Patient Image Optimization & Viewing the Medical Image PDF

Summary

This document discusses patient-image optimization in radiography, covering patient factors like subject contrast, thickness, and density, as well as image-quality factors such as spatial and contrast resolution. It also touches on pathology and how it affects technique. The document delves into the implications of pathology for technique.

Full Transcript

Principles of Radiography 1
Patient-Image Optimization &
Viewing the Medical Image
Julie Kloft, MSRS, RT(R)
Clinical Coordinator & Professor of Radiography
 Patient-Image Optimization

Technique
Considerations

1. Patient/Subject Factors
2. Image-Quality Factors
3. Exposure Technique Factors
 Patient/Subject Factors
Subject Contrast
Patient Thickness
Tissue Mass Density
Effective Atomic Number
Object Shape

Not positioning, but rather the technique to compensate for the
patient’s size, shape, and composition. (Positioning relates to
geometric factors.)
 Patient/Subject Contrast
Patient (or subject) contrast is the degree
of differential absorption resulting from the
differing absorption characteristics of the
tissues in the body.
 Subject Contrast
Radiographic Contrast = IR Contrast x Subject Contrast
(IR Contrast is expressed as the Average Gradient)

Component of radiographic contrast
determined by the size, shape, and x-ray
attenuating characteristics of the subject
being examined AND the energy of the
beam.
 Subject
Contrast
High Low
 Body Types

Hypersthenic: Large frame, overweight
Sthenic: Average, strong, active
Hyposthenic: Thin, but healthy appearance
Asthenic: Small, frail, emaciated
 Patient Thickness
Assuming comparable body composition, a
thick body section attenuates a greater
number of x-rays than does a thin body

The degree of
subject contrast
is directly
proportional to
the relative
number of x-rays
leaving those
sections of the
body.
Attenuation
Attenuation is the
reduction in the total
number of x-ray
photons remaining in
the beam after
passing through a
given thickness of
material.
 Attenuation
is the result of x-
rays interacting with
matter and being
absorbed or
scattered.

is determined by the
amount and type of
irradiated material.
Patient Density

Thicker, denser body parts absorb
more radiation.
 Tissue Mass Density
Different patients may have equal body part
thicknesses, but different mass densities.

≠
 Effective Atomic Number
When the effective
Effective Atomic
Number
Substance
atomic number of Human Tissue

adjacent tissues Fat
Soft Tissue
6.3
7.4
varies greatly, Lung 7.4

subject contrast is
Bone 13.8
Contrast Material

very high Air 7.6
Iodine 53
Barium 56
Other
Concrete 17
Molybdenum 42
Tungsten 74
Lead 82
 Pathology
Certain diseases can increase or decrease
tissue thickness or composition (change
the effective atomic number or density).
 Pathology
Collecting information can begin even BEFORE you
meet the patient, by reviewing the requisition. Any
history or diagnosis provided should be reviewed, as it
may give you clues about potential pathology.

Examples:
 Degenerative
 Emphysema
 Ascites
 Hemothorax
 Osteoporosis
 Pathology
Taking a good patient history helps
prevent repeat radiographs!

Example: You have a patient coming for a CXR because of a
cough. If you find your patient has a history emphysema, you
should adjust your technique. If you didn’t ask or get any additional
information, other than a cough, you may have images like these
and need to repeat.
 Pathology
In addition to talking to the patient, you
should also observe the patient for any
physical indications or outward signs of
pathology.
Radiopaque
Radiopaque tissue
Metal hardware
ABSORBS x-rays and
appears white on the
Contrast
radiograph.
Bone

Soft Tissue
Radiolucent tissue
attenuates few x-rays and
Air
appears black on the
radiograph.

Radiolucent
Pathology & Technique

As soon as you
identify your patient,
you should begin
evaluating them (and
their history) for
indications that might
affect your technique.
 Questions to ask yourself
when you meet your patient:
1. What are the physical characteristics of
the part to be examined?
 Internal deviations from normal are usually
indicated by external deviations.

2. Can you identify indicators of pathology
of the part being examined?
3. Is the patient going to be able to hold
still for the procedure?
 Pathology: Additive conditions
(aka Constructive Pathology)
If a disease causes the affected body
tissue to increase in thickness, effective
atomic number, and/or density, there will
be greater attenuation of the x-ray beam.
Hydrocephalus
Additive pathology is inversely proportional to IR exposure.
 Additive pathology means reduced IR exposure.

