NPRE 435: Radiological Imaging
In this course, we will discuss the basic principles for generating tomographic images of volumetric objects through the detection of ionizing radiation signals. These include the sources of ionizing radiation, interactions of ionizing radiation with matter, operating principles for state-of-art imaging detectors, mathematical and statistical principles for modeling the detected signal, basic techniques for reconstructing tomographic images from measured projections. Based on these discussions, we will introduce several critically important imaging modalities, such as planar X-ray radiography, X-ray computed tomography (CT), single photon emission computed tomography (SPECT), positron emission tomography (PET), and their application in diagnosis of diseases, monitoring therapeutic responses and as research tools for understanding the molecular pathways underlying various biological processes. We will also discuss several emerging radiological imaging techniques, such as X-ray fluorescence emission tomography (XFET), X-ray luminescence computed tomography (XLCT) and their applications in preclinical and clinical research.
This course will not only cover the basic principles of currently radiological imaging techniques, but also highlight the advantages and limitations of the existing imaging modalities, as well as identify potential directions for further advancing the field of radiological imaging.
Lab tour: We will have 2 lab tours during the semester to (1) the Molecular Imaging Center at the Biomedical Imaging Center (BIC) of the Beckman Institute, and (2) the Microscopic Suite at the Beckman Institute.
Term project: TBD.
Quizzes and Exams: Two major exams and 4-6 quizzes throughout the semester.
Teaching Staff and Office Hours
Instructor: Ling-Jian Meng, PhD. E-mail: email@example.com; Office: 111E Talbot Lab; Tel: 217-3337710.
Office hours: 3-5pm on Friday. Please feel free to come to my office during regular hours, or to send me email to make appointments.
Lecture Time and Place
MWF 2:00pm-2:50pm; 204 Transportation Building.
Unofficially: radiation interactions, basic principles of radiation detectors, probability and random variables complex numbers, linear algebra, Matlab.
Foundations of Medical Imaging, Z. H. Cho, John Wiley & Sons, 1993.
Radiation Detection and Measurements, Third Edition, G. F. Knoll, John Wiley & Sons, 1999.
Lecture Notes (will be posted after each lecture)
Chapter 1: A (Very) Brief Introduction to Radiation Sources and Radiation Interactions
§ A brief introduction to the radiation sources commonly used in radiological imaging: (09/06 – 09/11) Reading Material: Chapters 1 in Ref. book .
§ Radiation Interactions: Reading Material: Chapters 2 in Ref. book .
Chapter 2: Mathematical Preliminaries for Image Processing
§ Signals and systems: Reading Material: Chapters 2 in Ref. book .
§ Fourier transform basics, and sampling theory: Reading Material: Chapters 2 in Ref. book  and Chapters 2 in Ref. book .
§ Analytical Image Reconstruction Methods (1): Radon Transform & Central Slice Theorem: Reading: Chapter 3 in Ref. book . Chapter 6 (Page 192-207) in Ref. book 
§ Analytical Image Reconstruction Methods (2): Back-projection based reconstruction methods:
§ A brief introduction to Matlab.
§ Image Quality: Reading Material: Chapters 3 in Ref. book .
Chapter 3: X-ray Radiography and Computed Tomography
§ X-Ray Physics (1): X-ray generation. Reading Material: Chapters 4 & 5 in Ref. book 
§ X-Ray Physics (2): X-ray interactions, attenuation and practical considerations. Reading Material: Chapters 4 & 5 in Ref. book 
§ X-Ray Physics (3): X-ray detectors. Reading Material: Chapters 4 & 5 in Ref. book 
§ (Not covered in lecture) Planar X-Ray Image Formation: Reading Material: Chapters 5 in Ref. book . Note that the notations used in lecture notes may be different from those used in the text book.
§ (Not covered in lecture) SNR of X-Ray Images: Reading Material: Chapters 5 in Ref. book .
§ X-Ray CT: Image formation, image quality: Reading Material: Chapters 6 in Ref. book .
Chapter 4: Emission Tomography and Related Imaging Techniques
§ Single Photon Emission Computed Tomography (SPECT) (1): principle, radio-nuclides and Imaging systems: Reading Material: Chapters 7 & 8 in Ref. book .
§ Single Photon Emission Computed Tomography (2): SPECT systems, Image Formation, Design Considerations and Recent Advances: Reading Material: Chapters 7 & 8 in Ref. book .
§ Positron Emission Tomography (PET): Basic Principle, Instrumentations, Design Considerations and Clinical Uses: Additional Reading Material: Chapters 9 in Ref. book , and recent technological advances.
Chapter 5: Magnetic Resonance Imaging (MRI)
§ Basic Physics of NMR (1): Reading Material: Chapters 12 in Ref. book .
§ Basic Physics of NMR (2): Reading Material: Chapters 12 in Ref. book .
§ MRI Basic (1): Reading Material: Chapters 13 in Ref. book .
§ MRI Basic (2): Reading Material: Chapters 13 in Ref. book .
§ MRI Basic (3): Reading Material: Chapters 13 in Ref. book .
Homeworks (will be posted after each Monday’s lecture)
Mid-term Exam Information
The midterm exam is scheduled at 2-3pm on Nov. 9th. Please see below for further information:
1. This will be an open-book exam. You can bring your lecture notes, calculators and computers for accessing lecture note ONLY.
3. There will be four questions on the exam.
Final Exam Information
Time and Place: The final exam is scheduled at 7-10 pm on Friday, Dec. 14, 2018, in Room 204, Transportation Building.
Format: the exam will be open-book. You could take your lecture notes, textbooks, calculators, and computers. For accessing the textbook and lecture note online. The exam will be for 3 hours and contain 9 questions.
Contents covered: The final exam will only cover contents introduced after the mid-term exam, which include X-ray CT, and Emission Tomography (SPECT and PET) chapters. Please see the review slides attached above for a more precise coverage of the final exam.
Term project: 20%
Mid-term exam: 15%
Final exam: Exam 30%