1. Radiation Protection in Paediatric Radiology
Part No...., Module No....Lesson No
Module title
Radiation Protection in Paediatric Radiology
Radiation Protection of Children During Computed Tomography
L06
IAEA Post Graduate Educational Course in Radiation Protection in Pediatric Radiology 1

2. Educational objectives
At the end of the programme, the participants
should:
Recognize that CT is a relatively higher dose imaging procedure.
Understand dose management strategies for computed tomography in children.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

3. Answer True or False Reduction of kVp in CT reduces the dose.
CT contributes % of the dose from radiological examinations in developed countries.
The same CT protocol used for children and adults will result in a higher dose to adults.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

4. Contents Overview of CT systems: SDCT and MDCT.
Dose levels in CT and risk attributable to paediatric CT.
Importance of application of justification in paediatric CT.
Optimization of image quality and patient dose in paediatric CT.
Selection of appropriate technical parameters.
Use of shielding devices in paediatric CT.
Dose management strategies in paediatric CT.
Requirements for staff: experience and training.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

5. Computed Tomography
Computed tomography (CT) is the method that extends the clinical capabilities of X-ray imaging:
High contrast sensitivity for visualizing soft tissues.
Production of configurable data sets.
Three-dimensional (3D) representations
Multiplanar depictions
“Volume” CT
Dynamic (e.g. perfusion, cardiac) information
Tissue characterization (dual energy technology)
Advances in computed tomography (CT) technology have continued to improve existing and open new clinical applications.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

6. Nobel prize for medicine 1979
Computed Tomography
Since 1972; then…
Hounsfield
Cormack
Nobel prize for medicine 1979
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

7. Computed Tomography ..and now…
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

8. Modern CT Scanners
Modern CT scanners are 3rd generation, that is the tube and detectors rotate together around the patient
Slip ring technology allows for spiral hence volume scanning
Principle of spiral CT. Patient is transported trough the gantry, x-ray tube traces spiral path around the patient when acquiring data
M. Mahesh, MDCT physics, the basic technology, image quality and radiation dose, Wolters Kluwer, 2009
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

9. Single Detector (SDCT) vs Multi-detector (MDCT) Computed Tomography
SDCT and MDCT design. The difference is the presence of multiple-row detectors
in the longitudinal direction with MDCT yielding multiple slice options for single rotation
M. Mahesh, MDCT physics, the basic technology, image quality and radiation dose, Wolters Kluwer, 2009
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

10. Multi-detector (MDCT) Computed Tomography
MDCT detectors
M. Mahesh, MDCT physics, the basic technology, image quality and radiation dose, Wolters Kluwer, 2009
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

11. CT and Paediatric Radiology
The patient dose in CT is an important issue for children.
In some centres, the exposure factors used for scanning children are the same as for adults.
CT scanning contributes most to collective dose from exposures from medical imaging due both to relatively high dose per exam and to the increasing use of this modality.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

12. Facts About CT… Facts about CT…
69 million CT examinations per year for all ages in USA in 2007.
Approximately 10% growth rate per year
7 million CT examinations per year in children
40-50 % increase in paediatric CT from 2005/06.
Up to 31% of paediatric body CT examinations are multiphase in some reports
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

13. Facts About CT…
The frequency of CT examinations is evenly distributed at all ages:
33% are performed in children under age of 10
Repeated examination:
30% of adults and children have three or more CT scans
METTLER, F.A., et al., J. Radiol. Prot (2000)
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

14. CT as a Dose Contributor
Part No...., Module No....Lesson No
Module title
CT as a Dose Contributor
CT examinations:
comprise only 17% of all radiological examinations, but...
contributes to 49% of the effective dose all radiological examinations
Mettler et al. Helath Phys 2008, 95:502-7
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography
IAEA Post Graduate Educational Course in Radiation Protection in Pediatric Radiology

