Radiation Characteristics And Radiation Protection PDF

Summary

This document provides an overview of radiation characteristics, radiation protection, and related topics in dentistry. It covers various aspects including types of radiation, radiation effects, cumulative effects, genetic and somatic effects, radiation measurement, and maximum permissible dose.

Full Transcript

Unit 7

Radiation Characteristics and
Radiation Protection
 Review: Ionization
⬤
Electrons remain stable in their orbits around the
nucleus until x-ray photons collide with them
⮚ A photon is a minute bundle of pure energy that has no
weight or mass
⬤
Ions are atoms that gain or lose an electron and
become electrically unbalanced
⬤
X-rays have enough energy to push an electron
out of its orbit, producing an ion (an atom that
gains or loses an electron and becomes
electrically unbalanced) in a process called
ionization

2
 Review: Properties of X-Rays
⬤X-rays are a form of energy that can
penetrate matter
⮚ Like visible light, radar, radio, and television waves,
they belong to a group called electromagnetic
radiation
⬤Electromagnetic radiation is made up of
photons that travel through space at the
speed of light in a straight line with a wavelike
motion
⬤The shorter the wavelength of the x-ray, the
greater is its energy
3
 Types of Radiation
⬤Primary radiation is made up of x-rays that
come from the target of the x-ray tube
⮚ Useful beam or primary beam
⬤Secondary radiation is x-radiation that is
created when the primary beam interacts with
matter
⬤Scatter radiation is a form of secondary
radiation that occurs when an x-ray beam has
been deflected from its path by interaction with
matter

4
 Radiation Effects
⬤All ionizing radiation is harmful and produces
biologic changes in living tissues
⬤The amount of x-radiation used in dental
radiography is small, but biologic changes do
occur
⬤The dental assistant must understand how
the harmful effects of radiation occur and how
to discuss the risks of radiation with patients
⬤Entire x-ray area is considered a radiation
hazard area
 Biologic Effects of Radiation
⬤Exposure to radiation can bring about
changes in body chemicals, cells, tissues,
and organs
⬤The effects of the radiation may not become
evident for many years after the x-rays were
absorbed
⮚ This time lag is called the latent period
 Cumulative Effects
⬤Exposure to radiation has a cumulative effect
over a lifetime
⬤When tissues are exposed to x-rays, some
damage occurs
⬤Tissues have the capacity to repair some of
the damage; however, they do not return to
their original state
⬤The cumulative effect of radiation exposure
can be compared with the cumulative effect
from repeated exposure over the years to the
rays of the sun
Disorders of Critical Organs
 Genetic and Somatic Effects
⬤X-rays affect both genetic and somatic cells
⮚ Genetic cells are the reproductive cells (sperm and
ova)
Damage to genetic cells is passed on to succeeding
generations
⮚ All other cells in the body belong to the
classification of somatic tissue
X-rays can damage somatic tissue, but the damage is not
passed on to future generations

JUST REED THROUGH THIS ONE
 Radiation Measurement
⬤Radiation can be measured in a manner similar to
that used to measure time, distance, and weight
⬤Two sets of systems are used to define the way in
which radiation is measured
⮚ The older system is referred to as the traditional or standard
system
⮚ The newer system is the metric equivalent, known as the
Système Internationale (SI)
 Radiation Measurement (Cont.)
⬤Traditional units of radiation measurement
⮚ Roentgen (R)
⮚ Radiation absorbed dose (rad)
⮚ Roentgen equivalent [in] man (rem)
⬤SI units
⮚ Coulombs per kilogram (C/kg)
⮚ Gray (Gy)
⮚ Sievert (Sv)
 Maximum Permissible Dose
⬤Maximum permissible dose (MPD) of whole-
body radiation for those occupationally
exposed to radiation is 5000 mrem (5.0 rem)
per year, or 100 mrem per week
⬤This amount of radiation to the whole body
carries very little chance of injury
⬤For nonoccupationally exposed persons, the
current MPD is 500 mrem (5 mSv) per year
⬤Dental personnel should strive for an
occupational dose of 0 by adhering to strict
radiation-protection practices
 HARP -
https://www.ontario.ca/laws/statute/90h02