Additive pathology is directly proportional to technique.
 Additive pathology requires increased technical factors.
 Pathology: Additive conditions
Generally additive pathology requires
increased kVp to penetrate thicker, more
radiopaque parts.
 +15% of the kVp will double the exposure to the IR,
so increasing 5-15% of the kVp is sufficient for most additive
pathology.

Effusion identified on
image with appropriate
technique, but over-
exposed radiograph
does not demonstrate it.
 Sample Additive Pathologies
Chest
Atelectasis Abdomen
Extremities/Skull
Bronciectasis Aortic Aneurysm
Acromegaly
Cardiomegaly Ascites
Chronic Osteomyelitis
Congestive Heart Failure Cirrhosis
Hydrocephalus
Empyema Calcified Stones
Osteoblastic Metastases
Pleural Effusion
Multiple Sites Osteochondroma
Pneumoconiosis
Abscess Paget’s Disease
Pneumonia
Edema Sclerosis
Pneumonectomy
Tumors
Pulmonary Edema
Tuberculosis
Pathology: Destructive conditions
When a disease causes the affected body
tissue to decrease in thickness, effective
atomic number, and/or density, there will
be less attenuation of the x-ray beam.
Multiple Myeloma
Destructive pathology is directly proportional to IR exposure.
 Increased destructive pathology means increased IR
exposure.

Destructive pathology is inversely proportional to technique.
 Destructive pathology requires decreased technical
factors.
Pathology: Destructive conditions
Generally destructive pathology requires
decreasing the mAs to compensate for the
changes in the patient.
 A decrease of 25-50% of the mAs is usually sufficient for most
pathologic conditions.

Osteoporosis is
evident on a
properly exposed
radiograph. If over-
exposed, it may not
be evident.
Sample Destructive Pathologies
Extremities/Skull
Active Osteomyelitis
Abdomen Aseptic Necrosis
Aerophagia Carcinoma
Bowel Obstruction Degenerative Arthritis
Chest
Fibrosarcoma
Emphysema
Gout
Pneumothorax Multiple Sites
Hyperparathyroidism
Anorexia Nervosa
Multiple Myeloma
Atrophy
Osteolytic Metastases
Emaciation
Osteomalacia
Osteoporosis
 SOME Pathology=No Changes
Many diseases do not significantly affect
thickness or density and do not require
any adjustment to the technique.

Examples:
Fractures (without gross swelling)
Ulcers
Diverticula
 Things to Think About…
Skeletal: 50% loss of bone before a change
can be seen on radiograph
Respiratory: requires long scale contrast
(120 kV) to see lung processes and penetrate
mediastinum
GI Tract: 2 major considerations
Bowel Obstruction = taut (air) decrease technique
Ascites = feels like dough (fluid) increase technique
Radiographic Quality

The fidelity
(clarity/exactness)
with which the
anatomical
structure that is
being examined is
imaged
 What makes a high-quality
radiograph???
While there are
specific factors
that affect quality,
there is no
precise formula
for labeling it.
Image Quality By
 Image-Quality Factors
Spatial Resolution
Contrast Resolution
Distortion
IR Response

These qualities are ALL influenced by the
patient characteristics!
 Spatial Resolution
The ability to image small objects
with high subject contrast (such as
bone and soft tissue)
 Spatial Resolution
(Last week!)

The ability to image small objects with high
subject contrast.
(In DR, limited by pixel size!)

Most people can see objects as small as 200 um!
Contrast Resolution
The ability to
distinguish
anatomical
structures of similar
subject contrast
(liver/spleen)
 (Last week!)

Contrast Resolution
The ability to
distinguish between
and to image
similar tissues. CR
& DR have better
contrast resolution
than film-screen
because of wider
dynamic range.
 Image or Recorded Detail
(generic/old phrase often used to describe the appearance of anatomic structures on image)

The degree of sharpness of
structural lines on a radiograph.

Sharpness of image or recorded detail was an attempt to describe spatial resolution.
 Visibility of Detail

The ability to
visualize recorded
detail when contrast
and optical density
are optimized.