15. Amount of Radiation Resulting From CT
Examination
Effective Dose (mSv)
Chest X-ray Equivalents
3-view ankle radiography
0.0015
0.07
2-view chest radiography
0.02 1
Radionuclide cystogram
0.18 9
Flouroscopic cystogram
~0.33
~16
Radionuclide bone scan ~5
~250
Brain CT 2
100
Chest CT
up to 3
up to 150
Abdominal CT
up to 5
up to 250
Frush D, et al, CT and Radiation Safety: Content for Community Radiologists
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

16. Part No...., Module No....Lesson No
Module title
Why is this so?
Radiography CT
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography
IAEA Post Graduate Educational Course in Radiation Protection in Pediatric Radiology

17. Why is this so? Dose distribution* *in relative units
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

18. Risk of CT Examination Unique consideration in children:
Life time to manifest the bioeffects
More radiosensitive tissues
Dose is considered cumulative over time
Risk is higher for females and younger age groups
From a single abdominal CT in paediatric age, lifetime estimated risk for fatal cancer is 1: : 2000.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

19. Risk Versus Benefit
Important to distinguish between individual risks and collective, public-health risks
The individual risks are small, so the benefit / risk ratio for any child will generally be very large,
…but the exposed population (~7.0 million children/yr in the US) is large
Even a very small individual radiation risk, when multiplied by a large (and increasing) number of children, is likely to produce a significant long-term public health concern
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

20. CT in Paediatric Radiology
The frequency of paediatric CT examinations has been increasing over the past 20 years
Reduced requirements for sedation and allowance of examination of younger, sicker and less co-operative children
Increased speed of acquiring diagnostic information
Increased number of multiple scans
Attention must be given to adapting protocols to suit children taking into account that they are more sensitive than adults
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

21. In Paediatric Radiology…
If identical CT head examination protocol is used:
Adult dose: 1.5 mSv
Child dose: 6 mSv
Huda et al. Radiology, 1997, 203:417-22
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

22. In Paediatric Radiology…
It estimated that between a third and half of the examinations occurring have questionable indications.
Many are conducted using inappropriate technical factors.
Frush, RSNA, 2006,
Berenner Pediatr. Radio.l 32 (2002) 228 – 231,
Oikarinen et al. Eur Radiol 19 (2009)
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

23. Justification and CT
It is very important that each examination is rigorously justified, thus…
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

24. Justification for CT: Practical Advice
Justify CT examination rigorously and eliminate inappropriate referrals.
Perform only necessary CT examinations.
Reduce the number of multiple phase scans.
Work to account for previous procedures.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

25. Justification for CT: Practical Advice
Use referral guidelines and appropriateness criteria when available
Use alternative approaches, such as ultrasound, MRI where appropriate
Include justification in clinical audit
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

26. How to achieve the objective?
Respect age-specific pathology and its prognosis.
Consider potential contribution of the scan to patient management and outcome.
Consider the patient’s medical imaging record with respect to ionizing radiation
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

27. How to Achieve the Objective?
Respect cost and radiation exposure.
Replace CT by examination with no or with lower radiation exposure (e.g. US, MRI).
Delay/cancel follow-up examination unless a decision based on scan is needed now.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

28. Optimisation and CT One size does not fit all...
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

29. Optimisation and CT
For paediatric CT examinations, the use of specific radiographic technical parameters should be promoted as:
Child size the kVp and mA. 
One scan (single phase) is often enough. 
Scan only the indicated area.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

30. General Recommendation
You must use paediatric protocols to reduce the dose for the same image quality as in adults
Make sure there are no inappropriate high (e.g. adult) parameter settings behind the name paediatric protocols
Plan paediatric scans according to patient’s size and age
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

31. Generic Requirements for Optimisation
Inform and prepare the patient and accompanying person(s).
Be familiar with CT dose descriptors.
Realise lower noise usually means higher doses; accept noise if scan is diagnostic.
Make sure operating conditions balance image quality and radiation exposure. 
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

32. Generic Requirements for Optimisation
Optimize scan parameters within the axial plane.
Optimize a set of tube current settings for paediatric examinations.
Optimize scan parameters for volume coverage.
Scan minimal length and minimise repeated scanning at identical areas.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