13
 Responsibilities of the Dentist
⬤ Prescribe only images that are required for diagnostic purposes
⬤ Ensure that all radiographic equipment is maintained in safe working
condition
⬤ Ensure that appropriate shielding protects the staff and patients from the
effects of radiation
⬤ Require that all personnel who obtain images be properly trained,
credentialed and appropriately supervised while exposing images
⬤ Use only techniques that will produce diagnostic-quality images with
minimal radiation exposure to the patient and operator
⬤ Follow the province or territory’s radiographic licensing requirements,
rules and regulations.
⬤ Participate in obtaining informed consent from patient and family
⬤ Review the patient’s record to determine when images were last taken

JUST READ THROUGH THI|S

14
 Protective Devices
⬤The dental tubehead must be equipped with
certain appropriate components:
⮚ Aluminum filters
⮚ Lead collimators
⮚ PIDs
⬤Equipment should be checked on a regular
basis by provincial or federal regulating
agencies
⬤Faulty or malfunctioning equipment should be
repaired immediately
15
 Patient Protection
⬤Lead apron and thyroid collar:
⮚ A lead apron and thyroid collar must be used on
all patients for all exposures
⮚ This rule applies to all patients, regardless of the
patient’s age or sex or the number of images being
exposed
⬤The lead apron should cover the patient from
the neck to the lap to protect the reproductive
and blood-forming tissues from scatter
radiation
⬤This is a mandated practice!

16
 Fast-Speed Film
⬤When using film-based exposures, the film
speed refers to the amount of radiation
required to obtain the image
⮚ The size of silver bromide crystals is the main
factor in determining the film speed; the larger the
crystals, the faster the film
⮚ A fast film requires less exposure to produce a
quality radiograph
⮚ Fast-speed film is the single most effective method
of reducing a patient’s exposure to x-radiation
⮚ Fast-speed film is available for both intraoral and
extraoral radiography
Image Receptor-Holding Devices
⬤The use of a film/receptor-holding instrument
keeps the patient’s hands and fingers from
being exposed to x-radiation
⬤These devices also keep the film or receptor
in a stable position and help the operator to
properly position the film or sensor and the
PID
 Proper Technique
⬤Proper technique is necessary to ensure
diagnostic quality images and to reduce the
amount of radiation to which the patient is
exposed
⬤Images that are nondiagnostic must be
retaken; this results in additional radiation
exposure to the patient
⬤Retakes are a major cause of unnecessary
radiation exposure in patients and must be
avoided
 X-Rays During Pregnancy

⬤The Guidelines for Prescribing Dental Radiographs,
issued by the American Dental Association in
conjunction with the Food and Drug Administration, state
that dental radiographic procedures “do not need to be
altered because of pregnancy”
⬤When a lead apron is used during radiographic
procedures, the amount of radiation received in the
pelvic region is nearly zero
⬤There is no detectable exposure to the embryo or fetus
with the use of a lead apron
 Radiation Monitoring
⬤Three types of monitoring devices are used to
determine the amount of radiation exposure to
personnel:
⮚ Film badge
⮚ Pocket dosimeter (pen style)
⮚ Thermoluminescent, or TLD

21
 Equipment Monitoring
⬤Dental x-ray machines must be monitored for
radiation leakage
⬤If a dental x-ray tubehead has a faulty tubehead seal,
leakage results
⬤Dental x-ray equipment can be monitored through the
use of a calibration device that can be obtained from
the manufacturer or from the state health department
 Patient Questions (Cont.)
⬤Here are some examples of comments you
can make to patients during informal
discussions:
⮚ “The doctor orders x-rays on the basis of your
individual needs”
⮚ “Our office takes every step possible to protect you
from unnecessary radiation”
⮚ “We use a lead apron and thyroid collar to protect
your body from stray radiation”
⮚ “We use a high-speed film or sensor that requires
only minimal amounts of radiation”
⮚ “Do you have any questions before we begin?”
 Patient Issues
⬤Informed Consent – ⬤Confidentiality –
before taking any images, images are part of the
the operator must obtain patient’s record
and document receipt of ⮚ Clinician is obligated to
“informed consent” ensure privacy under state
⮚ Patient must be provided and federal laws (HIPPA)
an explanation of the ⮚ Patient has the right to and
procedure, why it is must give permission to
necessary and associated have records forwarded to
risks other providers
⮚ Patient signed and dated ⮚ Transfer of records is a
consent form is the best common professional
documentation courtesy

