2. CONTENTS
INTRODUCTION
Schedule of radiographic QA procedures
Daily procedures
Weekly procedures
Monthly procedures
QA of digital radiography
Conclusion
References
3. INTRODUCTION Quality Assurance- steps taken to make sure that a dental office or radiologic
facility will produce consistently high-quality radiographs with minimum cost
and pt exposure
QA
Quality control-Conventional X ray units Digital x-ray units
• Processing control(manual and automatic) - solid state sensors(CCD)
• Performance of x –ray inputs -phosphor plates
• Viewboxes -digital monitors
• Cassettes
• Dark room
Quality administration
• Assiging responsibility . Scheduling corrective
action
• Determining optimum testing frequencies . evaluation and revision.
• Providing training
• Evaluating test results
4. Schedule of Radiographic QA procedures
Daily Tasks:
For conventional set up
Compare the radiographs with
reference film
Enter findings in retake log
Replenish processing solutions
Check temperature of
processing solutions
Make step-wedge test of
processing system
For digital radiography
CCDs/CMOS
Visual inspection of wiring
and casing
For phosphor plates:(CR –system)
Visual inspection of any
external scratches
5. Weekly
For conventional set up:
Replace processing solutions
Clean processing equipment
Clean view-boxes
Review retake log
Monthly
For conventional set up:
Check darkroom safe-lighting
Clean intensifying screens
Rotate film stocks
Check exposure charts
For digital radiography
CCDs/CMOS and PSPs
Checking the uniformity of the
image
7. Daily tasks
Several tasks should be performed daily to ensure excellent
radiographs:
Compare Radiographs with Reference Film:
Simple and effective means for constant monitoring of the quality of images produced.
Soon after processing solutions are replaced, mount a patients film that has been
properly exposed and processed with exact time-temperature technique on a corner of
the viewbox.
This image with optimal density and contrast – serve as reference for radiographs made
in the following days and weeks.
Subsequent images are compared with the reference-if any discrepancy is identified,
source determeined and corrected
8. Enter findings in Retake Log:
Effective way of reducing the number of faulty
radiographs
Record all errors for films that were rendered
undiagnostic before the retake
9. Checking the automatic x-ray processor/manual solutions:
the purpose is to determine the proper freshness of developer solution and developing
temperature
Most usual problem is depleted developer or cold developer solution due to failure of the heating
element or its temoerature control
Step wedge test:
Provides accurate monitoring of day to day processing conditions
Measures the speed of imaging system and image contrasts-sensitive measures of the processing
environment.
An aluminum step wedge can be purchased or can be made using a stack of 5 lead foils from film
packets
Lay the step wedge on top of a film packet and expose using usual setting for an adult bitewing view.
After changing to fresh solutions develop the film and save it as a base line reference film.
Similarly expose a series of films and store it in the refrigerator.
Everyday, one of the pre-exposed film is run through the processor or processed manually and is
checked if density and contrast remain constant when compared with the baseline film.
10. If not of the same density-the solutions should be replenished or changed.
developer should be replenished after 4 full mouth surveys, panoramic films, or 80 IOPAs
4 to 6 onces of fresh developer should be added
2 to 3 ounces of fixer will be need – fixer lasts twice as long as developer
If problem persists, temperature should be checked;
All manual processors should be maintained at 70⁰F.
For replenishing/changing automatic processing solutions:
Always fill the fixer solution first. Rinse out the developer solution tank in case any fixer splashed into it
while filling the fixer tank. Then fill the developer tank.
After filling the processor , turn it on. If the processor has a thermostat to adjust the temperature, let it
reach the predetermined operating temperature.
11. WEEKLY TASKS:
Clean processing equipment:
Regular cleaning:
necessary for optimal operation
Clean the solution tanks before solutions are changed
For automatic processing:
For normal weekly cleaning, use warm water and non abrasive
brush to clean the rollers
Periodically(2-4 times in a month)use the systems cleaner
recommended by the manufacturer to remove heavier build-up
After cleaning with systems cleaner, one should rinse for twice as
long as the manufacturer recommends
Inspect the rollers, gears and turning mechanism for signs of wear
and reassemble
12. Clean view-boxes:
Clean view-boxes weekly to remove any particles or defects that may
interfere with film interpretation.
Should be of uniform luminance
A difference in luminance can create confusion and may effect
accurate interpretations.
If a bulb or tube fails, it is best to replace all of them.
Review Retake Log
Review the retake record weekly.
Identify any recurring problems with processing conditions or
operator techniques.
Use the information to educate staff or to initiate corrective actions.
13. Monthly tasks
Check dark room safelighting
Film becomes fogged in the darkroom because of
inappropriate safelight filters,
excessive exposure to safelights
Stray light from other sources.
To check for light leaks in a darkroom,
turn off all the lights,
allow your vision to accommodate to the dark and check for light leaks,
Mark light ;leaks with chalk or masking tape.