33. Equipment, Protocol, Dose and Image Quality
In most children a tube voltage of 80–100 kVp will suffice, especially in children with a body weight <45 kg.
In adolescents, a tube voltage of 100 kVp for the thorax and 120 kVp for the abdomen is usually sufficient
Recent studies with phantoms suggest that the optimal tube voltage in children may be even lower (60kVp) at least for some indications
Nievelstein
Nievelstein, Pediatr Radiol, 2010
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

34. Equipment, Protocol, Dose and Image Quality
Part No...., Module No....Lesson No
Module title
Equipment, Protocol, Dose and Image Quality
Spiral or helical scanning is preferable in paediatrics as an entire volume is imaged
Short tube rotation times reduce movement artefacts and provide more detailed cardiac imaging
One main benefit for MDCT scanners is speed of acquisition rather than dose reduction
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography
IAEA Post Graduate Educational Course in Radiation Protection in Pediatric Radiology

35. Equipment, Protocol, Dose and Image Quality
An increase in pitch can result in a shorter scan time and (in some scanner types) in a dose reduction
In modern MDCT scanners this may not be the best option (due to overranging)
If effective mAs is used, an increase in pitch will result in an increase in the tube current
Therefore, it is usually more dose efficient to keep the pitch as low as possible (<1) and if needed manually decrease the tube current
Nievelstein, Pediatr Radiol, 2010
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

36. Equipment, Protocol, Dose and Image Quality
Multi-slice scanners have potential to deliver higher dose
by having a wider beam irradiating a number of detector rows to achieve multiple slices simultaneously
as well as owing to more extensive clinical use
However.…
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

37. Equipment, Protocol, Dose and Image Quality
Strategies for dose reduction in MDCT:
Hardware improvements
Software improvements, as tube current modulation, image reconstruction algorithms, …
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

38. Equipment, Protocol, Dose and Image Quality
Modern scanners give automatic or semiautomatic correction of tube current (mA) for patient size (mA modulation).
Significant dose reduction (20–50%) without appreciative loss of image quality.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

39. Equipment, Protocol, Dose and Image Quality
Image thickness:
Should be chosen depending on the size of the child and the application
Use maximal acquisition collimation (assuming this would result in scanning at lower mA) appropriate for specific diagnosis
Narrow collimation in MSCT and 1 mm slices on some SDCT result in a higher dose (increase in mAs to maintain image quality)
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

40. Equipment, Protocol, Dose and Image Quality
2. Pitch:
SDCT: a pitch factor 1.5 is recommended for most examinations
25% reduction in dose compared with using a pitch of 1
MDCT: reduction in dose due to greater pitch may not be achieved
tube current (mA) can be automatically adjusted to keep the dose and noise the same
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

41. Equipment, Protocol, Dose and Image Quality
3. Tube potential (kVp)
There are few advantages to using a high tube potential (kV).
Without a reduction in tube current (mA) this leads to a significantly higher dose.
100 kVp or 80 kVp is usually adequate for children.
Lowering of kVp enhances contrast
10 kg patient transmits 3-4% while an adult transmits less than 0.1%.
Be aware that images with high noise, even if they do not look very crisp, may provide the diagnostic information.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

42. Equipment, Protocol, Dose and Image Quality
4. Lower tube current (mA):
Lower tube current (mA) should be used for scanning kids.
High tube current is required only when there is a need for high image detail ( in low contrast settings)
Decrease of mA according to body diameter and use of exposure charts if AEC is not available (dose reduction 70-80%), Lucaya, et al, 2000, AJR 175:895-92
Use of tube current modulation technology results in dose reduction by 60% for paediatric scanning, Kalra et al, 2004, Radiology, 233:649-57
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

43. Equipment, Protocol, Dose and Image Quality
5. Gantry Tilt
A straight gantry results in irradiation of a smaller volume of tissue compared with a tilted gantry and is recommended.
Exception: tilt is used to avoid unnecessary exposure of sensitive tissues, e.g. in brain CT for avoiding the orbits.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

