DIAGNOSTIC APPLICATIONS OF IONISING RADIATION PHYSICS - 2017/8

Module code: PHYM043

Module provider

Physics

Module Leader

PANI S Dr (Physics)

Number of Credits

15

ECT Credits

7.5

Framework

FHEQ Level 7

JACs code

F350

Module cap (Maximum number of students)

N/A

Module Availability

Semester 2

Overall student workload

Independent Study Hours: 140

Lecture Hours: 28

Tutorial Hours: 7

Assessment pattern

Assessment type Unit of assessment Weighting
Coursework REPORT ON HOSPITAL PRACTICAL (APPROXIMATELY 2000 WORDS) 30%
Examination END OF SEMESTER EXAMINATION - 1.5 HOURS 70%

Alternative Assessment

An essay on a topic relevant to nuclear medicine will be assigned to students unable to attend the hospital practical. 30%

Prerequisites / Co-requisites

None

Module overview

Ionising radiation is widely used for diagnostic purposes, and multi-modality imaging is now becoming ubiquitous. The majority of hospital physicists work with ionising radiation and hence the topic is fundamental for anyone entering the profession.

In this module, an introduction is given to imaging systems and image perception. Detailed lectures then cover X-radiography, X-ray computed tomography, radiopharmaceuticals, nuclear medicine. The lectures will be supported by an assessed nuclear medicine practical and by tutorials in image processing and image registration.

Module aims

 Give students both theoretical foundations and practical experience on the main imaging modalities based on ionising radiation.

Provide students with an awareness of the issues in image processing and registration.

Learning outcomes

Attributes Developed
Describe the general principles of imaging systems and image perception
Describe and compare the physical principles and key technologies which determine the performance of medical X-ray and gamma ray imaging systems KC
Describe and compare the physical principles and key technologies of transmission and emission tomography KC
Appraise the quality assurance cycle required for diagnostic X-ray and nuclear medicine equipment and to be familiar with test equipment commonly used for the most important measurements undertaken by physicists in an imaging department KPT
Describe the properties, production processes and uptake mechanisms of radiopharmaceuticals for diagnostic applications KC
Appraise the suitability of filters for specific applications and apply them to different imaging problems KC
Independently apply their knowledge when taking up posts within the Health Service and other related fields (K,T,P)
Apply physics techniques to a multidisciplinary context PT
Assess the risks involved in a particular application KPT

Attributes Developed

C - Cognitive/analytical

K - Subject knowledge

T - Transferable skills

P - Professional/Practical skills

Module content

Indicative content includes:

Dr LM Warren (5 hours)

X-rays, γ-rays, MTF and ROC analysis

Mathematical formulation of the imaging system; impulse response function, stationarity, line spread function, edge spread function, MTF. Usefulness of MTF, modulation input and output, test objects, measure of performance, cascade of MTFs. Perception of detail, visual acuity, resolution criteria. Existence of observer, decision criteria. Construction of the ROC curve and principle of ROC analysis.

3 hours

X-ray Mammography

Attenuation and scattering of x-ray photons by breast tissues. Contrast, resolution, dose, noise and dynamic range in mammography. The design and performance of the components of the mammographic imaging system: X-ray tube (focal spot size, choice of X-ray spectrum), anti-scatter grid, compression paddle, automatic exposure control and image receptor (screen film, DR and CR systems). Comparison of digital and analog systems for mammography. New developments in mammography: digital breast tomosynthesis and spectral imaging. The NHS Breast Screening Programme - organisation, facts and figures. Quality assurance. Risk/benefit analysis in mammography.

2 hours

Mr J Price

X-ray imaging and analysis

The X-ray tube construction and operational needs.

X-ray scatter in diagnostic imaging and scatter reduction methods.

Applications of medical X-ray imaging.

2 hours

 

Mr M. Pryor

X-ray Computed Tomography

Fundamental principles of x-ray computed tomography.  Reconstruction algorithms.  CT equipment and instrumentation: x-ray tube design, filtration, collimation, x-ray detectors.  Axial and spiral CT, multi-slice CT.  Quality control and performance tests for diagnostic CT.  Radiation safety, room design and optimisation of exposure.  CT artefacts.  Clinical applications of x-ray CT.

6 hours

 

 

Dr E Lewis, Dr P Elangovan

Image processing and image registration

Images in the Fourier domain. Object segmentation – thresholding, k-means and region growing, Filtering: Edge enhancement and smoothing filters. Edge detection, 2D morphological operators.

Image registration: rigid and non-rigid techniques; affine and non-affine methods. Application examples in Multi-modality imaging.

7 hours lectures/computing tutorials

 

Dr J Scuffham

Nuclear Medicine

Radionuclide calibrators, sample counters, in-vitro nuclear medicine tests.  Gamma camera components, signal processing and corrections. SPECT imaging, reconstruction and corrections. Clinical applications of single photon scintigraphy. Quality assurance in nuclear medicine. Positron Emission Tomography: principles and equipment. Clinical applications of PET.

8 hours

 

Hospital visit in which students will tour a nuclear medicine department and participate in experiments using gamma cameras and non-imaging equipment.

3 hours

 

Mr Paul Hinton

Radiopharmaceuticals and Molecular Imaging

Radionuclides - review of decay modes and production methods.  Preparation of radiopharmaceuticals - Pharmacopoeial requirements.  Overview of radiopharmaceuticals - labelling methodologies.  Diagnostic radiopharmaceuticals - selection of radionuclide, localisation mechanisms, clinical applications, protein and peptide based radiopharmaceuticals.

2 hours

 

Methods of Teaching / Learning

The learning and teaching strategy is designed to:

provide students with the theoretical foundations of the current imaging modalities as well as knowledge about instrumentations, procedures and regulations.

give students practical experience in calibration and quality assurance in nuclear medicine give students direct experience of typical filters used in image processing and their effects.

 

The learning and teaching methods include:

• Formal lectures and occasional large group tutorial/question sessions (28 hours, 2- or 3-hours lectures). Teaching given by handouts and white board presentations and notes.

• Image processing lab sessions (4 hours)

• Hospital visit (3 hours)

 

Assessment Strategy

The assessment strategy is designed to provide students with the opportunity to demonstrate their understanding of both the theory and the practice of the use of ionising radiation for clinical imaging and the implications of different image processing modalities.

 

Thus, the summative assessment for this module consists of:



1.5 hour examination, with three questions to be answered out of five.


Report on hospital practical, to be submitted typically in Week 9 or 10 (max 2000 words)



 

Formative assessment

Non-marked optional quiz.

 

Feedback

Feedback will be given verbally during classes and the hospital practical. Written feedback on the hospital visit practical will be given

 

Reading list

Reading list for DIAGNOSTIC APPLICATIONS OF IONISING RADIATION PHYSICS : http://aspire.surrey.ac.uk/modules/phym043

Please note that the information detailed within this record is accurate at the time of publishing and may be subject to change. This record contains information for the most up to date version of the programme / module for the 2017/8 academic year.