This document discusses Computed Radiography (CR) and Digital Radiography (DR), which are two methods for obtaining digital x-rays. CR uses existing x-ray machines and captures images digitally using imaging plates, which store x-ray data that is later extracted digitally. DR uses direct or indirect flat panel detectors in digital x-ray machines to directly or indirectly convert x-rays into electronic signals. Both methods allow for digital image processing and eliminate the need for darkroom film processing.

1. COMPUTED
RADIOGRAPHY &
DIGITAL
RADIOGRAPHY
Dr Mohit Goel
JR II, 1/10/2013

2. Digital X-ray Technology
There are two ways to obtain Digital X-rays:
• Computed Radiography
• Digital Radiography

3. Computed Radiography (CR)
• A Digital way of doing general radiography
with Conventional X-ray machines

4. What is CR?
• Computed Radiography (CR) is a process of
capturing radiographic data from a
conventional X-ray machine and processing
the data digitally to produce crisp and high
quality radiographic images

5. What is CR?…
• For exposure, an Imaging Plate (IP) is placed in a
cassette instead of a piece of film. The IP captures
and "stores" the X-rays
• The image is "developed" in a CR reader instead
of a film processor. The CR reader extracts the
information stored in the plate and produces a
digital image

6. What is CR?…
• Computed Radiography is a digital image
acquisition process that produces images that
have much better contrast than a
Conventional X-ray film-screen system

7. Basic Modules of CR
MATRIXLR 3300
Digitizer
Preview & ID Station
Processing Server
ID Tablet
Laser Camera
Cassette with
Imaging Plate

8. Imaging Plate (IP)
• The Imaging Plate looks like the intensifying
screens found in Conventional film-screen
cassettes
• They are made of photostimulable phosphor

9. Imaging Plate (IP)
• Instead of emitting light immediately when exposed
to X-rays, the photostimulable phosphor has the
special property of storing the X-ray energy in a
latent form and releasing the same when stimulated
by a laser energy in the CR Reader / Digitizer

10. Imaging Plate (IP)…
• Storage phosphors are unique because they
respond to a very wide range of X-ray exposures
• This latitude gives the flexibility in selecting
X-ray technique and takes care of under or over
exposure
• Regardless of the exposure, the image can be
displayed correctly
• As a consequence, retakes due to inappropriate
exposures are drastically reduced

11. Storage phosphor principle
laser stimulation
EmissionAbsorption
x-rays
electron
trap
electron
trap

12. Storage phosphor principle…
• The imaging plate is coated with
photostimulable phosphor, also called storage
phosphor
• The phosphor material is generally a kind of
Bariumfluorohalide
• The Imaging Plate contains not only the
phosphor layer, but also a protective coat, a
conductive layer, support and laminate layers

13. Storage phosphor principle…
• Incident X-rays excite electrons into a higher energy
level (electron traps)
• A latent image is created in the form of “stored energy”
• Stimulation with a scanning laser beam releases
electrons
• Typical wavelength of the stimulating laser is 633 nm
• Falling back, electrons emit luminescent light
• Typical wavelength of the emitted light is 390 nm

14. CR Readout

15. Storage phosphor principle…
• The emitted light intensity is proportional to
the original incident X-ray intensity
• The emitted light is captured with an optical
array and a photomultiplier and is digitized
• The residual image is erased from the plate by
an intense light source, which returns all
electrons to their original state. This makes
the plate ready to be reused for new exposures

16. • The storage phosphor plate fits inside a standard
size cassette and is exposed to X-rays exactly like
film
• The X-ray energy is stored on the plate in the form
of latent energy
How is a Storage Phosphor plate
exposed?

17. Patient ID Station
• Before exposing the cassette, the patient
demographic and exam data is stored on the
microchip attached on cassette
• This is done by inserting the cassette in a slot
of ID station and entering the data with the
help of keyboard
• When cassette is inserted in digitizer after
X-ray exposure, the digitizer reads both
patient data as well as X-ray exposure data
• The two data are combined to display images
along with patient data

18. Digitizer
• The plate is inserted into the digitizer
where it is scanned with a high power laser
• The laser light causes the storage
phosphors to release the energy they have
captured in the form of blue light
• In the digitizer, this blue light energy is
converted to electrical signals which are
then digitized to produce digital images

19. What happens to a Storage Phosphor
Plate after it is scanned?
• After exposure and scanning, the phosphor
plate is "erased" by exposing to a bright light
exposure within the digitizer
• The previous image stored in the phosphors is
removed and the plate is ready to be exposed
again

20. Workstation
• The digitized image
data is processed on
a processing server
and is displayed on
its monitor

21. How many times can we use a
Storage Phosphor Plate?
• The life of a phosphor plate depends on
how carefully it is handled. Physical
damage to the plate will limit its useful
life
• If properly cared for, a plate will produce
thousands of images
• Imaging Plates are known to last more
than 50000 Exposure Cycles

22. Does CR require X-ray machine
replacement?
• No, CR uses the existing X-ray equipment
• One CR system can support multiple x-ray
rooms

23. How is the workflow different with
CR ?
• Instead of taking the film cassette to a dark
room for processing, the technologist takes
the cassette with imaging plate to the CR
reader for digital processing of the image
• Instead of manually taking the films to the
reporting radiologists , the softcopy images
reach the workstation almost immediately

24. How is the workflow different with
CR ?…
• The time required to acquire a Digital
image is much less compared to
conventional darkroom process
• The film is the first product in Conventional
where as the film is the last product in CR

25. CR WORKFLOW
Rx
Network
Digitizer
Printing
MATR IXLR 3300
Identification
Processing server
Exposure
Cassette with Imaging Plate

26. Rx
Network
Digitizer
Printing
MATR IXLR 3300
Identification
Processing server
Exposure
Cassette with Imaging Plate
The cassettes fit into X-ray table. After the exposure, the cassette is identified in the ID-station. Here patient
and exam related information is stored. Next the digitizer reads the identification data, handles the plates, reads
the image and sends out a raw dataset in DICOM-format. The automatic processing server processes the image
according to the type of exam. For each type of exam, an optimized image processing parameter set-up is used.
The processing server then pushes the processed image to the preview station for previewing. After approval
the image is routed to other destinations such as a printer, a review station and an archive server.