44. Equipment, Protocol, Dose and Image Quality
6. Scan Length
Scan the minimum length required and be restrictive in defining upper and lower limits.
Optimise scan parameters for volume coverage by using representative volume sample(s) when the entire volume is not needed (by sequential scans with gaps) to reduce dose-length product
Vock and Wolf , Dose Optimization and Reconstruction in CT of children, in Radiation Dose from Adult and Paediatric MDCT, Springer, 2007
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

45. Equipment, Protocol, Dose and Image Quality
7. Reconstruction Algorithm
Appropriate reconstruction algorithms, window levels and window settings should be used
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

46. Equipment, Protocol, Dose and Image Quality
8. Dose Indices
Protocols must be adjusted by the operator to take into account the patient's age and weight (size).
Newer scanners indicate the volumetric CT dose index (CTDIvol ) and Dose-length product (DLP) on the console (Requirement from IEC ).
This allows the user to automatically:
See the relative effect on dose owing to changes in kVp, mA, collimation and pitch,
Estimate the effective dose to patient.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

47. Radiation Dose Indices for CT
Dose displays on modern multislice scanners:
Volume CTDI (CTDIvol)
Dose Length Product (DLP)
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

48. Dose Indices for CT
CTDI is a local per scan dose and is dependent on kVp, mAs and slice collimation.
DLP is an integral dose over the scan length and number of series and depends on pitch and dose
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

49. Computed Tomography Dose Indices
Effective dose, E, provides risk estimate which depends on the body size and organs imaged as well as on the integral dose.
E is calculated as the product of DLP and conversion factors
Shrimpton et al, BJR (2006) 79,
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

50. Typical Doses in Paediatric CT
Exam type
Relevant
organ
Range of absorbed
organ doses (mGy)
Range of
effective doses
(mSv)
Head unadjusted*
(200 mAs)
Brain
23- 49
Head adjusted
(100 mAs)
Abdomen unadjusted
Stomach
Abdomen adjusted
(50 mAs)
5 - 11
6 - 12
*"Unadjusted" refers to using the same settings as for adults. "Adjusted" refers to settings adjusted for body weight.
NCI:
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

51. Equipment, Protocol, Dose and Image Quality
9. Viewing Conditions:
Make sure windows levels and settings are adequate and that the monitors are calibrated.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

52. Equipment, Protocol, Dose and Image Quality
10. Shielding:
Lead shielding can be place over the male gonads if:
the edge of the volume of investigation is less than 10-15cm away
it does not interfere with the image
Dauer, et al, BMC Medical Imaging 2007, 7:5 doi: /
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

53. Equipment, Protocol, Dose and Image Quality
10. Shielding:
The use of reusable bismuth attenuation shields is possible for sensitive organs such as the eyes, gonads, breasts and thyroid.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

54. Shielding
The bismuth eye shield is simple to place and covers only the eye
In-plane shields are associated with greater image noise and streak artifacts. However, shields reduce radiation dose. Automatic exposure control did not increase radiation dose when using a shield.
Karla et al, Korean J Radiol. 10:156-63, 2009
This adult patient has a 3 layer bismuth latex eye shield in place. While artefact is seen into the globe, no artefact is transmitted into the brain. Standoff pads can reduce surface artefact
Hopper KD, et al, Am J Neuroradiol 22:1194–1198,2001
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

55. Equipment, Protocol, Dose and Image Quality
11. Training
The examination should always be supervised by a radiologist experienced in paediatric imaging
If all listed factors are taken into consideration, significant dose reduction can be achieved
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

56. Training Following options are available on modern scanners
Tube current modulation (mA, mA/slice, effective mAs), pitch, noise level setting, field-of-view for bow tie filter, kVp, beam (vs slice) collimation…
This requires a skilled operator:
Who knows well the model of the scanner using
Trained in paediatric imaging to adjust the examination parameters according to examination type, age and/or size of the child
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

57. Radiologists, Physicists and Technologists’ Responsibilities
Improve awareness of need to decrease CT radiation dose to children.
Be committed to make a change in daily practice by team work between radiologists, technologists, referring healthcare providers and parents.
Medical physicists, radiologists, technologists and department managers should review vendor or other CT protocols and “down-size” them for children.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