Weather stripping is useful for sealing light leaks under doors
14. Penny test:
Can be done monthly to evaluate for fogging caused by inappropriate
safe lighting conditions:
Open the packet of an exposed film and place the test film in the area where film
are unwrapped and clipped on the hanger
Place a penny on the film and leave it in this position- approximate time required
to unwrap and mount a full mouth set of films—usually about 5 minutes
Develop the test film-if image of the penny is visible ,room is not light-safe
Each type of film used should be tested.
Assess the integrity of safelights(GBX-2 filters with 15 watt bulb)-
should be intact without cracks
15. Clean intensifying screen
Clean all intensifying screens in panoramic and
cephalometric film cassettes monthly.
Scratches or debris – recurring light areas in the images
Foam supporting the screens must be intact and capable
of holding both screen closely against the film
If close contact not maintained-image loses sharpness
16. Stocking films and storage of CCDs,CMOS, PSPs
For conventional X-ray films:
Dental x-ray film is stable when properly handled
Store it in a cool, dry facility away from a radiation source.
Rotate stock when new film is received – old film does not
accumulate in storage.
Always use the oldest film first
For CCDS , CMOS,PSPs:
Should be kept in a cool dry place, must be kept dust-free
CCDs should be kept covered by disposable polythene cover
every time an exposure is made and should be changed after
every exposure
17. Check exposure charts:
Each month inspect exposure tables listing the proper
kVp , milliamperes(mA) and exposure times for making
radiographs of each region.
Help ensure all operators use the appropriate exposure
factors
Usually, mA is set at its highest setting;kVp is fixed;and
exposure times is varied-patient size and area of interest.
Exposure times are initially determined emprirically
18. Yearly task
Calibrating the X-ray machine:
X ray machines are generally quite stable and only rarely is a
malfunctioning of the machine the acuse of poor radiographs.
So, machines need to be calibrated only annually unless a
specific problem is identified.
The x-ray machine is annually tested for the following three
factors relating to the x-ray- quantity, quality and
collimattion.
19. Checking the quatity of the x-ray beam(output)
Purpose is to verify that output of the machine has not changed since the
last procedure.
Quantity is mainly affected by mA circuit and mainly by exposure time
To measure for quantity, set the machine at a standardised set of
exposures(for eg; 0.25 seconds, 7 or 10 mA and 65 or 70 kVp and measure
the quantity of radiation being generated.
Can be done using a pocket dosimeter or using an inexpensive aluminum or
lead foil wedge.
If the baseline(first reading) has been 180mR(say) and the present reading
is the same, then no further testing of beam quantity is needed.
In case of step wedge-on comparing with a baseline step wedge image with
the present step wedge image is exactly similar in terms of DENSITY and
CONTRAST,then the machine is functioning normal.
If not, then mA circuit and timer is checked
20. Checking the timer:
Procedure employed demonstrates the principle-
self rectified dental x-ray machines-xrays are generated in
impulses
constant potential machines –x-rays are produced
continuously for the selected exposure time interval.
A simple brass spinning top is used in self rectifying machines
where as in constant potential machines an electric timer
meter is used.
21. Using spining brass top:
A brass top on which there is a brass disc with a single small hole on
the periphery is placed on top of an occlusal film or a panoramic film
in a cassette
The machine is set at 0.25 ie 15 impulses(say)(60 impulses in 1s)
Central ray is directed perpendicular to the spinning top, which is in
motion
On the resultant image one small dark spot will be produced for each
impulse.
Dark spot produced should match with exposure time set
22. Checking the mA circuit:
Procedure usually demonstrates the principle of mAs reciprocity
Usually done in machines where there two mA settings usually
10mA and 15 mA.
As long as the mAs factor remain the same for both settings and
output measured with pocket dosimeter remains the same for the
both settings, mA circuits are said to be operating properly
Firstly, the operator sets at 70 kVp, 15mA and 1 sec(15mAs),measures
the output in mR
Then , the operator sets at 10 mA and 1.5 seconds(15mAs) at 70
Kvp,again measures the output in mR
Both mR readings should be same, if not servicing is required.
23. Checking the quality of the X-ray beam:
Quality of the x-ray photons is the function of kVp that
determines the wavelength and penetrating power of the
x-ray beam.
These two are influenced by accuracy of Kvp setting and
Focal spot size.
24. Checking the penetrating power of the beam:
This procedure demonstrates HVL principle
“50% of the x-ray photns should penetrate through a standardized thickness of a given
material(usually Al) depending on kVp”
As per the standard;
For machines working at max kVp of 69 or less;50% of x-ray should pass through at least
1.5mm of Al
For those working at max kVp of 70+;HVL should be at least 2.5mm Al
To test HVL, discs of 1.5mm or 2.5mm of Al is placed above a pocket dosimeter and the
machine is set at its max kVp.
The operator then compares the output readings with and without discs in place.
