Radiology (Basics and Image Interpretations) Lecture Notes PDF

Summary

These lecture notes provide an introduction to radiology, covering various topics such as course objectives, sources of radiation, and different types of radiographic imaging. The document also explains the biological effects and safety precautions related to radiation. It is intended for an undergraduate or postgraduate level medical course.

Full Transcript

Course Instructor
Dr.Ali Hayder ALi
Topics:

 Course objectives.
 Course contents.
 Sources of Radiation.
 Radiation in medicine.
 Types of Radiographic Imaging.
 Bioliogical effects of radiation.
 Radiation protection and safety.
 By the end of the radiology courses, and for
the practice, you should be able to:
 Understand the concept of Radiology.
 Learn the terminology specific to Radiology and how to use it in verbal
and written communication with patients, family, staff and peers.
 Understand the relationship between the basic and clinical sciences as it
applies to Radiology.
 Apply their knowledge in the basic and clinical sciences to the
determination of which imaging studies are most appropriate to the care
of their patients.
 Understand which study would be most important and helpful versus
which studies are less useful or helpful for diagnoses of a wide spectrum
of specific diseases.
 Demonstrate and discuss radiation safety including radiation biology,
dosimetry, and exposure limits, radiation protection and waste disposal.
 Introduction to Radiology.
 Medical applications of radiology.
 Radiologic Imaging Modalities.
 Biological Effect of Radiation.
 Radiation Protection and Safety.
 Standards for the Reporting And
Interpretation of Imaging Investigations
 Image quality , artifacts , hanging
radiograph , projection terminology.
 Approach to the CXR, AXR, and skull x.ray
interpretations: Technical and clinical
Aspects.
 The basics of MRI and CT chest ,abdomen,
and skull.
 The different options for MRI and CT
imaging of the chest , abdomen , and skull..
 A few disease patterns that will help you
impress.
 Clinical scenarios and competitions.
 Definition:
 Radiology is the branch of medical science
dealing with medical imaging. It may use x-ray
machines or other such radiation devices.
 It also uses techniques that do not involve ionize
radiation, such as MRI and ultrasound.
 Radiology, as a field is still advancing, helping &
participating in the steady progress of modern
medicine.
 Today it is difficult to imagining clinical medicine
without the diagnostic support from radiology.
 “Radiation is an energy in the form of electro-
magnetic waves or particulate matter,
traveling in the air.”
 Sources of radiation can be divided into two
categories:

Natural
Man-Made
Backgroud
Radiation
Radiation
 Cosmic
Radiation

Terrestrial Internal
Radiation Radiation
 The earth, and all living
things on it are constantly
bombarded by radiation
from outer space in all
directions.
 Charged particles from the
sun and stars interact with
the earth’s atmosphere + + - + - +_ _
and magnetic field to __ ++__
produce a shower of
radiation typically beta
and gamma radiation. EARTH
Path of incoming solar radiation
Albedo: a measure of how well a surface
reflects insolation
 Radioactive material is also
found throughout nature in:
soil – water – vegetation

 Some of these materials are
ingested with food and water,
while others, such as radon,
are inhaled.

 The dose from natural
background varies in different
parts of the world.
 In addition to the cosmic and
terrestrial sources, all people
also have radioactive 40K, 14C,
210Pb, and other isotopes
inside their bodies from birth.
 People are exposed to
radiation from radioactive
material inside their bodies.
 Besides radon, the most
important internal radioactive
element is naturally occurring
40K but U and Th are also
present.
 Radionuclides Found in the Body
Total Mass of Total Activity of Daily
Nuclide* Nuclide Found Nuclide Found in Intake of
in the Body the Body Nuclides

Uranium 90 mg 0 1.1 Bq 1.9 mg

Thorium 30 mg 0.11 Bq 3 mg

40K 17 mg 4.4 kBq 0.39 mg

Radium 31 pg 1.1 Bq 2.3 pg

14C 95 mg 15 kBq 1.8 mg
*Uranium, Thorium and Radium are elements
 Radiation produced in devices, such as x-ray
machines,

 Produced radioisotopes made in a reactor or
accelerator.
 Medical Radiation
 Consumer Products
 Industrial Applications
 Nuclear power
 Radioactive Fall out
 Examples on Non-ionizing
Radiation Sources
GAMMA
Visible light
Microwaves ULTRA V

Radios VISIBLE
INFRARED
MICROWAVE
Video Display Terminals TV
AM
Power lines RF

Radiofrequency Diathermy (Physical
Therapy)
Lasers
 These two groups are:

2/Occupationally
1/ Members of
exposed
the public individuals
 Tobacco (polonium-210)
 Televisions
 Medical x-rays
 Smoke detectors (americium)
 Nuclear medicine
 Building materials
 Airport X-ray systems Of lesser
magnitude, to radiation from the
nuclear fuel cycle
 Shipment of radioactive materials
▪ Residual fallout from nuclear
weapons testing and accidents,
such as Chernobyl.
Radiography
Radiation oncology departments
Nuclear medicine departments
University research laboratories
Nuclear power plants
Fuel cycle
 are exposed according to their occupations
and to the sources with which they work.

