SD0306 Medical Imaging Systems

3 ECTS - 2-0 Duration (T+A)- 0. Semester- 2 National Credit

Information

Code SD0306
Name Medical Imaging Systems
Term 2024-2025 Academic Year
Duration (T+A) 2-0 (T-A) (17 Week)
ECTS 3 ECTS
National Credit 2 National Credit
Teaching Language Türkçe
Level Lisans Dersi
Mode of study Yüz Yüze Öğretim
Catalog Information Coordinator Doç. Dr. ZİYAFER GİZEM PORTAKAL


Course Goal / Objective

To teach and compare the information about the physical principles of medical imaging systems.

Course Content

Introduction to Medical Imaging. Basic Concepts in Medical Imaging. Physical Principles in Magnetic Resonance Imaging (MRI). Imaging Applications on MRI. Physical Principles in Computed Tomography (CT). Imaging Applications on CT. Physical principles in conventional and digital X-ray. Imaging Applications in X-Ray Devices. Physical principles in ultrasonography (US, color Doppler US, Elastography). Imaging Applications in Ultrasonography Devices. Physical Principles in PET (Positron Emission Tomography) and SPECT (Single Photon Emission Computed Tomography). Imaging Applications on PET and SPECT Devices. Device Quality Control Methods in Medical Imaging. Patient Quality Control Methods in Medical Imaging.

Course Precondition

Resources

Lecture notes and related articles.

Notes

1. How Does MRI work? An Introduction to the Physics and Function of Magnetic Resonance Imaging. Second Edition, Springer, 2008. Dominik Weishaupt, Victor D. Köchli, Borut Marincek. 2. An Introduction to The Principles of Medical Imaging. Revised Edition, Imperial College Press, 2005. Chris Guy, Dominic ffytche. 3. The Physics of Medical Imaging. Taylor&Francis Group, 1988. Steve Webb. 4. X-Ray Computed Tomography in Biomedical Engineering. Springer Verlag London Limited, 2011. Robert Cierniak. 5. Medical Imaging Physics. Fourth Edition, Wiley-Liss, 2002. William R. Hendee, E. Russell Ritenour. Prof. Dr. Doğan Bor, Radyasyon, Sağlık Riskleri ve Tanısal İncelemelerde Korunma. Dünya Tıp Kitabevi, 2016. Ahmet Kumaş, Radyasyon Fiziği ve Tıbbi Uygulamaları. Palme Yayıncılık, 2009. IAEA, Training Course Series No. 42. Radiation Biology: A Handbook for Teachers and Students. Vienna, 2010. Yves Lemoigne, Alessandra Caner, Radiation Protection in Medical Physics. NATO Science for Peace and Security Series B: Physics and Biophysics. Springer Science, 2011.


Course Learning Outcomes

Order Course Learning Outcomes
LO01 Defines the concepts of basic medical imaging.
LO02 List the historical development of medical imaging.
LO03 Explains the physical principles of magnetic resonance imaging.
LO04 Presents examples of the MRI usage.
LO05 Explains the physical principles of computed tomography.
LO06 Presents examples of the CT usage.
LO07 Explains the physical principles of conventional and digital X-ray.
LO08 Presents examples of the X-ray usage.
LO09 Explains the physical principles of Ultrasonography.
LO10 Presents examples of the ultrasonography usage.
LO11 Explains the physical principles of PET (Positron Emission Tomography) and SPECT (Single Photon Emission Computed Tomography).
LO12 Presents examples of the PET ve SPECT usage.
LO13 Defines the device quality control methods in medical imaging.
LO14 Defines the patient quality control methods in medical imaging.
LO15 Learns which method is used in medical imaging related to the purpose.


Week Plan

Week Topic Preparation Methods
1 Introduction to Medical Imaging. Prepared for the topics by searching the literature. Öğretim Yöntemleri:
Anlatım, Soru-Cevap, Tartışma, Gösteri, Örnek Olay
2 Basic Concepts in Medical Imaging. Prepared for the topics by searching the literature. Öğretim Yöntemleri:
Anlatım, Soru-Cevap, Tartışma, Gösteri, Örnek Olay
3 Physical Principles in Magnetic Resonance Imaging (MRI). Prepared for the topics by searching the literature. Öğretim Yöntemleri:
Soru-Cevap, Tartışma, Gösteri, Örnek Olay, Anlatım
4 Imaging Applications on MRI. Prepared for the topics by searching the literature. Öğretim Yöntemleri:
Soru-Cevap, Tartışma, Gösteri, Örnek Olay, Anlatım
5 Physical Principles in Computed Tomography (CT). Prepared for the topics by searching the literature. Öğretim Yöntemleri:
Soru-Cevap, Tartışma, Gösteri, Örnek Olay, Anlatım
6 Imaging Applications on CT. Prepared for the topics by searching the literature. Öğretim Yöntemleri:
Soru-Cevap, Anlatım, Tartışma, Gösteri, Örnek Olay
7 Physical principles in conventional and digital X-ray. Prepared for the topics by searching the literature. Öğretim Yöntemleri:
Anlatım, Soru-Cevap, Tartışma, Gösteri, Örnek Olay
8 Mid-Term Exam Prepared for the exam. Ölçme Yöntemleri:
Yazılı Sınav
9 Imaging Applications in X-Ray Devices. Prepared for the topics by searching the literature. Öğretim Yöntemleri:
Anlatım, Soru-Cevap, Tartışma, Gösteri, Örnek Olay
10 Physical principles in ultrasonography (US, color Doppler US, Elastography). Prepared for the topics by searching the literature. Öğretim Yöntemleri:
Anlatım, Soru-Cevap, Tartışma, Gösteri, Örnek Olay
11 Imaging Applications in Ultrasonography Devices. Prepared for the topics by searching the literature. Öğretim Yöntemleri:
Anlatım, Soru-Cevap, Tartışma, Gösteri, Örnek Olay
12 Physical Principles in PET (Positron Emission Tomography) and SPECT (Single Photon Emission Computed Tomography). Prepared for the topics by searching the literature. Öğretim Yöntemleri:
Anlatım, Soru-Cevap, Tartışma, Gösteri, Örnek Olay
13 Imaging Applications on PET and SPECT Devices. Prepared for the topics by searching the literature. Öğretim Yöntemleri:
Anlatım, Soru-Cevap, Tartışma, Gösteri, Örnek Olay
14 Device Quality Control Methods in Medical Imaging. Prepared for the topics by searching the literature. Öğretim Yöntemleri:
Anlatım, Soru-Cevap, Tartışma, Gösteri, Örnek Olay
15 Patient Quality Control Methods in Medical Imaging. Prepared for the topics by searching the literature. Öğretim Yöntemleri:
Anlatım, Soru-Cevap, Tartışma, Gösteri, Örnek Olay
16 Term Exams Prepared for the exam. Ölçme Yöntemleri:
Yazılı Sınav
17 Term Exams Prepared for the exam. Ölçme Yöntemleri:
Yazılı Sınav


Student Workload - ECTS

Works Number Time (Hour) Workload (Hour)
Course Related Works
Class Time (Exam weeks are excluded) 14 2 28
Out of Class Study (Preliminary Work, Practice) 14 2 28
Assesment Related Works
Homeworks, Projects, Others 0 0 0
Mid-term Exams (Written, Oral, etc.) 1 8 8
Final Exam 1 16 16
Total Workload (Hour) 80
Total Workload / 25 (h) 3,20
ECTS 3 ECTS

Update Time: 23.08.2024 02:27