Elsevier
24
 Unit 6: Exposure and
technique errors
Chapters 38, 39

Copyright © 2012, 2009, 2005, 2002, 1999, 1995, 1990, 1985, 1980, 1976 by Saunders, an imprint of Elsevier Inc. All rights reserved. 25
Unexposed Receptor
Receptor
May occur with digital
sensors or film
Appearance
The image appears clear
Cause
Failure to turn on the x-
ray machine
Electrical failure
Malfunction of the x-ray
machine
Correction
Make certain the x-ray
machine is turned on and
listen for the audible
exposure signal.
Film Exposed to Light
Receptor
Occurs only with film
Appearance
The image appears black.
Cause
The film was exposed to
white light.
Correction
Do not unwrap in a room
with white light.
Check the darkroom for
light leaks.
Turn off all lights in the
darkroom except the
safelight.
Overexposed Receptor
Receptor
May occur with digital
sensors or film
Appearance
Image appears dark or
high in density.
Cause
Excessive exposure
time, kilovoltage,
milliamperage
Correction
Check settings and
reduce as needed
before exposing
receptor.
Underexposed Receptor
Receptor
May occur with digital
sensors or film
Appearance
The image appears light
or low in density.
Cause
The receptor was
underexposed.
Correction
Check the exposure time,
kilovoltage, and
milliamperage settings
on the x-ray machine
before exposing the
receptor.
Absence of Apical Structures
Receptor
May occur with digital
sensors or film
Appearance
No apices appear on the
receptor.
Cause
The receptor was not
positioned in the patient’s
mouth to cover the apical
regions of the teeth.
Correction
Make certain no more than ⅛
inch of the receptor edge
extends beyond the incisal-
occlusal surfaces of the
teeth.
Dropped Receptor Corner
Receptor
May occur with digital
sensors or film
Appearance
The occlusal plane appears
tipped or tilted.
Cause
The edge of the receptor
was not placed parallel to
the incisal-occlusal
surfaces of the teeth.
Correction
Make certain the edge of
the receptor is placed
parallel to the incisal-
occlusal surfaces of the
teeth.
Overlapped Contacts: Incorrect
Horizontal Angulation

Receptor
May occur with digital
sensors or film
Technique
May occur with paralleling or
bisecting technique
Appearance
Overlapped contacts
Cause
The central ray was not
directed through
interproximal spaces.
Correction
Direct the x-ray beam
through interproximal
regions.
Foreshortened Images: Incorrect
Vertical Angulation
Receptor
May occur with digital
sensors or film
Technique
May occur with the bisecting
technique when beam
alignment is not used
Appearance
Short teeth with blunted
roots
Cause
Excessive vertical angulation
Correction
Do not use excessive vertical
angulation with the bisecting
technique.
Elongated Images: Incorrect
Vertical Angulation
Receptor
May occur with digital
sensors or film
Technique
May occur with the bisecting
technique when a beam
alignment device is not used
Appearance
Long, distorted teeth
Cause
The vertical angulation was
insufficient.
Correction
Use adequate vertical
angulation with the bisecting
technique.
Cone-Cut with Beam
Alignment Device
Receptor
May occur with digital sensors
or film
Technique
May occur with either
paralleling or bisecting
technique when a beam
alignment device is used
Appearance
A clear area appears on the
image.
Cause
The PID was not properly
aligned with the periapical
beam alignment device.
Correction
Make certain the x-ray beam is
centered over the receptor.
Cone-Cut Without Beam
Alignment Device
Receptor
May occur with digital
sensors or film
Technique
May occur with bisecting
technique when a beam
alignment device is not used
Appearance
A clear area appears on the
image.
Cause
The PID was not directed at
the center of the receptor.
Correction
Make certain the x-ray
beam is centered over the
receptor.
Incorrect Receptor Placement
of Premolar Bite-Wing
Receptor
May occur with digital sensors or film
Technique
May occur with bite-wing technique when
a beam alignment device or bite-tab is
used
Appearance
Distal surfaces of the canines are not
visible on the image.
Cause
The bite-wing receptor was positioned
too far posteriorly in the mouth.
Correction
Make certain the anterior edge of the
bite-wing receptor is positioned at the
midline of the mandibular canine.
Incorrect Placement
of Molar Bite-Wing
Receptor
May occur with digital sensors or film
Technique
May occur with the bite-wing technique
when a beam alignment device or bite-
tab is used
Appearance
Third molar regions are not visible on
image.
Cause
The bite-wing receptor was positioned
too far anteriorly in the mouth.
Correction
Make certain the anterior edge of the
bite-wing receptor is positioned at the
midline of the mandibular second
premolar.
Overlapped Contacts: Incorrect
Horizontal Angulation