 Some of the isotopes of concern would be
uranium and its daughter products, 60Co,
137Cs, 241Am, and others
 Fallout is a term used to
describe radioactive
material which has become
airborne as a result of
nuclear weapons testing in
the atmosphere or as a
result of large scale
accidents such as that
which occurred at the
Chernobyl nuclear reactor
 The airborne material is
carried into the
atmosphere and is
deposited (falls out of the
sky) on remote locations.
 0
10
20
30
40
50
60
70
Smoking

25
(perWeek)

Medical
60

Building

7
Material

Phosphate

4
Fertilizer

2

Natural Gas

Nuclear Plant
0.4

Lantern
0.2

Mantles

Coal Plant
0.15
 Treatment

 Diagnosis

 Sterilization
 2. Therapeutic
1.Diagnostic imaging
imaging. (Radiotherapy).
 Diagnostic Radiology is the branch of
medical science dealing with medical imaging
and diagnosing purposes.

 It may use x-ray machines or other such
radiation devices.
 It also uses techniques that do not involve
radiation, such as MRI and ultrasound
 Radiation therapy uses ionizing radiation to
treat cancer i.e. to destroy cancerous cells.

 There are two techniques in radiation therapy
that are used to treat cancer using ionizing
radiation:
 1/Teletherapy
 2/Brachytherapy
 Cancerous tumors can be treated using the
following main methods:

1/ Chemotherapy (drugs).

2/ Radiation therapy (radiotherapy and
brachytherapy).

3/ Surgery.
 The aim of radiation therapy is to cause
damage to the cancerous cells whilst
minimizing the risk to surrounding healthy
tissue.
 The damage inflicted by radiation therapy
causes the cancerous cells to stop reproducing
and thus the tumor shrinks.
 Unfortunately, healthy cells can also be
damaged by the radiation.
 Radiation is classified into:

 Ionizing radiation
 Non-ionizing radiation
Ionizing Radiation
– Higher energy electromagnetic waves (gamma) or
heavy particles (beta and alpha).
– High enough energy to pull electron from orbit.

Non-ionizing Radiation
– Lower energy electromagnetic waves.
– Not enough energy to pull electron from orbit, but
can excite the electron.
 NON-
IONIZING IONIZING
RADIATION RADITION
 Paper Plastic Lead Concrete

Alpha
Helium nucleus (2 protons, 2
neutrons): +2 charge

Beta
Electron: +1 or -1 charge

Gamma and X-rays
Photon: 0 charge

Neutron
Neutron: 0 charge
X-rays were discovered by Roentgen (1845–1923) in 1895
while studying cathode rays (stream of electrons) in a gas
discharge tube.
Roentgen received the first Nobel Prize in Physics in 1901.

This radiation could penetrate opaque substances, produce
fluorescence, blacken a photographic plate, and ionize a
gas.

He named the new radiation x-rays.
 Radiation in Medicine X-ray
Diagnostics

First X-ray photograph
made by Röntgen in 1895,
shows ring on his wife’s
hand (left)

Modern X-ray picture
obtained by means of
digitized data and
image processing
(right)

From: National Geographic 171/1(1987)2-41
48
 X-Rays

X-ray of Bertha Roentgen's Hand
Roentgen soon found that photographic
plates were sensitive to the newly
discovered rays.
 Roentgen placed his hand on a cassette
loaded with a photographic plate. He then
aimed the activated cathode ray tube at her
hand for fifteen minutes.

An x ray of the hand requires an exposure
of about 1/25 to 1/50 of a second today
Scientist filled the room at the University of Wurzburg, Germany,
in 1896, when Wilhelm Conrad Roentgen demonstrated his
newly discovered x-rays
 Characteristics of X rays
And all ionizing radiation
1. Electromagnetic spectrum

2. Penetration

3. Radiographic effect

4. Biological effect

5. Ionization

6. Fluorescence
7. Chemical effect
8. Thermal effect
 The production of X rays

X-ray production typically involves bombarding a metal
target in an x-ray tube with high speed electrons (kV).
The bombarding electrons can eject electrons from the
inner shells of the atoms of the metal target.
Those vacancies will be quickly filled by electrons
dropping down from higher levels, emitting x-rays with
sharply defined frequencies associated with the
difference between the atomic energy levels of the target
atoms.
Genetic
appears in latter generations
due to cell damage of the reproductive organs

Somatic
appears in the irradiated individual immediate
or delayed effects

54
Cells were most sensitive to radiation when they
are:

Rapidly dividing
Undifferentiated
Have a long mitotic future

The more often they divide, the more chances for
DNA damage to result in cell death.
56
No change
Mutation and repair
Permanent change with limited effect
Changes leading to cancer or other effects
Death of cell / organism (mins - years)