Visibility of image detail was related to contrast resolution and image contrast.
 Resolution

The ability to
image two
separate objects
and visually
distinguish one
from the other.
 Distortion
A misrepresentation of the true size or shape of an
object on a finished radiographic image.
Shape Distortion

Actual Size

Foreshortening:
appears shorter than actual length

E l o n g atio n:
appears longer than
actual length
 Size Distortion

Magnification can distort the image
and make an item appear much
larger/smaller than it actually is.
 Reducing Distortion

Distortion is reduced by positioning the
patient body part parallel to the image
receptor and having the Central Ray
perpendicular to both.
 Viewing the
Medical Image
The adoption of digital imaging and viewing images on a digital
display device requires an understanding of photometry (the
science of the response of the human eye to visible light).
 Photometric Quantities
The first attempt to quantify human vision
was made in 1924 by the International
Commission on Illumination (CIE), and
included a definition of light intensity, the
candle, the footcandle, and candle power.
 Response of the Eye
The CIE recognized the difference between
photopic (bright-light vision using cones)
and scotopic (dim-light vision using rods).
 Bright-light vision is best at 555 nm.
 Dim-light vision is best at 505 nm.
 Photometric Units
The basic photometric unit
is the lumen.
Luminous flux is the
fundamental quantity of
photometry and is
expressed in lumens (lm).
Luminous flux describes
the total intensity of light
from a source.
100 watts of energy consumed and 1490 lumens of light output.
 Illuminance
The intensity of light incident on a surface.
 One lumen of luminous flux incident on one
square foot is a footcandle (fc).
 One lumen of luminous flux incident on one
square meter is a lux (lx).
1 fc = 10.8 lx

Location Illuminance
Digital Reading Room 1 fc
Twilight 5 fc
Indoor Room 100- 200 fc
Cloudy Day 1000 fc
OR 3000 fc
Sunny Day 10,000 fc
 Luminance Intensity
Describes a property of the source of light
(viewbox or digital display).

Luminance intensity is the luminous flux that is
emitted into the entire viewing area and is
measured in lumens per steradian or candela.
 Luminance
Measures the brightness of a source
 Expressed in units of candela per square meter
or nit
 Cosine Law
When a digital display device is viewed
straight on, the luminous intensity is
maximum. When viewed from the side,
illumination and contrast are reduced.

The reduced projected surface area follows the mathematical function called cosine.
 Inverse Square Law
Luminous intensity decreases in proportion to
the inverse square of the distance from the
source.
 Hard Copy vs Soft Copy
Until the 1990s, essentially all medical
images were “hard copy,” and presented to
the Radiologist via film on a viewbox.
 CT and MR were the first to move to digital images.
However, it was common for these images to be laser
printed and viewed on a viewbox!
 Liquid Crystal Display
(LCD) Monitor
Images are displayed pixel by pixel with an
intense white backlight to illuminate each
pixel.

Most have 1 MP (1000 x 1000 pixels). High resolution = 8 MP (2160 x 3840 pixels).
Image Luminance
Only about 10% of the
backlight is transmitted
through a monochrome
LCD monitor. About half
of that is transmitted
through a color monitor.
 Aperture Ratio
On an LCD monitor, the portion of the pixel
face that is available to transmit light is called
the Aperture Ratio.
 The intrinsic noise of an LCD monitor is low,
so there is better contrast resolution.
 Aperture Ratio is to an LCD monitor what
Fill Factor is to a digital
image receptor.
 Light-Emitting Diode Display
(LED) Monitor
LED monitors display images by turning on and adjusting
the brightness of colored diodes. An entirely white image
with black text will therefore require many more
illuminated diodes – and far more power – than white
text on a black background.
 Light Emission
Any material that emits light in
response to an outside stimulus is
called a phosphor and the
resulting light is called
luminescence.
 Fluorescence is when visible light is
emitted ONLY while the phosphor is
stimulated.
 Phosphorescence is when the phosphor
continues to emit light after stimulation.
 Electroluminescence is the production of
light by the flow of electrons, such as
within crystals.
 Backlight

 All video monitors are really LCDs with a more
intense backlight powered by LED.
 LED monitors have a longer life-expectancy by
at least a factor of two over fluorescent backlit
monitors.
 LED monitors use less energy and give off
less heat.
 Ambient Light
LCD monitors reduce the influence of ambient
light on image contrast.

Best viewing condition is in near total darkness.
 Viewing Angle
There is a serious loss of image contrast
when the image on an LCD is viewed off-
center.

The principal disadvantage of an LCD monitor is the dependence of the viewing
angle—contrast falls sharply as the viewing angle increases.
 Ergonomics
The viewing
requirements of flat
panel digital display
devices has led to
reconfigured
ergonomically-designed
digital workstations for
the Radiographers and
Radiologists.

Ambient light levels must be reduced to near-darkness for best viewing!
 Software Artifacts
The digital imaging system will manipulate the
output of the IR to correct for potential
artifacts (dead pixels, dead rows/columns of
pixels).