Receptor
May occur with digital
sensors or film
Technique
May occur with the bite-wing
technique when a beam
alignment device or bite-tab
is used
Appearance
Overlapped contacts on the
image
Cause
The central ray was not
directed through the
interproximal spaces.
Correction
Direct the x-ray beam
through the interproximal
spaces.
Distorted Image: Incorrect
Vertical Angulation
Receptor
May occur with digital
sensors or film
Technique
May occur with the bite-wing
technique when a bite-tab is
used
Appearance
Image appears distorted
Cause
The vertical angulation was
incorrect.
Correction
Always use a +10-degree
vertical angulation with the
bite-wing technique.
Cone-Cut with Beam
Alignment Device
Receptor
May occur with digital sensors or
film
Technique
May occur with bite-wing
technique when a beam
alignment is used
Appearance
A clear area appears on the
image.
Cause
The PID was not properly aligned
with the beam alignment device.
Correction
Make certain the PID and the
aiming ring are aligned.
Cone-Cut Without Beam
Alignment Device
Receptor
May occur with digital
sensors or film
Technique
May occur with bite-wing
technique when a bite-tab is
used
Appearance
A clear area appears on the
image.
Cause
The PID was not directed at
the center of the receptor.
Correction
Make certain the x-ray beam
is centered over the
receptor.
Bending
Receptor
May occur with indirect
digital sensors or film
Technique
May occur with the
paralleling, bisection, or
bite-wing techniques
Appearance
Images appear
stretched (on a film)
and distorted (on PSP
receptors).
Cause
Improper handling;
receptor damaged
Correction
Check receptor
placement before
exposure.
Creasing
Receptor
May occur with indirect
digital sensors or film
Technique
May occur with
paralleling, bisecting, or
bite-wing technique
Appearance
A thin radiolucent line
appears on the image.
Cause
Improper handling;
receptor creased; film
emulsion cracked
Correction
Do not over-manipulate
the receptor.
Debris Accumulation
Receptor
May occur with digital
sensors
Technique
May occur with paralleling,
bisecting, or bite-wing
technique
Appearance
Debris on the surface of
sensor may cause
permanent radiopaque
artifacts or radiolucent
scratch marks on the
sensor.
Cause
Sensors not handled
carefully or wiped between
uses; debris/dirt
accumulates on the
surface of sensor
Correction
Extreme care must be used
when handling sensors.
Phalangioma
Receptor
May occur with digital
sensors or film
Technique
May occur with the
bisecting technique when
finger-holding method is
used
Appearance
The patient’s finger
appears on the image.
Cause
The patient’s finger was
positioned in front of the
receptor.
Correction
Make certain the
patient’s finger is placed
behind the receptor.
Movement/Motion Unsharpness

Receptor
May occur with digital
sensors or film
Technique
May occur with the
paralleling, bisecting, or
bite-wing techniques
Appearance
Blurred images appear on
the image.
Cause
The patient moved during
exposure of the receptor.
Correction
Instruct the patient to
remain still while the
receptor is being exposed.
Reversed/Backward Placement