58. Radiologists, Physicists and Technologists’ Responsibilities
Single phase scans are often adequate
Pre- and post-contrast or delayed scans rarely add additional information in children, but can double or triple the dose.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

59. Radiologists, Physicists and Technologists’ Advice
Scan only the indicated area. If a patient has a possible small dermoid on ultrasound, there may not be a need to scan the entire abdomen and pelvis.
Be involved with your patients. Be the patient’s advocate. Ask the questions required to ensure that you “child-size” the scan.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

60.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

61.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

62. Summary CT can be a relatively high dose diagnostic imaging procedure
Rigorous justification of CT for children is required
Good practice in paediatric CT:
Optimisation of the CT examination protocol based on patient size (lower kVp and mA)
Acceptance of images with greater noise
One scan (single phase) is often enough - Reduce repeat scanning of identical body areas
Scan only the indicated area
Use of shielding devices
Trained and experiences staff
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

63. Answer True or False Reduction of kVp in CT reduces the dose.
CT contributes % of the dose from radiological examinations in developed countries.
3. The same CT protocol used for children and adults will result in a higher dose to adults.
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64. Answer True or False
Тrue - Reduced kVp reduce the dose in children while maintaining image quality.
Тrue - It is a high dose modality and with 10% contribution to number of all radiological examination it gives 60-70% of dose.
False- It is opposite, the same protocol will give a few time higher dose to children.
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

65. References
BRENNER, D.J., ELLISTON, C.D., HALL, E.J., BERDON, W.E., Estimated risks of radiation-induced fatal cancer from paediatric CT, Am. J. Roentgenol (2001)
BRENNER, D.J., Estimating cancer risks from paediatric CT: going from the qualitative to the quantitative, Pediatr. Radio.l 32 (2002) 228 – 231.
FRICKE, B.L., et.al., In-plane bismuth breast shields for pediatric CT: effects on radiation dose and image quality using experimental and clinical data, Am. J. Roentgenol. 180 (2003) 407 – 411.
HOPPER, K.D.,et al, The breast: in-plane x-ray protection during diagnostic thoracic CT - shielding with bismuth radioprotective garments, Radiology 205 (1997) 853 – 858.
KILJUNEN, T., JÄRVINEN, H., SAVOLAINEN, S., Diagnostic reference levels for thorax X-ray examinations of paediatric patients, Br. J. Radiol. 80 (2007)
BOONE, J.M., et. al., Dose reduction in paediatric CT: a rational approach, Radiology 228 (2003)
LUCAYA, J., et. al., Low-dose high-resolution CT of the chest in children and young adults: dose, cooperation, artefact incidence and image quality, Am. J. Roentgenol. 175 (2000)
INTERNATIONAL ATOMIC ENERGY AGENCY, Dose Reduction in CT while Maintaining Diagnostic Confidence: A Feasibility/Demonstration Study, IAEA-TECDOC-1621, IAEA, Vienna, (2009).
KALRA, M.K., et. al., Techniques and applications of automatic tube current modulation for CT, Radiology 233 (2004)
INTERNATIONAL COMMISSION ON RADIOLOGICAL PROTECTION, ICRP Publication 102: Managing Patient Dose in Multi-Detector Computed Tomography (MDCT), Annals of the ICRP Volume 37/1, Elsevier, (2007).
D. Tack,Pierre A Gevenois, Radiation Dose from Adult and Pediatric Multidetector Computed Tomography, Springer, 2007
Karla et al, In-plane shielding for CT: effect of off-centering, automatic exposure control and shield-to-surface distance, Korean J Radiol Mar-Apr;10(2):
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography

66. Additional material

67. Practical Optimisation in Paediatric CT (I)
Reduce mAs according to body weight/diameter or composition and/or
Use dose modulation (angular/longitudinal)
Use maximal slice reconstruction thickness to reduce noise and potentially dose appropriate for specific diagnosis.
Decrease kVp for thin (small) patients and high contrast exams (CT angiography, chest, musculoskeletal )
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68. Practical Optimisation in Paediatric CT (II)
Normally use shortest rotation time available.
Use representative volume sample when entire volume is not needed.
Use spiral scan with pitch greater than 1 (eg.: 1.5), provided this does not automatically increase the mA.
Use newer dose reduction strategies such as iterative reconstruction and adaptive modulation (to reduce over ranging)
Radiation Protection in Paediatric Radiology L06. Radiation protection in computed tomography 68