 Digital images are obtained as raw data sets
which are ready “for processing”
 “For processing” images are then manipulated
into “for presentation” images
 Calibration
Calibrating digital
equipment allows the
software to recognize
dead pixels and “auto-
fill” the areas.
Offset and gain
images are automatic
calibration images to
make the IR response
more uniform.
Gain images are generated every few months.
Offset images are generated many times each day.
Pre-Processing
The ability to manipulate
images BEFORE display.
Primarily automated process of
producing artifact-free digital
images.
Before the image is sent “for-
processing,” dead pixel areas
are repaired using interpolation
techniques to assign digital
values to each dead pixel, row,
or column.
 Pre-Processing:
Flatfielding
Flatfielding is performed pre-
processing to offset the irregular
variation of the anode-heel effect.
Before flatfielding After flatfielding
 Pre-Processing:
Signal Interpolation
Digital IRs and monitors have millions of
pixels, so it is to be expected that some
individual pixels will become defective (to
respond differently or not at all).
Signal Interpolation corrects the defective
pixels by averaging the response of the
surrounding pixels.
Problem Solution
Defective Pixel Interpolate adjacent pixel signals
Image Lag Offset correction
Line Noise Correct from dark reference zone.
 Pre-Processing:
Image Lag
Each type of digital IR generates an electronic
latent image that may not be made completely
visible.
Image lag is the image that is not completely
visible and is corrected by applying offset
voltage before the next image is acquired.

Problem Solution
Defective Pixel Interpolate adjacent pixel signals
Image Lag Offset correction
Line Noise Correct from dark reference zone.
 Pre-Processing:
Line Noise
There are voltage variations in the buses that
drive each pixel. Line noise is the linear
artifacts that appear on the final image due to
the voltage variations and is corrected via
voltage correction from a row or column of
pixels in a dark, unexposed area of the IR.

Problem Solution
Defective Pixel Interpolate adjacent pixel signals
Image Lag Offset correction
Line Noise Correct from dark reference zone.
 Post-Processing
Operator manipulation of the image after it is
acquired.
Process Results
Annotation Label the image
Window/Level Expand the digital grayscale
Magnification Improve visualization and spatial resolution
Image Flip Reorient the image presentation
Image Inversion Make white-black and black-white.
Subtraction (DSA) Improve image contrast
Pixel Shift Re-register an image to correct for patient motion in series
Region-of-Interest Determine average pixel value
 Post-Processing:
Image Annotation
Annotation is the process of adding text to
an image.
 (Last week!)

Dynamic Range
A 16-bit Dynamic
Range DR system has
65,536 shades of
gray. The human eye
can only discern about
30 shades.
Window/Leveling
allows us to fully
visualize each region.
The exact number of shades of gray is determined by bit depth.
12-bit dynamic range: 2bit depth = 212 = 4096
14-bit dynamic range: 2bit depth = 214 = 16,384
16-bit dynamic range: 2bit depth = 216 = 65,536
 Post-Processing:
Image Display Adjustments
By manipulating the window width and levels, the
Radiographer can make all of the shades of gray
available VISIBLE.
Terminology Action Changes
Window Width Contrast Inverse:
(visibility of detail) ↑WW = ↓contrast
Window Level Density Direct:
(brightness) ↑ WL = ↑ density
 Post-Processing:
Magnification

The larger matrix size monitors have better
spatial resolution because they have smaller
pixels. This allows magnification of a region
of an image to “zoom in” to make the smallest
anatomic objects visible.
 Post-Processing:
Image Flip

Digital images may be
reoriented by flipping
them vertically or
horizontally. Image
Flipping is used to bring

Additionally, newer technology allows for all-axis orientation correction.
 Post-Processing:
Image Inversion
Pathology, tubes, and
lines of often made more
visible by applying
image inversion, which
results in a black
appearance of bone and
a white appearance of
soft tissue.
 Post-Processing:
Image Subtraction

Image subtraction, commonly used in Digital
Subtraction Angiography (DSA), allows
images taken in a series to “subtract” portions
of the image to make other areas easier to
see.
Post-Processing:
Pixel Shift
Often used in
conjunction with
subtraction, pixel shift
allows for correction of
patient motion in a
series of images.
Post-Processing:
Region of Interest

Region of Interest
allows for rescaling of
the digital image and
computing the mean
pixel value for the
area of interest.
 Post-Processing:
Additional Features
 Edge Enhancement helps highlight
fractures and small, high-contrast
tissues.
 Highlighting can be effective in
identifying diffuse, non-focal disease.
 Pan, scroll, and zoom allow for
careful visualization of precise
regions of an image.
 See you
next week!