1. Lecture 4 Beam restricting Devices, their Use and Maintenance
Topic 1 Importance of beam restricting devices
Topic 2 Types of beam restricting devices
Topic 3 Quality assurance tests of beam restricting devices
Topic 4 Compression of area of interest

2. Topic 1 Importance of beam- restricting devices

3. Topic 1 Importance of beam restricting devices
These devices restrict the primary x-ray beam to the area of interest.
The larger the area covered by primary x-ray beam, the greater the scattered radiation produced.
Scattered radiation must be minimized. They increase radiation dose and add to film darkening thus reducing visualization of details.

4. Topic 1 Importance of beam- restricting devices
Beam was not restricted to the chest – the area of interest. Entire abdomen and part of face of baby was exposed unnecessarily.

5. Topic 1 Importance of beam- restricting devices
Unrestricted beam-considerable scatter
Restricted beam – less scattered radiation

6. Topic 2 Types of beam-restricting devices
a. Attached to x-ray tube housing
Aperture diaphragms - lead sheets with
circular, square, or rectangular openings
Cones – detachable metal tubes of different lengths, shapes, and sizes of opening
Variable aperture collimators – adjustable
lead plates or shutters , contain "cross hairs",
a light source, and a mirror to project the
light
Aperture diaphragms are inserted near the tube window and are usually used with a cone and a variable aperture collimator. The cone length and size of opening affect the size of the x ray field. Variable aperture collimators are also called light beam diaphragms.

7. Beam- restricting devices
Removable
metal cone
Variable aperture collimator

8. Variable aperture, multiple shutter collimator
Diaphragm closer to window reduces off-focus x rays.
Multiple shutters
Multiple shutters
Smaller sized field reduces size of primary beam.

9. Topic 2 Types of beam - restricting devices
b. Not attached to x ray tube housing Lead blockers – used to divide a cassette when more than one exposure is made on a single film; reduces unnecessary exposure of film thus improving image quality
Lead blockers limit the chances of film fog due to the unnecessary x ray exposure.

10. Use of lead blockers
Place blocker on couch for lateral projections of thoracic, lumbar, sacrum or
coccyx spine.
Position blocker next to patient's back to absorb radiation that will not pass through spine.
Defective lead rubber aprons could be cut
into a range of sizes to serve as blockers.

11. Topic 3 Quality assurance tests of beam limiting devices
Collimation or limiting the x-ray beam to the area of interest requires use of beam restricting devices. It is good practice to collimate such that the resulting image has collimated edges on all four sides of film

12. Topic 3 Quality assurance tests of beam- restricting devices
Bring tube to rest on table top to check
that all four edges of square light beam
diaphragm touch the table top when
using vertical beam. Do several times
during the day.
Do the same test with cone inserted in
front of the x ray tube window.
Caution: Cones sometimes become bent when dropped or bumped.

13. Topic 3 Quality Assurance tests of beam restricting devices
Do collimator-beam alignment check at least every six months.
Do check of alignment of centre of x ray
beam at least every six months.

14. Collimator-beam alignment test
Using 100 cm focus-film distance (FFD), set collimator at 20 cm x 20 cm field size on surface of loaded cassette.
Place metal coins or paper clips on top of cassette as shown in next slide.
Expose the film at 60 kVp and 4 – 8 mAs.
Process the film.
Check whether the distance between outer edges of image and of paper clips/coins is
within +/- 2% of FFD.

15. Line diagram showing metal coins and field size
Coin to identify right upper corner.
Edge of light.
Cassette.

16. Collimator-beam alignment test result

17. Check of alignment of centre of x-ray beam
Place unexposed loaded cassette in centre of bucky tray and centre tube to cassette.
Move tube to 100 cm FFD to bucky tray. Reduce longitudinal collimators to a thin slit (e.g. 0.5 cm). Close lateral collimators. Expose using 60 kVp and 4 – 8 mAs.
Do not remove cassette.

18. Check of alignment of centre of x ray beam (cont)
Close longitudinal collimators and open lateral collimators to a thin slit. Expose film again. Process film.
Bend film in half and check that exposed "cross" is in film centre.
Acceptable deviation: 1 cm on either side of centre.
Can also be done for non-bucky radiography.
Just move tube so 100 cm FFD is to cassette top.

19. Centre of beam alignment test result

20. Topic 3 Summary Beam restricting devices
may be attached or not attached to tube housing
require periodic checks
are necessary for radiation protection and contribute to good image quality
minimize primary radiation
minimize scatter radiation
Use a compression band.
Use a compression band

21. Topic 4 Compression of area of interest
Reducing patient thickness by compression minimizes production of scattered radiation, thus reducing radiation dose.
Device used : compression band.

22. Topic 4 Compression of area of interest
Compression band over abdomen reduces its volume. This reduces scatter radiation.

23. Lecture 4 Summary Beam-restricting devices are important in
radiation protection.
These devices should be checked regularly.
Regular performance of quality assurance tests is in accordance with ALARA.