Oral Radiology Image Characteristics PDF

Summary

This document is a lecture on oral radiology, describing various image characteristics such as density and contrast. It also details controlling factors including milliamperage (mA), exposure time, kilovoltage (kVp), subject thickness, and source-film distance during dental radiography procedures. The factors that affect the image quality are also outlined. This is part 1.

Full Transcript

Oral Radiology

IMAGE CHARACTERISTICS
Part 1
OMD-711n
Radiography in Dental Clinic
 Objectives of
Lecture
By the end of the lecture ,the student should be able to :-

1-Choose and purchase the best X-ray machine
suitable for a specific workload.

2-Identify the best exposure parameters during
conventional imaging.

3- Demonstrate the significance of linking the
chosen exposure parameters to yield an ideal
diagnostic image
IMAGE CHARACTERISTICS are :

I-Visual II-Geometric

Sharpness
Density (Definition)

Size
Contrast
Shape
 I- Density
It is the overall degree of darkening of an exposed film

Primary Factors Secondary Factors
1. Subject thickness and
1. Exposure factors density.
(amalgam, bone, etc.; as
 mA
object density increases,
 Exposure time image density decreases)
 kVp 2. Filtration
3. Collimation
2.Source- film distance 4. Film (speed – processing)
Controlling factor:
1-Milliamperage (mA):
 An increase in Milliamperage produces more x-
rays that expose the film and, as a result,
increases film density.
 If the Milliamperage is increased, the film
density increases and the radiograph appear
darker.
 On other hand, if the Milliamperage is
decreased, the film density decreases and the
radiograph appear lighter.
2- Exposure time:
 An increase in exposure time increases film density
by increasing the total number of x-rays that reach
the film surface.
 So, the film density increases, and the radiograph
appears darker& vice versa.
 The product of mA setting and exposure time (mA ×
s, or mAs) is often used as a single parameter to
denote the total number of photons produced.
 For instance, a machine operating at 10 mA for 1
second (10 × 1 = 10 mAs) produces the same
number of photons when operated at 20 mA for 0.5
second (20 × 0.5 = 10 mAs).
3- Operating kilovoltage peak (kVp):
 An increase in operating kilovoltage increases film
density by producing x-rays of higher energy (more
penetrating ability).
 If the operating kilo-voltage is increased, the film
density increases and the radiograph appear darker
& vice versa.
 Increasing the kVp increases the potential
difference between the cathode and the anode,
increasing the kinetic energy of the electrons as
they move toward the target.
 Increasing the kVp of an x-ray machine increases:
The number of photons generated
The maximal energy of the photons
The mean energy of the photons
4- Subject thickness:
 Fewer x-rays reach the film in a patient with an
increased amount of soft tissue or thick, dense
bones. As a result, the radiograph has less density
and appears lighter.
 Adjustments in operating kilovoltage,
Milliamperage, or exposure time can be made to
compensate for variations in the size of patients
and subject thickness.
5- Subject Density:
 Variations in the density & the amount of the
subject (tooth structure, metal, composite, etc.)
exert a deep effect on the image. As a general,
film density (darkness) decreases when object
density increases.
6- Source- film distance:
 The intensity (I) of an x-ray beam (the number of
photons per cross-sectional area) is inversely
proportional to the distance (D). If the distance ↑ the
intensity ↓ thus the density will decrease.
 Changing the distance between the x-ray tube and
the patient, such as by switching from a machine
with a short tube to one with a long tube, has a
marked effect. Such a change requires a
corresponding modification of the kVp or mA to keep
constant the exposure to the film.
 Density (cont.)
 Finally, the overall density of the film affects the
diagnostic value of the film.

Too Light Ideal Density Too Dark
The x-ray tube
Photo of an X-ray Tube

Beryllium Window Leaded glass

Target Focusing cup
(filament located inside)
 2. Radiographic Contrast
 Contrast refers to the range of densities on a
radiograph. It is defined also as the
difference in densities between light and dark
regions on a radiograph.
 Thus an image that shows both light areas
and dark areas has High Contrast.
 In dental radiography, the terms (Short–Scale
Contrast) and (Long-Scale Contrast) may be
used to describe the appearance of a
radiograph.
 Short Gray Scale of Contrast
 A dental radiograph that shows
only two densities, i.e., areas of
black and white.

