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RAD309. Patient Dose. CT. Patients are exposed to higher radiation levels from the use of computed tomography compared to most imaging techniques. Radiation Dose in CT. How much dose is scanner delivering? Inter-scanner comparison of dose Estimate patient potential risk
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RAD309 Patient Dose
CT • Patients are exposed to higher radiation levels from the use of computed tomography compared to most imaging techniques
Radiation Dose in CT • How much dose is scanner delivering? • Inter-scanner comparison of dose • Estimate patient potential risk • Weigh risk against benefit • Patient exposure tables/ a requirement by regulatory agencies (JCAHO)
CT Beam Geometry • Most modern CT • Emit fan shaped beam • Narrow cross section • Thin beam slice across patient
How do we measure dose? • Ionization chamber • Quantifies radiation exposure • Air filled container • Amount of collected charge is proportional to amount of radiation passing through it • Charge is removed and measured with electrometer • Total Q measured in coulombs • 1 C = 1.6 x 10^9 e
Multiple Scan Average Dose • Ave dose delivered to patient when a series of scans are performed • Graphical
Multiple Scan Average Dose • MSAD is dose from “many” slices
BED Index distance bed is moved between adjacent scans (mm) each scans the patient is moved a bed index distance
Computed Tomography Dose Index • (CTDI) special quantity expresses radiation dose in CT • Measured with a dosimeter inserted into a phantom that represents a patient • Dose is measured by scanning one slice • factors are applied to convert the measured phantom CTDI to an actual patient scan • a reasonable estimation of the actual dose to the patient
CTDI and MSAD • Slice dose versus procedure dose • CTDI: ionization chamber used for measurement • Area of dose cure for single slice dived by slice width • MSAD: use CTDI to calculate an ave dose in middle of series of scans • Ratio of slice width to slice spacing multiplied by CTDI
CTDI and MSAD Affect • To increase CTDI area under curve intensity ( raises height of curve) OR Widening the curve ( open collimator) CTDI Patient Dose CTDI is the MSAD at canter of a series of 14 contiguous slices
MSAD and BI • BI MSAD • Large gap b/w slices (slices further apart) • Radiation spread over a large area (ave. Dose) • BUT relevant tissue can be missed out • Limit to BI increase
BRH Recommendation • A measurement based on 2 concepts CTDI and MSAD (using pencil ion chamber) • Dose from CT is commonly specified in terms of CTDI • CTDI is derived from measurement dose from single slice
CT DOSIMETRY dosetools
CTDI/MSAD method • a pencil ionization chamber • 2 sized phantoms (16cm and 32cm) made of acrylic to standardize CT dose measurements • Both phantoms have holes drilled at specific locations to accommodate the ionization chamber during dose measurement • The chamber is positioned in 1 hole at a time while the other holes are filled with acrylic plugs • An exposure is made and recorded. This is done for all holes so that dose measurements can be obtained for a number of positions in the phantom • It is critical to note at this point that the ionization chamber is measuring the exposure and not dose • a factor is used to convert exposure to dose
Reduction of Dose • You ,the operator, must know dose • You, the operator, how to keep it at minimum • What can be done to reduce MSAD • How does this affect image
Factors Affecting Patient Dose • KVp • mAs • Pitch • Collimation • Bed Index • Beam Geometry • Detector Setup • Other: repeats, shielding, alignment, patient size...etc..
How does KV affects Dose Reducing x-ray tube voltage (kV) while keeping mAs constant, the patient dose is decreased Dropping KV from 120 to 80 kV at a constant current (mAs) typically reduces the patient dose by about 60%
Pitch and Dose Pitch = The distance the patient couch travels during one 360 degree turn As pitch increases, the time spent in any one point in space is decreased Pitch <1 = Higher Radiation Dose
Pitch is 0.75 Image shows 25% overlap
Shield thyroid, breast, eye lens, gonads • to reduce organ dose by 30—60%
Patient AlignmentPatient Alignment • Correctly centering patient on CT gantry can reduce radiation dose by as much as 56% • When the patient is in the incorrect position the patient must be moved and the CT scan repeated
Perspective • When a CT scan is justified by medical need, the associated risk is small relative to the diagnostic information obtained • CT scans save thousands of lives daily • CT scans greatly reduce exploratory surgeries
Justification : is the scan necessary for ongoing patient care? Can the examination be replaced by a low- or no-dose examination Equipment maintenance: Having to repeat a slice or an entire examination due to equipment failure increases dose with no benefit to the patient. QA program Limit the scan boundaries to area of interest. careful positioning of the scan volume, source to object distance, limiting the scan coverage to the area of interest, or angling the gantry away from sensitive structures can be very effective Decrease the exposure: The correct balance between dose and image quality .The guidelines also give reference values for patient dose for particular examinations. Customize the exposure to patient size: adjust the exposure factors to compensate for changes in patient size (mAs for children examinations)
Customize scan parameters to examination type : High resolution (fine detail) scans such as sinuses, inner ear and skeletal structures can be performed with lower exposure factors as spatial resolution is relatively independent of dose levels. for example, report dose levels as low as 20mAs Education and research: Radiographers review CT protocols at their institution and compare image quality and dose to the ICRP guidelines. education on dose reduction techniques in departmental CT training Programs Detector sensitivity: When purchasing CT scanners ask questions about scanner performance and radiation dose. Don't assume that all manufacturers scanners will have similar detector sensitivity and performance