General Radiation Safety

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General Radiation Safety

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Ionising radiation can cause chemical reactions in the body's ... Barium enema = 7 mSv. CT abdomen = 10 mSv. Conventional abdomen = 1 mSv. Chest PA = 20 uSv ... – PowerPoint PPT presentation

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Title: General Radiation Safety

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Radiation Safety in Medical Practice

John Saunderson
Radiation Protection Adviser
(TPRH ext. 6690, john.saunderson_at_hey.nhs.uk)

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Programme

Introduction
Radiation basics and hazards
Organising radiation safety
Any questions?

Ionising radiations
x-rays
gamma rays (?-rays)
beta particles (?)
electron beams

Not ionising radiations
lasers
ultraviolet (UV)
infrared (IR)
ultrasound
MRI

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Radiation basics and hazards

Why is it dangerous?
Radiation in hospitals

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Ionising radiation can cause chemical reactions
in the bodys cells which may

do no harm
kill the cell
cause the cell to multiply out of control
(cancer)
cause the cell to misfunction in some other way.

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Where very large doses kill many cells

radiation burns
cateract
radiation sickness.

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Threshold risksVery large doses onlyThe bigger
the dose, the more severe the effect
Staff doses never this big
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Cancer risksIt is assummed that any dose of
radiation could potentially cause cancer.The
bigger the dose, the more likely the effect will
occur, (but it will probably never occur).
i.e. a bit like crossing the road - the more
times you cross the more likely you are to be run
over, but probably never will.
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Radiation in hospitals

Radioactive substances
nuclear medicine
pathology
radiotherapy
X-ray sources
Radiology
Radiotherapy
Pathology .

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Scatter Dosee.g. Lat. Lumbar spine

No lead apron 0.6 mGy _at_ 30 cm
With 0.35 mm apron 0.06 mGy _at_ 30 cm
Public dose limit 1 mSv ? 17 patients
CC constraint 5 mSv ? 83 patients
Staff limit 6 mSv ? 100 patients.

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Doses Relative to Lum. Sp.

Chest x 0.02
Skull x 0.04
Thoracic spine, pelvis x 0.5
Abdomen x 0.8
IVU x 1.5
Ba. Enema x 4.1
CT abdomen x 5.9.

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All doses should be kept

As
Low
As
Reasonably
Achievable
The ALARA Principle .

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Basic Principles

Time
Distance
Shielding

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Distance

Double distance 1/4 dose
Triple distance 1/9th dose.

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Shielding
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Shielding
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Organising radiation safety

Controlled Areas
Local Rules
Radiation Protection Supervisor
Radiation Protection Adviser
Radiographer .

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IRMER

Operators
Training

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f i n
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Radiation Quantities and Units

Dose
e.g. skin dose
Dose equivalent
Effective dose

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Absorbed Dose (D)

Amount of energy absorbed per kg
Measured in Grays (Gy)
1 Gy 1000 mGy (milligray)
1 mGy 1000 ?Gy (microgray)
gt 2 Gy to skin causes erythema (sun burn)

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Typical Values of D

Radiotherapy dose 40 Gy to tumour (over several
weeks)
LD(50/30) 4 Gy to whole body (single dose)
Annual background dose 2.5 mGy whole body
Chest PA skin dose 160 uGy
Mammo skin dose 9 mGy .

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Dose Equivalent (H)

Measured in Sieverts (Sv)
1 Sv 1000 mSv (millisievert)
1 mSv 1000 ?Sv (microsievert)
Dose equivalent absorbed dose x Q
Q depends on type of radiation
For X-rays, Q 1, so 1 Sv 1 Gy
Alpha rays are ten times as dangerous as X-rays,
so Q 10, so 10 Sv 1 Gy

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Effective Dose (E)
Tissue or organ wT Gonads 0.20 Red bone
marrow 0.12 Colon 0.12 Lung 0.12 Stomach 0
.12 Bladder 0.05 Breast 0.05 Liver 0.05 Oe
sphagus 0.05 Thyroid 0.05 Skin 0.01 Bone
surfaces 0.01 Remainder 0.05

Sum of equivalent doses to each tissue/organ x
organ weighting factors E ?T wT.HT
Units are Sieverts (Sv)
Risk of cancer is proportional to effective dose

e.g. if breast alone received 2 mGy to tissue, E
0.05 x 2 0.1 mSv.
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Typical Values of E