 It can also be described as
having High Contrast, in which
areas of black and white &
easily differentiated from each
other.

 High contrast is best for caries
detection. (WHY???)
 Long Gray Scale of Contrast
 A dental radiograph that have
many densities or many
shades of gray, has a long
contrast scale.
 Many shades of gray can also
be described as having Low
Contrast.
 Best for periapical or
periodontal evaluation.
(WHY???)
Low Contrast

High Contrast
 Contrast is influenced by:
Primary Factors Secondary Factors

1. Exposure factors 1. Subject contrast
 kVp 2. Filtration
3. Collimation
4. Film (contrast -
processing)
1- kVp
 Increasing the kilovoltage affects film
contrast by increasing the average energy
of the x-rays and by producing higher
energy x-rays.
 X-rays with higher energy are better able
to penetrate tissue.
 A 90-kVp setting produces a radiograph
that has Low Contrast (more shades of
gray).
 A 70-kVp setting produces a radiograph
with High Contrast (fewer shades of
gray). 40 50 60 70 80 90 100
1- Subject Contrast:
IIs the features of the subject that affect
radiographic contrast. It is affected largely by:
a) The subject's thickness.
b) Density: In order to see an image on the
film, the subject being radiographed must
have different subject densities.
c) By increasing or decreasing the kilovoltage.
SUBJECT CONTRAST IN RELATION TO IMAGE
CONTRAST

 Dense structures (thickness, density and
composition) as bone  absorb rays more than soft
tissues, cavities or canals.

 Increasing KV > 90 with low subject contrast  long
grayscale image.

 Decreasing KV < 60 with high subject contrast 
short gray scale mage.
 Step Wedge

lead bar

aluminum

Step Wedge Pattern
 White No white

Many gray
Few gray shades
shades

Black Black

Short gray scale Long gray scale

High Contrast Low Contrast
 2- Film Contrast:
 Is the capacity of radiographic films to display
differences in subject contrast.

 A high-contrast film shows areas of small
difference in subject contrast more than does a
low-contrast film.

 The film contrast can be affected by:
A) The hidden qualities of the film: The quality
of the film are under the control of the film
manufacturer and cannot be changed by the
dental radiographer.
B) Film processing: is under the control of the
dental radiographer. Development time or the
temperature of the developer solution affects the
contrast of a dental radiograph. An increase in
development time or developer temperature
results in a film with increased contrast.

The recommended
Increased developer time
developing time and
or temperature
temperature.
C) Improper handling of film: such as storage at too
high a temperature, exposure to excessively bright
safelights, or light leaks in the darkroom, also
degrades film contrast.
D) Fogging on an x-ray film: results in increased film
Density. Film contrast is reduced by the addition of
this undesirable density.
Common causes of film fog:
a) Improper safe lighting
b) Development of film at an excessive temperature or for
a prolonged period
c) Exhausted processing chemicals
d) Storage of film at too high a temperature
e) Scatter radiation
f) Using expired film
 Film Fog:
 Fogging on an x-ray film: results in
increased film density. Film contrast is
reduced by the addition of this undesirable
density.
 Film fog can be reduced by proper film
processing and storage.
Film contrast:
 This is incorporated into the film by the
manufacturer.
 In general, high film contrast (green curve below)
requires very precise exposure of the film; if it is too
high or too low, the film will be too dark or too light,
resulting in a non-diagnostic film.
 With low film contrast (purple curve) the film will be
diagnostic over a broader range of film exposure.
Density

Exposure of film
The quality, or average energy, of the x-ray beam is increased with
an increase in kVp or an increase in filtration. The quantity, or
number of x-rays, is increased with an increase in mA, exposure
time and kVp setting.