27. Digital Radiography
This technique is performed by digital X-ray
machines with flat panel detectors

28. Digital Radiography
Digital Radiography uses two types of
detectors:
• Direct
• Indirect

29.  TFT = THIN-FILM TRANSISTOR ARRAY

30. Indirect detectors
Uses a two step
process that first
converts X-rays
into light, then
converts that
light energy into
electronic signals

31. Direct detectors
• Direct detectors
automatically convert X-
rays into electronic signals.
 X-rays interact with
semiconductor material
 Amorphous selenium
 X-rays converted directly
into electrical charge
 No intermediate steps

32. Direct detectors
• The flat panel detector consists of an amorphous
selenium semiconductor X-ray absorber coating over
a thin-film transistor array of amorphous silicon
• In this system,X-ray photons are immediately
converted into electronic signal
• This immediate conversion eliminates the need for
additional steps to capture and convert incident X-ray
energy
• Corrective image processing which can result in
increased image noise is reduced with the highly
efficient X-ray energy conversion of direct DR

33. Limitations of Conventional X-ray process
(X-ray film / Screen/Darkroom)
• Film has a limited exposure latitude i.e less
detail contrast
• Time consuming & cumbersome
• Intolerant to exposure errors
• Repeat X-rays ( More radiation exposure )
• Film wastage

34. Limitations of Conventional X-ray process
(X-ray film / Screen/Darkroom)…
• Cannot be duplicated without loss of quality
• Film storage is a problem
• Scatter radiation reduces contrast and increases
patient dose
• Quality control is an issue

35. What are the advantages of
Digital X-rays?
• Post processing (soft tissue and bony details can
be viewed at same time )
• Reduction in hazardous X-ray dose to patients
• More info on one image
• Constant image quality
• Possibility of viewing X-ray images wherever
needed

36. What are the advantages of
Digital X-rays?…
• Digital images are of extremely high
quality
• Digital images have a future scope of
better image management
• Facility of giving multiple images of
investigative studies on a single high
definition laser film

37. How is Digital X-ray similar to Conventional
basic radiography process ?…
• Radiography consists of following
functions:
-Image data acquisition
-Image processing
-Reproduction of image
-Storage

38. How is Digital X-ray similar to Conventional
basic radiography process ?…
• In Screen film system, all the processes are
done on the X-ray film itself which is used
for:
-Image data acquisition
-Image reproduction
-Storage

39. How is Digital X-ray similar to Conventional
basic radiography process ?…
On the other hand, Digital X-ray distributes all the
processes into different stages:
• Imaging plate and digitizer are used for
image data acquisition in CR and Amorphous
Selenium detector array in DR
• Processing server is used for image processing and
storage
• Workstation monitor is used for image reproduction

40. What is the role of Digital X-ray
in PACS Environment?
• Digital X-ray is the only film less way to
link the existing general radiography set up
into the digital environment of PACS

41. Features of Digital X-ray
• Image enhancement
• Printing
• Annotation
• Black border
• Panoramic dental package
• Full leg / Full Spine

42. Under/over exposure

43. Soft tissue and bone windows

44. Digital image manipulation
• Image pre-processing
• Scale the data to appropriate range
• Contrast enhancement – Anatomy specific
grayscale manipulation
• Spatial frequency enhancement

45. Soft tissue and bone windows

46. Zoom

47. Collimation

48. Collimation
MISS.PADMINI 20YRS,F 14/08/2004 20:15:01
SKULL, MASTIODS 23
MISS.PADMINI 20YRS,F 14/08/2004 20:17:01
SKULL, MASTIODS 23
MISS.PADMINI 20YRS,F 14/08/2004 20:15:01
SKULL, MASTIODS 23
MISS.PADMINI 20YRS,F 14/08/2004 20:17:01
SKULL, MASTIODS 23

49. Magnifying glass

50. Invert image

51. Invert image
DIGITIZER, EMERGENCY 1O/07/2004 22:3O:28 DIGITIZER, EMERGENCY 1O/07/2004 22:3O:28

52. Annotation

53. Vertical flip
MR.RAVINDER 33YRS, M 19/08/2004 14:20:08
RIGHT LEG, AP&LAT 268
MR.RAVINDER 33YRS, M 19/08/2004 14:20:08
RIGHT LEG, AP&LAT 268

54. Multiple images on single film
MRS.SWAPNA 30YRS, F 29/06/2004 09:15:32

55. Multiple images on single film
MRS.FARIDA 30YRS ,F 12/8/2004
09:15:23

56. CR vs DR
CR
 imaging plate
 Processing is done
in a Digital Reader
 Signal sent to
computer
 Viewed on a monitor
DR
 transistor receiver
(like bucky)
 directly into digital
signal
 seen immediately
on monitor –

57. Thank
you