Receptor
May occur with digital
sensors or film
Technique
May occur with paralleling,
bisecting, or bite-wing
techniques
Appearance
Light images with a
herringbone pattern
appear on the image.
Cause
The receptor was placed
backward in the mouth and
then exposed.
Correction
Always place the white
side of the receptor
adjacent to the teeth.
Double Image
Receptor
May occur with indirect
digital sensors or film
Technique
May occur with the
paralleling, bisecting, or
bite-wing techniques
Appearance
A double image appears
on the image.
Cause
The receptor was
exposed twice in the
patient’s mouth.
Correction
Always separate exposed
and unexposed
receptors.
 Unit 8: Quality
Assurance, Legal
considerations, Digital
Radiography

50
Digital Radiography
Has been used in The term digital image is
used instead of
dentistry since 1987 radiographs, x-rays, or
Today, in many films
Digital images are not
areas of the United radiographs, but
States and Canada, electronic signals that are
dentists and dental captured by sensors and
displayed on a computer
schools are monitor almost
changing from instantaneously
These images can be e-
conventional film- mailed to insurance
based radiography companies and other
to digital dentists
Hard copies can be
radiography printed on image quality
paper

51
Digital Radiography (Cont.)
A conventional x-ray machine is still
needed to expose the image
The positioning of the image receptor (sensor
or phosphor storage plate) in the mouth is
identical to positioning with film
Strict infection control measures must be
used because the sensors and PSPs are
reused time and again
FDA-cleared disposable, fluid impervious
barriers must be used on digital image
sensors and phosphor plates

52
Types of Digital Imaging
Systems
There are two basic methods of acquiring
a digital x-ray image:
Direct imaging
Indirect imaging

53
Direct Digital Imaging
A solid-state sensor is the
image receptor
It contains an x-ray
sensitive silicon chip with
an electronic circuit
embedded in the silicon
The charge-coupled device
(CCD) sensor is the most
commonly used digital
receptor
Like telephones, some
CCDs are wireless
Other types have a cable
connected directly from the
sensor to the computer

54
Indirect Digital Imaging
Phosphor storage
imaging
The image receptor is a
thin flexible plate, the
size of conventional x-ray
film, that has been
coated with phosphor
crystals
The phosphor layer is
able to store the energy
of the x-ray photons for
some time
A scanner is required to
“read” the information
stored on the plate by
using a laser beam to
release the energy from
the plate and convert it
into a digital image

55
Phosphor Storage Imaging
After the plates are
scanned, they are exposed
to bright light that erases
all remaining energy, and
the plates are ready to be
used again
For infection control, the
imaging plate is inserted
into a specially designed
barrier envelope
The barrier envelope is
sealed by removing the
adhesive strip and
pressing the envelope
closed

56
Phosphor Storage Imaging
(Cont.)
The imaging plate is
positioned in the patient’s
mouth using the same
positioning techniques as
with conventional dental x-
ray film
After exposure, the imaging
plate is carefully removed
from the barrier envelope
and is then placed in a
scanner that uses a laser to
display the image on the
computer
The imaging plates cannot be
autoclaved, and extreme care
must be taken when handling
to avoid scratches or dust

57
Digitizing Film-Based
Radiographs
Film-based radiographs may be digitized
for viewing on a computer in much the
same way as any other document
Desktop scanners capture and digitize the
light signal of whatever is placed inside them
The process is similar to placing a film on a
duplicator lightbox
This type of indirect digital imaging is slightly
less detailed than direct digital imaging
because the resultant image is similar to a
“copy” of the image

58
Digital Imaging Software
Programs
Most computer software programs that are
used in digital imaging are capable of
performing electronic image enhancement
The operator can change the following image
variables either together or separately:
Contrast
Brightness
Image size (zoom)
Sharpness
Inversion (white to black and black to white)
Pseudocolor alteration

59
 Federal Regulations
The use of dental x-ray equipment is
regulated by both federal and provincial
regulations
All dental x-ray machines manufactured or
sold in the United States after 1974 must
meet federal regulations
These include safety specifications for
minimum filtration and accuracy of the
milliamperage time and kilovoltage setting
All x-ray equipment is also subject to
regional or provincial radiation health
codes