57
1/Direct 2/Indirect
Action Action
H 2O H 2O + + e -  Radiation ionizes a
water molecule
H2O+ H+ + OH  The positive ion
dissociates
 The electron attaches
H 2O + e- H2 O- to a neutral water
molecule
H2O- H + OH-  The negative ion then
dissociates
H + H H2  The H radicals combine to form
hydrogen gas
OH + OH H2O2  Hydrogen peroxide is produce
through two mechanisms
H + O2 HO2  *OH and peroxide are very
reactive
HO2 + H H2O2  Damage cell membranes,
proteins, and DNA
 Possibility of antioxidants as
treatment
1/Stochastic
2/Non-stochastic
(Random)
(Deterministic)
Effects.
Effects
Occur by chance
Occur in both exposed and unexposed
individuals
Are not unequivocally related to the radiation
exposure
Become more likely as dose increases
Severity is independent of the dose
 1 Assumes that any
Probability of

amount of radiation
has a detrimental
effect
0.5
Is not a predictive
model
Is used to establish
0 regulatory dose limits
Dose
Cancer
Mental Retardation
Genetic Effects
Radiation induced tumors most frequent in the
hemopoietic system, thyroid, and skin.
Cancer induction is well documented at doses of 100
rad or more
Induction at lower doses is inconclusive (possible
exceptions are leukemia and thyroid cancer)
Tumor induction has a latent time of 5-20 years
Radiation induced leukemia in Atomic bomb survivors
has been documented at doses above 40 rad
Bone Cancer induction has been documented in
laboratory animals for large injection of “bone
seeking” radionuclide
Radiation induced lung cancer is seen mainly in
underground miners exposed to high Radon
concentrations
Most pronounced in those exposed between
the 8th and 17th week of pregnancy
Brain cells divide rapidly during this period
Has been observed in children exposed in-utero
to radiation from the atomic bombs in Japan
No radiation induced genetic effects have been
observed in humans
Genetic effects have been observed in animal
studies
 A certain minimum dose must be exceeded
before the effect occurs
 The severity of the effect increases as dose
increase
 There is a clear causal relationship between
exposure and occurrence
 100  No response is seen
until the threshold
Present Response

dose is exceeded
 At some dose all
50
individual experience
the effect
 Applies to non-
0 stochastic effects
Dose
 Sterlity
 Cataracts
 Skin Erythema
 Hemopoietic Syndrome
 Gastrointestinal (GI) Syndrome
 Central Nervous System Syndrome
 Temporary sterility had been observed
 In men at dose as low as 30 rads in women at
does as low as 300 rads
 In women at doses as low as 300 rads
 The higher the dose the longer the period of
sterility.
 Cataracts
 Threshold eye dose of about 200 rads of beta or
gamma radiation.
 Threshold may be as low as 60 rads for neutron
radiation.
 Long latent period.
 Reddening of the skin (erythema) occurs at
photon or beta doses of about 300 rads
 Higher doses may cause epilation, blistering,
necrosis, and ulceration
 Blood changes may
be seen at doses as
low as 14 rads
 Blood changes
almost certain at
doses above 50 rads
 Hemopoietic Syndrome appears at about 200
rads
 Characterized by depression or ablation of the
bone marrow
 May be accompanied by nausea, vomiting,
fatigue, and increased temperature
 Death occurs within 1-2 months unless medical
treatment is successful
 Occurs at a whole body dose of 1000 rads or
greater
 Characterized by the destruction of the
intestinal epithelium and complete
destruction of the bone marrow
 Accompanies by severe nausea, vomiting,
and diarrhea soon after exposure
 Death occurs within a few weeks
 Occurs at whole body doses of 2000 rads or
more
 Damages the central nervous system as well
as all other organs and systems
 Unconsciousness occurs within minutes
 Death follows in a matter of a few hours to a
few days
 Biological effects of concern in the occupational
setting do not appear until several years after
radiation exposure if they appear at all
 The probability of these effects increases with dose
 In any individual case it can never be determined
with 100% confidence that radiation was the cause
 Radiation protection and radiation safety:

Protection is “reactive” while “safety” is
proactive and indicating positive gain.

 Radiation cannot merely be controlled but preferably
managed.
 RSMS is a system approach to managing
radiation hazards and risks.
 RSMS involves the interaction of five major
elements to achieve set goals.
 The five major elements are:
a. policy;
b. organizing;
c. planning and implementation;
d. evaluation; and
e. action for improvement
 Justification of practice

 Optimization of protection

 Individual dose limits
As Low As
Reasonably
Achievable
 Primary Methods
of
Radiation Protection
Three basic
factors
Time
Distance
Shielding
1. To protect the patient from deterministic
effects, e.g., skin burns

2. To optimize X ray exposure to minimize risk
of stochastic effects,
e.g., development of cancer

88
 ICRP Publication 85. Avoidance of radiation injuries
from medical interventional procedures
 LK Wagner. Radiation injury is a potentially serious
complication to fluoroscopically-guided complex
interventions. Biomed Imaging Interv J 2007; 3(2):
http://www.biij.org/2007/2/e22/

 IAEA http://www.rpop.org
Radiation protection of patients

89
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