Course Objectives:
This course will enable the students to –
1. To provide knowledge of the operation and principles used in the systems and procedures associated with the clinical track.
2. To acquaint the students with nuclear radiation and radioactivity, its properties, units of measure, dosimetry measurement concepts and methods .
3. To develop an understanding of the biological effects of radiation and its application for radiation safety and for radiation treatment.
4. To prepare students to take further studies in Bio-Physics or take up interdisciplinary research and make them suitable for handling various medical diagnostic instruments based on principles of Physics.
Course outcomes (COs):
Course |
Learning outcomes (at course level) |
Learning and teaching strategies |
Assessment Strategies |
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Course Code |
Course Title |
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PHY 227
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Medical Physics (Theory)
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The students will be able to: CO60: Gain a broad knowledge of therapeutic applications like the ultrasound, color Doppler, computed tomography, conventional radiography, digital radiography, mammography and magnetic resonance imaging.
CO61: Explain X-ray technology while developing particular expertise in medical applications.
CO62: Describe radiation dosimeter, regarding need for radiological protection and the sources of an approximate level of radiation exposure for treatment purposes.
CO63: Develop the ability to understand the concept of human body, its anatomy and biological effects of radiations on human body.
CO64: Describe radiation safety and how it is used as a therapeutic technique and radiation safety practices. |
Approach in teaching: Interactive Lectures, Discussion, Tutorials, , Demonstration, Problem Solvingin tutorials, Visit to a medical college/ university
Learning activities for the students: Self learning assignments, Effective questions, Seminar presentation, Solving numerical, Additional learning through online videos |
Class test, Semester end examinations, Quiz, Solving problems s, Assignments, Presentations |
Recent advances in imaging technology: Basic principle of Ultrasound, colour Doppler, Computed tomography, Magnetic Resonance Imaging (MRI)-: Principle, application, its advantage over computed tomography or ultra sonography, Conventional radiography, Digital Radiography, Mammography.
X-Rays : Production of X-rays: X-ray tube, anode, cathodeconstruction and working principles of transformersand autotransformers used in x-ray circuits, voltagerectification and measurements in x-ray circuits. Physics of x-ray production ( Bremsstrahlung and Characteristic x-rays).
Radiation Dosimetry: Characteristic curve of gasfilled detectors. Regions of the characteristic curve. Construction of gas filled detectors and their working. Scintillation counter, semiconductor detector, alpha particle monitoring, Gamma and x-ray monitoring, neutron monitoring devices.Measurement of absorbed dose using calorimetry, chemicaldosimetry solid state methods, TLD & film dosimetry.
Biological effects of radiation: Direct and indirect action ofradiation, cell cycle effect, somatic and genetic effects . Effects on tissues and organs: Stochastic and non-stochastic (deterministic) effects, acute effects, late effects, effects of radiation on Embryo & fetus: lethal effects, organ malformation, growth impairment, mentalretardation, cancer induction, genetic effects, Late (delayed) effects: cataract formation, organ function,cancer induction.
Radiation Safety: Radiation protection quantities and units: exposure, absorbed dose, KERMA, dose equivalent (H). Committeddose equivalent (HT), effective dose equivalent (HE), Equivalent dose ((HTR), effective dose (E).Sources of radiation exposure: Natural sources and human made sources. Standards and regulations, philosophies of exposure limit , occupational limits, non-occupational limits.Radiation protection procedures for patients and personnel. Advisory groups & regulatory agencies - ICRP, NCRP,UNSCEAR, AERB.
1. Essential Physics of Medical Imaging
2. Medical Physics – J. R. Cameron & J. G. Skofronick.
3. Basis Radiological Physics – Dr. K. Thayalam.
1. Physics of Human body – Irering P. Herman
2. Pysics of Radiation Therapy – F M Kahn.
3. Christenson’s Physics of Diagnostic Radiology : Curry, Dowday & Murry.
E-Content:
1. “Radiation Physics for Medical Physicists”, E.B.Podgorsak, Second Edition, Springer,2009.
2. “An Introduction to Medical Physics”, Muhammad Maqbool,Springer,2017