Should be checked if the readings meet the accepted standard.
25. Checking the accuracy of kVp setting:
Procedure visible demonstrates the kVp measurement.
If the x-ray machine fails the HVL test, then kVp circuit must be checked
A kVp meter is generally used to check the kVp circuit.
The machine is set at max kVp stting and aimed at the target area on kVp meter.
Exposure time should be long enough for the kVp meter to obtain a reading
Measures the wavelength and frequency of the beam- gives an accurate read-out
of actual kVp.
Should be same as that of the setting
If different, problem is asso with the machine itself, not the external power
supply.
26. Checking the focal spot:
Purpose is to evaluate the surface area of the focal spot that
becomes pitted over time and enlarges.
An enlarged focal spot decreases definition and increases
magnification. A small focal spot size provides sharpness that is
measured by resolution.
Resolution is the ability to visibly separate or resolve images of small
objects placed close together.
Can be checked by using a test object-containing a no. of bar
patterns – to test the resolution.
27. Focal spot checker:
Inexpensive device – 6 inch plastic cylinder –has paired bar patterns on a lead
wafer on one end and other end is open
Open end centered over a occlusal film and an exposure is made by placing the
end of PID against the closed end.
If 11 or 12 line pairs visible on the processed film- excellent resolution
7 or less line pairs-poor resolution-focal spot need to be replaced (either by
rebuilding or purchasing a new machine).
28. Checking the collimation of the x-ray beam:
Purpose to ensure proper reduction of size of the x-ray beam
As per standards; beam must be collimated to 2.75inches at the tip of the
PID
Collimation test:
Operator simply places end of the PID against a rare –earth fluorescent screen or
a loaded panoramic cassette-exposure time is set at 1 or 2 seconds
Lights turned off-operator looks through the leaded window if the fluorescence
is limited to diameter of PID
Can also process the panoramic film to check if the exposed area is limited to the
DM of the PID
29. Alternate test for collimation:
Four no.2 dental films placed on a piece of paper in the form of cross-shaped template
PID and location of each film is traced on the paper-film identified with lead numbers or
small puncture holes
PID is positioned to cover approx. half of each of the films
Exposed using half the max. anterior exposure-processed and returned to proper order.
If exposed area >2.75inches in DM-collimator opening is too large.
Rarely , beam may not be centered on open end of the PID –due to faulty positioning of
collimator-result in unavoidable cone-cuts-resolved by adjusting the collimator by
tapping or changing the PID
30. Panoramic slit alignment test:
Done to check wether the opening on the X-ray tube head is in alignment with the
opening in the image receptor
Procedure:
Tape film packets to the top and bottom of the slit on the image receptor
Mark the position of the slit on the film packetswith a ballpoint pen
Expose the film
Observe if the exposed portion of the film is in alignment with demarcation caused by the
use of the pen
Record the results
Discrepancy if any should be reported to x-ray service provider for repair as soon as
possible.
31. QC procedures for digital radiography
Digital image quality assessment should include:
Investigation of any significant deterioration in quality
and instigation of appropriate corrective measures:
Recording all investigations together with identified
cause and action taken
Regular annotation of image quality record
Subjective assessment of quality of each radiograph.
32. QC of digital equipment:
Solid state sensors:
can be either CCDs or CMOS:
They require
Regular checks to ensure no evidence of cracks or
damage to the cable and sensor casing
Regular assessment of non-uniformity of receptor.
33. Phosphor plates:
These require:
Regular checks for visible scratches and dirt
Being passed daily through the reader to detect scratches
Regular cleaning following manufacturer's instructions
Regular assessment for non-uniformity of receptor
34. Monitors
These require:
Regular cleaning
Regular QA calibration/checks for
Distortion
Grey scale reproduction
Limiting resolution(at both high and low contrast)
Unifromity
Can be done using specific test patterns designed such as TG18-QC test
pattern(by AAPM)and SMPTE test patten designed by SMPTE
36. REFERENCES:
Oral radiology- Principles & interpretation-white &
pharoah-5th edition
Essentials of dental radiography-johnson,
Mcnelly,Essay(6th edition)
Essentials of dental radiology and radiography-whaite &
Drago (5th edition)
Principles Of Dental Imaging-
Langland,Langlaise,preece(2nd edition)
Hinweis der Redaktion
Qualtiy assurance – come into general use to describe the administrative and technical efforts-made to identify and correct equipment problems before they have become so severe so as to affect the diagnostic quality of the radiographs being produced.for eg;if QA priciples concerning periodic changes of the developing solutions are not meticulously followed
Implememtation of QA assurance program will lead to improved diagnostic performance and a substantial savings in cost.
QA procedures have been shown to lower the level of radiation to which the patient is exposed by decreasing the number of retakes and by preventing overexposure of the patient in an attempt to compensate for processing deficiencies.
A well run QA program also serves to enhance our understanding of many of the concepts in quality image production.