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Introduction to Nuclear Medicine Technology 231 NMT

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Abdullah A. Alshreef MSC Biomedical Imaging. PgDip Medical Physics. BSC Biomedical Engineering. E-mail : engalshreef_at_gmail.com Course Credits: 3 hours; 3 ... – PowerPoint PPT presentation

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Title: Introduction to Nuclear Medicine Technology 231 NMT


1
Introduction to Nuclear Medicine Technology231
NMT
  • Abdullah A. Alshreef
  • MSC Biomedical Imaging.
  • PgDip Medical Physics.
  • BSC Biomedical Engineering.
  • E-mail engalshreef_at_gmail.com

2
Introduction to Nuclear Medicine Technology231
NMT
  • Course Credits 3 hours 3 hr Lecture per week.
  • Prerequisite for None

3
  • This course is primarily concerned with
  • - introduction to the field of nuclear medicine.
  • - overview on radiation safety.
  • - procedures performed in nuclear medicine.

4
Course Objectives
  • 1- introduction to the field of nuclear medicine
  • 2- knowledge upon vital signs, patient care,
    universal precautions, and phlebotomy.
  • 3- overview on radiation safety and the most
    common procedures performed in nuclear medicine.

5
Course Contents
  • 1- Overview of Nuclear Medicine
  • 2- Interpersonal Communication
  • 3- Health Care Ethics
  • 5- Patient Care Body Mechanics
  • 6- Universal Precaution
  • 7- Administration of Pharmaceuticals
    Radiopharmaceuticals
  • 8- Venipuncture

6
Course Contents
  • 9- Radiation Protection and Safety
  • 10- Medical Terminology in NMT
  • 11- Instrumentation and Quality Control in NMT
  • 12- Common Nuclear Medicine Procedures

7
Evaluation
  •  
  • First Assessment Exam 20
    marks
  • Participation and Attendance 10 marks
  • Second Assessment Exam 20 marks
  • Final Exam
    50 marks

  • 100

8
References
  • 1- Nuclear Medicine and Pet Bernier, Langan,
    Christian
  • 2- Nuclear Medicine Procedure Manual,
    Klingersmith, Ed. Wick, 2006-2008
  • 3- Nuclear Medicine and PET/CT Technology and
    Techniques, Christian, Waterstram-Rich, Mosby,
    2007

9
Principles of Imaging
  • 1- Diagnostic Radiology
  • Transmission of radiation from an external source
  • 2- Nuclear Medicine
  • Emission of radiation from an internal source
  • 3- Ultrasound
  • Reflection of sound waves

10
Principles of Imaging
  • 4- Magnetic Resonance Imaging
  • Nuclear Magnetic Resonance
  • 5- Computed Tomography
  • 3D Transmission
  • 6- Positron Emission Tomography (PET)
  • 3D Emission
  • 7- Single Photon Emission Computed Tomography
    (SPECT)
  • 3D Emission

11
Principles of Imaging
  • Need to understand underlying the physics to
    design improved systems.
  • Need to understand underlying physics to process
    data from imaging systems

12
Clinical Aspects of Radionuclide Imaging
  • Oncology
  • Cardiology
  • Renal Medicine
  • Respiratory Medicine
  • Gastroenterology
  • Geriatrics
  • Paediatrics
  • Orthopaedics
  • Endocrinology
  • Haematology
  • Psychiatry
  • Obstetrics
  • Breast Unit
  • General Surgery
  • Vascular Surgery

13
Radiation Emission from Nucleus
  • Alpha
  • Alpha particle 2 protons 2 neutrons
  • Energies of 4 to 6 MeV
  • Range of few cm in air, lt 0.01 mm in tissue
  • Beta-
  • n ? p e- ? Energy shared between
    electron and anti-neutrino
  • Beta
  • p ? n e ? Energy shared between
    positron and neutrino
  • Beta particles energies 10 keV to 4 MeV
  • Range of particles in tissue 20 keV ? 0.01 mm
  • 400keV ?1.3 mm

14
Annihilation Radiation
Two 511 keV photons produced
15
Radiation Emission from Nucleus
  • Gamma Emission
  • Photon originating from nucleus
  • Often carries away excess energy from other types
    of decay
  • Nuclear Isomers
  • Same number of protons and neutrons. Different
    Nuclear Energy levels
  • For example 99mTc decays to 99Tc ?

16
Radioactive Decay
Becquerel is one disintegration per second.
17
Production of Unstable Nuclei.
  • Decay from naturally occurring isotopes
  • Reactor
  • Bombard target material with neutrons
  • Accelerator (Linac or Cyclotron)
  • Bombard target material with charged particles
  • Generator
  • Separate daughter product from longer lived
    parent isotope

18
Technetium Generators
19
Gamma Camera
20
Radiation Quantities
  • Production
  • Activity of radionuclide.
  • mAs gt Flux of photons
  • Exposure
  • Charge produced per kilo of interacting matter
  • Kerma (Kenetic Energy Released per Unit Mass)
  • Absorbed Dose (Gray Joule kg-1)
  • Equivalent Dose (Sievert Joule kg-1)
  • Effective Dose (Sievert Joule kg-1)

Biologically relevant
Easy to measure
21
(No Transcript)
22
  • Thank You for your kind attention
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