69. Practical Optimisation in Paediatric CT (III)
Be restrictive in defining upper-most and lower-most scan range
Use localising projection scan extending just minimally beyond scan limits.
Consider low kVp and single AP topogram
Reconstruct additional thick noise-reduced slices without increase in exposure.
Avoid major overlap when scanning adjacent areas with different protocols
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70. Practical Optimisation in Paediatric CT(IV)
Avoid additional non-enhanced scans unless specifically justified.
Optimise the protocol to obtain all the information requested during one scan.
Minimise the number of scans in multi-phase scanning.
In case of multi-phase scanning use shorter scan length for additional scans.
Use lower dose for non-enhanced or repeat scans unless high quality is needed.
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71. Practical Optimisation in Paediatric CT (V)
Minimise length of scans and fluoroscopy time in interventional applications.
Use low mA with CT fluoroscopy
Replace test bolus/bolus triggering by standard can delay unless timing is very critical.
Use additional protection devices where indicated such as bismuth shields (lens, thyroid, breast, gonads).
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72. Tube Current Modulation Options
Based on patient's size
Longitudinal (z-axis)
Angular (xy-axis)
Combined
Thin patient
Thick patient
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73. Tube Current Modulation Options
Part No...., Module No....Lesson No
Module title
Tube Current Modulation Options
200 mA
150 mA
130 mA
180 mA
210 mA
170 mA
Dose reduction based on patient anatomy.
Lower mA in AP, higher mA in lateral directions.
Methods
Patient attenuation measured during scout scan (AP & Lat) and alter mA for each gantry rotation (Smart mA1, Real AEC2) or “on-the-fly” (Care dose3)
1 GE, 2 Toshiba and 3 Siemens MDCT
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IAEA Post Graduate Educational Course in Radiation Protection in Pediatric Radiology

74. kV = dose Tube potential (kVp)
Part No...., Module No....Lesson No
Module title
Tube potential (kVp)
Decreasing kVp significantly reduces dose, typically:
80 kV – 0.5 mSv
100 kV – 1 mSv
120 kV – 1.6 mSv
140 kV – 2.3 mSv
kV = dose
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IAEA Post Graduate Educational Course in Radiation Protection in Pediatric Radiology

75. Tube potential (kVp)
CT examinations with a high intrinsic contrast (chest, bones) justify lowering the tube voltage to 80–100 kVp
However, bony examinations can
be performed with very
low current 25-70mA
Nievelstein, Pediatr Radiol, 2010
Cook, Imaging, 2001
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76. Guidelines
FDA Public Health Notification: Reducing Radiation Risk from Computed Tomography for Paediatric and Small Adult Patients, November 2nd, 2001
National Cancer Institute: Radiation Risks and Paediatric Computed Tomography (CT): A Guide for Health Care Providers,
Image Gently:
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77. Protocols for Children?
A Practice Quality
Improvement (PQI)
Program in CT Scans in
Children:
The PQI module capture how your practice performs CT scans in children, and allows you to compare your practice to “safe practice” guidelines in the literature.
How to Develop CT
Protocols for Children?
Provide guidance in developing CT protocols for children and periodically verifying that your current protocols are appropriate
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78. Example of successful story I
Arch and Frush, AJR 2008;191:611–617:
Since 2001, kVp and mA settings, two principal parameters determining radiation dose, have decreased significantly for paediatric body MDCT
It is a reasonable assumption that these changes are due to efforts to increase awareness about the risks of radiation
Paediatric chest CT
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79. Example of successful story II
Wallace, et al. Proceedings of IRPA 12, Buenos Aires, 2008, FP0227:
Eight paediatric hospitals
Training and seminars on optimisation
Dose reduction greater than 50%
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