Quality Quantity
kVp (primarily)

mA no change

Time no change

Filtration

Collimation no change
Distance Intensity per cross-sectional area
Important Relationship
kVp and Scatter
The amount and energy of scatter radiation exiting the patient depends, in part, on the
kVp selected. Examinations using higher kVp produce a greater proportion of higher-
energy scattered x-rays compared with examinations using low kVp.

Volume of Tissue Irradiated and Scatter
The volume of tissue irradiated is affected by both the part thickness and the x-ray
beam field size. Therefore, the greater the volume of tissue irradiated, because of
either or both factors, the greater the amount of scatter radiation produced.

Beam Restriction and Patient Dose
As beam restriction or collimation increases, field size decreases, and patient dose
decreases. As beam restriction or collimation decreases, field size increases, and
patient dose increases.

Collimation and Scatter Radiation
As collimation increases, the field size decreases, and the quantity of scatter radiation
decreases; as collimation decreases, the field size increases, and the quantity of
scatter radiation increases.
Collimation and Radiographic Contrast
As collimation increases, the quantity of scatter radiation decreases, and radiographic
contrast increases; as collimation decreases, the quantity of scatter radiation
increases, and radiographic contrast decreases.
Over-collimation → ↓↓ size of the beam → ↓↓ x-ray photons → ↓↓density.

Under-collimation → ↑↑ size of the beam → ↑↑ x-ray photons → ↑↑ density.
It will also ↑↑ the scattered radiation → decreased patient safety and contrast.

 Over-filtration → removal of excess rays →
↓↓ x-ray photons → ↓↓density.
N.B.: image contrast will not be directly
affected if the kVp is not changed.

 Under-filtration → beam of both long and
short wave length → bad contrast and more
scattering.
N.B.: beam quantity will not be affected if
the mA is not changed.
 Therefore;
IMAGE CHARACTERISTICS are :

I-Visual II-Geometric

Sharpness
Density (Definition)

Size
Contrast
Shape
Geometric Characteristics

1. Sharpness &
Resolution.
2. Magnification.
3. Distortion.

33
1- Sharpness & Resolution
 Sharpness: It is the ability of a
radiograph to reproduce the boundaries /
edges of an objects.
 Resolution: It is the ability to reveal small
objects that are close together.
Both are interdependent, influenced by
the same geometric variables.

34
Sharpness and Resolution
It usually is measured by radiographing an object made up of a
series of thin lead strips with alternating radiolucent spaces of
the same thickness. The groups of lines and spaces are arranged
in the test target in order of increasing numbers of lines and
spaces per millimeter.
Typically, direct exposure films used for
intraoral radiography can delineate 20
lp/mm (line pairs per millimeter) or more.
Screen film combinations for panoramic and
cephalometric radiography resolve
approximately 5 lp/mm.
 Penumbra
 Umbra: it is the area on the
film that represents the image
of a tooth.
 Penumbra: it is the area
around the umbra.
So, The penumbra is the zone of
Umbra
unsharpness along the edge of
the image; the larger it is, the
less sharp the image will be. Penumbra
How The Penumbra Is Formed?

X-rays is emitted in
divergent way from either
extreme of the target, and
from many points in
between, pass through the
edge of the object and
give a share in the
penumbra.

Penumbra Umbra

37
Sharpness affected by:

A. Focal spot size.
B. Source – object (teeth) distance.
C. Object (teeth) - film distance.
D. Intensifying screens.
E. Motion.

38
 A- Decrease Focal Spot Size, Increase Sharpness

 As seen in the diagram below, x-rays from
opposite ends of the larger target (at right) pass
through the edge of the tooth and create a larger
penumbra around the image of the tooth on the
film.

Target (source) Tooth Umbra Penumbra
During purchasing an X-ray Unit ,we must put in mind that one of the
components of the machine (called the focal spot ) affects the
sharpness of the image (sharpness is not a visual character but is a
geometric character).

Focal spot size
The smaller the focal spot (target), the shaper the image
(teeth) will be.

Sharpness measures how well the details
(boundaries/edges) of an object are
reproduced on a radiograph
Focal spot size
B- Increase Source-tooth Distance, Increase Sharpness

 When the target is closer to
the tooth, as in (B), the A
penumbra is larger.
 If the target is moved away B
from the tooth (A), the
penumbra surrounding the
tooth image is smaller,
creating a sharper image.

