Computed tomography : principles, design, artifacts, and recent advances

2021 marks the 50th anniversary of x-ray computed tomography (CT). Over the years, CT has experienced tremendous technological development, driven mainly by clinical needs but also by technology advancements in other fields. Six years after the third edition of Computed Tomography, this fourth edition captures the most recent advances in technology and clinical applications. New to this edition are descriptions of artificial intelligence, machine learning, and deep learning, and their application to image reconstruction, protocol optimization, and workflow. A new chapter covers the principles and advances in dual-energy and spectral CT. A new detector technology, the photon-counting detector, is described in detail, and its impact on CT system and clinical applications is analyzed. Many exciting developments in clinical applications, such as cardiac functional imaging and stroke management, are also covered in detail.

Preface Nomenclature and Abbreviations 1 Introduction 1.1 Conventional X-ray Tomography 1.2 History of Computed Tomography 1.3 Different Generations of CT Scanners 1.4 Problems References 2 Preliminaries 2.1 Mathematics Fundamentals 2.1.1 Fourier transform and convolution 2.1.2 Random variables 2.1.3 Linear algebra 2.2 Fundamentals of X-ray Physics 2.2.1 Production of x rays 2.2.2 Interaction of x rays with matter 2.3 Measurement of Line Integrals and Data Conditioning 2.4 Sampling Geometry and Sinogram 2.5 Artificial Intelligence, Machine Learning, and Deep Learning 2.5.1 Overview of AI development 2.5.2 Neural network structure 2.5.3 Neural network training 2.5.4 Recent advances in DL 2.6 Problems References 3 Image Reconstruction 3.1 Introduction 3.2 Intuitive Approach to Image Reconstruction 3.3 The Fourier Slice Theorem 3.4 The Filtered Backprojection Algorithm 3.4.1 Derivation of the filtered back-projection formula 3.4.2 Computer implementation 3.4.3 Targeted reconstruction 3.5 Fan-Beam Reconstruction 3.5.1 Reconstruction formula for equiangular sampling 3.5.2 Reconstruction formula for equally spaced sampling 3.5.3 Fan-beam to parallel-beam rebinning 3.6 Iterative Reconstruction 3.6.1 Mathematics verses reality 3.6.2 The general approach to iterative reconstruction 3.6.3 Algebraic reconstruction 3.6.4 System modeling process 3.6.5 Optimization algorithms 3.6.6 Image quality benefit of model-based iterative reconstruction 3.6.7 Reconstruction speedup 3.7 Deep Learning-based Reconstruction 3.7.1 General approach 3.7.2 Training dataset selection 3.7.3 Determination of the training dataset size 3.7.4 Examples of DL-based reconstruction 3.8 Problems Reference 4 Image Presentation 4.1 CT Image Display 4.2 Volume Visualization 4.2.1 Multiplanar reformation 4.2.2 MIP, minMIP, and volume rendering 4.2.3 Surface rendering 4.3 Impact of Visualization Tools 4.4 Volume Visualization 4.4.1 Clinical utility 4.4.2 Hardware technologies 4.4.3 File format 4.4.4 Typical 3D printing workflow 4.5 Problems References 5 Key Performance Parameters of the CT Scanner 5.1 High-Contrast Spatial Resolution 5.1.1 In-plane resolution 5.1.2 Slice sensitivity profile 5.2 Low-Contrast Resolution 5.2.1 Factors impacting low-contrast detectability 5.2.2 LCD phantoms 5.2.3 LCD evaluation methodologies 5.3 Temporal Resolution 5.4 CT Number Accuracy and Noise 5.5 Impact of Iterative Reconstruction on Performance Measurement 5.5.1 Performance-metric-based approach 5.5.2 Task-based approach 5.5.3 Surrogate task with clinical data 5.5.4 Surrogate task with nonclinical data 5.6 Performance of the Scanogram 5.7 Problems References 6 Major Components of the CT Scanner 6.1 System Overview 6.2 The X-ray Tube and High-Voltage Generator 6.3 The X-ray Detector and Data-Acquisition Electronics 6.3.1 Direct-conversion gas detector 6.3.2 Indirect-conversion solid-state detector 6.3.3 Direct-conversion semiconductor detector 6.3.4 General performance parameters 6.3.5 Specific performance parameters 6.4 The Gantry and Slip Ring 6.5 Collimation and Filtration 6.6 The Reconstruction Engine 6.7 The Patient Table 6.8 Problems References 7 Image Artifacts: Appearances, Causes, and Corrections 7.1 What Is an Image Artifact? 