60
 Provincial/Federal
Requirements
The Healing Arts Radiation Protection Act is a
federal law that requires persons who take
dental radiographs to be properly trained and
certified
It is up to the individual province to determine its
own policy regarding the qualifications of
individuals exposing radiographs
HARP APPROVAL
Ontario requires that Dental Assists either pass
the National Dental Assisting Examining Board
exam as a level II OR have proof of HARP
approval from the educational institution, that the
DA has graduated from a HARP approved course

61
 Risk Management
Risk management policies are designed to reduce
the likelihood of a malpractice lawsuit against the
dentist
The dental assistant has an important role in risk
management
The dental assistant must be careful never to say
anything negative about the x-ray equipment, or how it is
working
Statements made without thinking (such as “The timer
must be off,” “This thing never works right,” or “The
solutions are weak”) are unnecessary and can make the
patient feel uncomfortable
Statements made by anyone at the time of an
alleged negligent act are admissible as evidence
in court

62
 Informed Consent
It is the dentist’s responsibility to discuss
the need for radiographs and treatment
procedures with the patient
The dental assistant may participate in the
process of obtaining informed consent
Patients must give informed consent for
dental radiographs, as well as for other
procedures

63
 For Valid Informed Consent
The patient must be provided with the
following information in lay terms:
The risks and benefits of imaging procedures
The person who will be exposing the images
The number and type of images
The consequences of not having the images
Any alternative diagnostic aids that may
provide the same information as dental
images

64
 Ownership of Dental
Radiographs
Dental images are the property of the
dentist, even though the patient, or the
patient’s insurance company, paid for them
This is because dental radiographs are a part of
the patient’s records
Patients may request a copy of their images;
this request should be written and signed by
the patients
Make an entry in the chart stating when and to
whom duplicate or digital dental images were
sent
Never give or send original radiographs to a
patient

65
 Quality
assurance
Chapter 40
Quality Assurance in the
Dental Office
Quality assurance (QA) is a way of
ensuring that everything possible is
being done to produce high-quality
diagnostic images
It includes both quality control tests that
monitor dental x-ray equipment, supplies,
and image processing
It also involves quality administration
procedures, including keeping schedules of
maintenance and record-keeping logs

67
Types of Quality Control
Tests
X-Ray Machine Quality
Control Steps
Dental X-Ray Film:
Traditional film Phosphorus
Plates
Check each box of film while
opening it
Reusable phosphor
Follow these steps to test film storage plates
for freshness:
In the darkroom, unwrap one
(PSP) require less
unexposed film from the newly radiation exposure
opened box
Process the film with the use of than film
Must be handled
fresh chemicals
Check the results
If the processed film appears
clean with a slight blue tint, the with care to avoid
film is fresh and has been
properly stored and handled and scratching the
is safe to use
If the processed film appears
surface
fogged, the film has been
improperly stored or exposed to
radiation and must not be used

70
View Boxes
A properly functioning The view box should
view box is necessary be periodically
for the interpretation of
conventional checked for dirt and
radiographs discoloration of the
The view box contains Plexiglas surface
fluorescent bulbs that The surface of the
emit light through an view box should be
opaque plastic or wiped clean daily
Plexiglas front Permanently
The view box should discolored Plexiglas
emit a uniform and or blackened
subdued light when fluorescent bulbs
functioning properly must be replaced
71
Darkroom Lighting
Check the darkroom for light leaks every 6
months:
While standing in the darkroom, turn off all the
lights, including the safelight
Once your eyes become accustomed to the
darkness, look around the room for any signs of
white light
Check the results
If the darkroom has no visible light leaks, the room
is safe for processing films
If light leaks are present, they must be corrected
with weather stripping or black electrical tape
before film processing is continued

72
Processing Solutions
The most critical component in the quality
control of film processing
You must replenish the processing solutions
daily and change them every 3 to 4 weeks, as
recommended by the manufacturer
As an alternative to using the calendar to
determine the freshness of solutions,
quality control tests can be used to
monitor the strength of the developer and
fixer solutions
You should check the processing solutions each
day before any patient films are processed

73
Stepwedge Radiograph
A stepwedge is a device that is
constructed of layered aluminum steps
When a stepwedge is placed on top of a film
and then is exposed to x-rays, the different
steps absorb varying amounts of radiation
When the film is processed, different
densities are seen on the dental radiograph

74