic Modelingand Energy-Based Method; 1.4.3 Practical Medical Image Recognition, Segmentation, and Parsing Algorithms
- 1.5 Medical Image Recognition Using Machine Learning Methods1.5.1 Object Detection and Context; 1.5.2 Machine Learning Methods; 1.5.2.1 Classification; 1.5.2.2 Regression; 1.6 Medical Image Segmentation Methods; 1.6.1 Simple Image Segmentation Methods; 1.6.2 Active Contour Method; 1.6.3 Variational Methods; 1.6.4 Level Set Methods; 1.6.5 Active Shape Models and Active Appearance Models; 1.6.6 Graph Cut Method; 1.7 Conclusions; Recommended Notations; Notes; References; Part 1: AutomaticRecognition and DetectionAlgorithms; Chapter 2: A Survey of Anatomy Detection; 2.1 Introduction
- 2.2 Methods for Detecting an Anatomy2.2.1 Classification-Based Detection Methods; 2.2.1.1 Boosting detection cascade; 2.2.1.2 Probabilistic boosting tree; 2.2.1.3 Randomized decision forest; 2.2.1.4 Exhaustive search to handle pose variation; 2.2.1.5 Parallel, pyramid, and tree structures; 2.2.1.6 Network structure: Probabilistic boosting network; 2.2.1.7 Marginal space learning; 2.2.1.8 Probabilistic, hierarchical, and discriminant framework; 2.2.1.9 Multiple instance boosting to handle inaccurate annotation; 2.2.2 Regression-Based Detection Methods; 2.2.2.1 Shape regression machine
- 2.2.2.2 Hough forest2.2.3 Classification-Based vs Regression-Based Object Detection; 2.3 Methods for Detecting Multiple Anatomies; 2.3.1 Classification-Based Methods; 2.3.1.1 Discriminative anatomical network; 2.3.1.2 Active scheduling; 2.3.1.3 Submodular detection; 2.3.1.4 Integrated detection network; 2.3.2 Regression-Based Method: Regression Forest; 2.3.3 Combining Classification and Regression: Context Integration; 2.4 Conclusions; References; Chapter 3: Robust Multi-Landmark Detection Based on Information Theoretic Scheduling; 3.1 Introduction; 3.2 Literature Review; 3.3 Methods
- 3.3.1 Problem Statement3.3.2 Scheduling Criterion Based on Information Gain; 3.3.3 Monte-Carlo Simulation Method for the Evaluation of Information Gain; 3.3.4 Implementation; Learning-based landmark detection; Spatial correlation across landmarks; 3.4 Applications; 3.4.1 Automatic View Identification of Radiographs; 3.4.2 Auto-Alignment for MR Knee Scan Planning; 3.4.3 Auto-Navigation for Anatomical Measurement in CT; 3.4.4 Automatic Vertebrae Labeling; 3.4.5 Virtual Attenuation Correction of Brain PET Images; 3.4.6 Bone Segmentation in MR for PET-MR Attenuation Correction; 3.5 Conclusion
- Note
- Notes:
- Description based upon print version of record.
- Includes bibliographical references and index.
- Description based on online resource; title from PDF title page (ebrary, viewed January 15, 2016).
- ISBN:
- 9780128026762
- 0128026766
The Penn Libraries is committed to describing library materials using current, accurate, and responsible language. If you discover outdated or inaccurate language, please fill out this feedback form to report it and suggest alternative language.