7.2 Different Appearances of Image Artifacts 7.3 Artifacts Related to System Design 7.3.1 Aliasing 7.3.2 Partial volume 7.3.3 Scatter 7.3.4 Noise-induced streaks 7.4 Artifacts Related to X-ray Tubes 7.4.1 Off-focal radiation 7.4.2 Tube arcing 7.4.3 Tube rotor wobble 7.5 Detector-Induced Artifacts 7.5.1 Offset, gain, nonlinearity, and radiation damage 7.5.2 Primary speed and afterglow 7.5.3 Detector response uniformity 7.6 Patient-Induced Artifacts 7.6.1 Patient motion 7.6.2 Beam hardening 7.6.3 Metal and high-density object artifacts 7.6.4 Incomplete projections 7.7 Operator-Induced Artifacts 7.8 Problems References 8 Computer Simulation and Analysis 8.1 What Is Computer Simulation? 8.2 Simulation Overview 8.3 Simulation of Optics 8.4 Simulation of Physics-Related Performance 8.5 Simulation of a Clinical Study 8.6 Problems References 9 Helical or Spiral CT 9.1 Introduction 9.1.1 Clinical needs 9.1.2 Enabling technologies 9.2 Terminology and Reconstruction 9.2.1 Helical pitch 9.2.2 Basic reconstruction approaches 9.3 Slice Sensitivity Profile and Noise 9.4 Helically Related Image Artifacts 9.4.1 High-pitch helical artifacts 9.4.2 Noise-induced artifacts 9.4.3 System-misalignment-induced artifacts 9.4.4 Helical artifacts caused by object slope 9.5 Problems References 10 Multislice CT 10.1 The Need for Multislice CT 10.2 Detector Configurations of Multislice CT 10.3 Nonhelical Mode of Reconstruction 10.4 Multislice Helical Reconstruction 10.4.1 2D backprojection algorithm 10.4.2 Reconstruction algorithms with 3D backprojection 10.4.3 Over-beaming (or over-scanning) compensation 10.5 Multislice Artifacts 10.5.1 General description 10.5.2 Multislice CT cone-beam effects 10.5.3 Interpolation-related image artifacts 10.5.4 Noise-induced multislice artifacts 10.5.5 Tilt artifacts in multislice helical CT 10.5.6 Distortion in step-and-shoot mode SSP 10.5.7 Artifacts due to geometric inaccuracy 10.5.8 Comparison of multislice and single-slice helical CT 10.6 Problems References 11 X-ray Radiation and Dose-Reduction Techniques 11.1 Biological Effects of X-ray Radiation 11.2 Measurement of X-ray Dose 11.2.1 Terminology and the measurement standard 11.2.2 Other measurement units and methods 11.2.3 Issues with the current CTDI 11.3 Methodologies for Dose Reduction 11.3.1 Tube-current modulation 11.3.2 Umbra-penumbra and overbeam issues 11.3.3 Physiological gating 11.3.4 Organ-specific dose reduction 11.3.5 Protocol optimization and impact of the operator 11.3.6 Postprocessing techniques 11.3.7 Advanced reconstruction 11.4 Problems References 12 Dual-Energy and Spectral CT 12.1 Intuitive Explanation 12.1.1 Material differentiation 12.1.2 Material representation 12.2 Theory of Basis Material Decomposition 12.2.1 Basis material 12.2.2 Projection-space material decomposition (MD) 12.2.3 Image-space material decomposition 12.2.4 Multimaterial identification and quantification 12.2.5 Noise 12.3 Generation of Derivative Images 12.3.1 Monochromatic image 12.3.2 Basis material transformation 12.3.3 Electron density image 12.3.4 Effective atomic number image 12.4 Data Acquisition 12.4.1 Energy-integrating systems 12.4.2 Photon-counting system 12.5 Clinical Applications 12.6 Problems References 13 Advanced CT Applications 13.1 Introduction 13.2 Cardiac Imaging 13.2.1 Coronary calcium scan 13.2.2 Coronary artery imaging 13.2.3 Cardiac function 13.3 Interventional Procedures 13.4 Stroke: CT Perfusion and Multiphase CTA 13.4.1 Perfusion 13.4.2 Multiphase CTA 13.5 Screening and Quantitative CT 13.5.1 Lung cancer screening 13.5.2 Quantitative CT 13.5.3 CT colonography 13.6 Impact of Artificial Intelligence 13.7 Problems References Glossary Index