 N.B, The distance from the
tooth to the film is Film
unchanged. Target (source) Umbra
Tooth Penumbra
 C- Decrease Tooth-film Distance, Increase Sharpness

 As x-rays coming from
opposite ends of the target pass
through the edge of the tooth
they continue in a straight line,
diverging from each other.

 The farther the film is from the
tooth, the more the x-rays
diverge, creating a wider
Film
penumbra. This decreases the
sharpness of the image.
Target (source) Umbra
Teeth Penumbra
 D- Intensifying Screens Decrease Sharpness
 Extra oral films use intensifying screens which contain
special phosphor crystals that produce light when exposed
to x-rays.
 This light in turn exposes the film. Notice how the light
spreads out as it leaves the phosphor crystal, this results in
a less sharp image.
 Compare the Periapical film and the same area on a
panoramic film. The Periapical image is much sharper.

Film
Panoramic Periapical
E- Patient Motion Decreases Sharpness

 If the patient moves during the exposure of a film, the
images will be blurred, or unsharp, as seen below.
 2-Magnification
 In radiology, magnification is an increase in
the size of an object.
 It is caused by the divergence of the x-ray
beam as it moves away from the x-ray tube.
 The amount of magnification can be reduced by:
 Increasing the distance from the target to
the teeth (Source-object Distance).
 Decrease the distance from the teeth to the
film (Object-film Distance).
46
 Increase Source-object Distance, Decrease
Magnification

 The closer the source is to the teeth, the more
the x-rays spread out as they pass by the
teeth, resulting in increased magnification &
vice versa.

Target
16” Target
8”
Source-object Distance Large
 Decrease Object-film Distance,
Decrease Magnification

 When the film is placed closer to the tooth as
seen below, the x-ray beam does not spread
out as much and magnification is decreased
& vice versa.

Target
16”
Increase Source-object Distance, Decrease Magnification

Target
16” Target
8”

Decrease Object-film Distance, Decrease Magnification

Target
16”
 3- Distortion
 Distortion is unequal magnification i.e. a change
in the shape & size of an object or the
relationship of that object with surrounding
objects.
 It is affected by:
1) The film-teeth relationship (angle between the
film and teeth):
 Are they parallel with each other.
 Or the long axis of the film at an angle to the
long axis of the teeth.
2) The alignment of the x-ray beam:
 Is the beam perpendicular to both the teeth
and the film (Paralleling Technique).
 Or is it at an angle to both the teeth and film
(Bisecting Angle & Occlusal Techniques).
In the paralleling technique:
 The long axis of the film and the long axis of
the tooth are parallel.
 The x-ray beam is directed perpendicular to
both the long axis of the tooth and x-ray film.
As a result, distortion is minimized or
eliminated.
In the bisecting angle and Occlusal techniques:
 There is an angle between the teeth and film,
dependent on the patient’s oral anatomy,
which influences film placement, and the
technique used.
 Occlusal technique requires a larger angle
between the film and teeth, approaching 90
degrees).
 Geometric Effect of influencing
Influencing factors
characteristics factors
 focal spot size =  sharpness
Sharpness Focal spot size
focal spot size =  sharpness
 Crystal size =  sharpness
Film composition
 Crystal size =  sharpness
 movement =  sharpness
Movement
 movement =  sharpness
 TFD =  magnification
Magnification Target-film (TFD) distance
 TFD =  magnification
 OFD = magnification
Object-film alignment
 OFD =  magnification
Object and film parallel
=  distortion
Distorsion Object-film alignment Object and film not
=  distortion
parallel
Beam perpendicular to =  distortion
x-ray beam alignment
object and film

Beam not perpendicular
=  distortion
to object and film
 Ideal Radiograph

1. Image same size as object.
2. Image same shape as object.
3. Image has good detail.
4. Image has good density and
contrast.
Mandibular molar periapical film comes closest to satisfying properties of an ideal
radiograph (either paralleling or bisecting).
Questions