Patient Dosimetry in CTindico.ictp.it/event/a12208/session/4/contribution/3/...IEC methods Other...

John M. Boone, Ph.D., FAAPM, FSBI, FACR

Professor and Vice Chair (Research) of Radiology Professor of Biomedical Engineering

University of California Davis Medical Center Sacramento, California

Patient Dosimetry in CT: what to measure and estimate;

why and how?

2013 ICTP/IAEA Training Course on Radiation Protection of Patients Trieste

Disclosures Paid Consultant to:

Varian Imaging Systems

Alston and Bird LLC

CardioInsight

DXray

Royalty Income from:

Lippincott Williams and Wilkins

Samsung Corporation

Research Funding from:

Stanford Research Institute

University of Pittsburgh

Siemens Medical Systems

Hologic Corporation

National Institutes of Health (NIBIB)

Trieste 15 Sept 2013

Why

What

How: conventional CT systems

How: cone beam CDT systems IEC methods

Other approaches

Measure versus Estimate

Summary

Patient Dosimetry in CT: what to measure and estimate; why and how?

5

80 x 80 matrix 8 grey scale (3 bit images)

EMI Mark 1: 1972

water bag for bolus 4 minute scan (120 sec/image) overnight reconstruction

Images courtesy ImPact Website (UK)

6

Modern helical multi-slice CT

8

axial coronal sagittal

high resolution three dimensional imaging

9

Allan M. Cormack

Godfrey N. Hounsfield

Nobel Prize for Medicine 1979

10

Helical CT

Multi-slice CT

technology advancements have led to greater CT use

531 mm

331 mm 200 mm

CT x-ray tube output

GE VCT 120 kV 32.3 mGy/100 mAs @ IC 600 mAs 1/6 rotation 432 mGy @ isocenter ISL = 2.57 1.1 Gy @ skin

~60°

Why

What



Other approaches


Summary


Firs

t B

rain

CT

Fir

st W

ho

le B

od

y C

T

Firs

t 4

rth

Gen

erat

ion

CD

T

Spir

al C

T

Du

al S

lice

CT

(aga

in)

mA

Mo

du

lati

on

Meg

a H

U x

-ray

tu

be

s

Fou

r Sl

ice

CT

8 t

o 4

0 s

lice

CT

64

slic

e C

T

Du

al S

ou

rce

CT

Flyi

ng

foca

l sp

ot

Ad

apti

ve D

ose

Co

llim

atio

n

Epila

tio

n c

ause

d b

y C

T

Evolution of CT Scanners and Dosimetry

CTDIFDA

CTDIW CTDIVOL

TG-204

TG-111 CTDI

TG-233

SB-1237

TG-200

TG-220

19

72

19

74

19

74

19

89

19

92

19

94

19

95

19

97

20

00

20

00

20

04

20

06

20

07

20

09

20

10

20

13

A brief history of the….

15

CTDI:

Computed Tomography Dose Index

16

The solid state CT detector

T

n=16

0.625 mm

nT = 16 × 0.625 mm = 10 mm

17

cone angle

fan angle

z-axis

Multiple Detector CT

Many detector arrays along z nT is the width of the x-ray beam at IC

nT

1( )CTDI D z dz

nT

do

se

position

Z=0 -Z +Z

1( )CTDI D z dz

nT

( )D z

CTDI

50

100

50

1( )

mm

mm

CTDI D z dznT

position

do

se

Z=0 -Z +Z

50

100

50

1( )

mm

mm

CTDI D z dznT

100 mm

position

do

se

Z=0 -Z +Z

50

100

50

1( )

mm

mm

CTDI D z dznT

100 mm

This equation requires table movement, either axial or helical CT scans which traverse 100 mm It is not valid for a stationary table scan such as with CT perfusion or CT fluoroscopy

50

100

50

1( )

mm

mm

CTDI D z dznT

100 mm

position

do

se

Z=0 -Z +Z

100 mm

CTDI - based Dose Metrics

32 cm diameter PMMA

16 cm diameter PMMA

100 mm pencil chamber

The Tools…….

Adult Body Phantom

Head Phantom

Peds Body Phantom


The Methods…….

CTDI100 peripheral

CTDI100 center

26 Measuring CTDI100 in the real world

The CTDI “Head” Phantom in position for CTDI100 measurement

The CTDI “Body” Phantom in position for CTDI100 measurement


The Mechanics…….

CTDI100 peripheral

CTDI100 center + ⅓ ×

⅔ ×

weighted CTDI, CTDIw

dose = 1 / pitch

Volume CTDI, CTDIvol = CTDIw / pitch

W Leitz, et al., CT dose assessment – a practical approach, Radiat Prot Dosim 1995; 57: 377


The CTDIw is the planar average dose to the central slice of the phantom in a series of slices spanning 100 mm

30

L

Which scan has more “dose”?

L

…to first order, the dose is the same

31

L

DLP = CTDIvol × L (mGy • cm)

Dose Length Product (DLP):

DLP is related to the total energy deposited in the patient

32

Effective Dose ≈ DLP × k

Effective Dose per DLP

(AAPM TG-96)

Region of Body

Head and neck

Head

Neck

Chest

Abdomen / pelvis

trunk

k (mSv/[mGy-cm])

0.0031

0.0021

0.0059

0.014

0.015

0.015

33

dose length product (mGy-cm)

The CT scanners now have a dose report that state the DLP. One can use these values with the conversion factors above to estimate the effective dose for the patient

Effective Dose per DLP

CTDI - based Dose Metrics Free-in-air measurement (no phantom)

CTDIfree-in-air or CTDIair


CTDI100 (center & peripheral)

The Tools

CTDIw

CTDIvol

DLP

The Metrics

The Methods

CTDIair

Why

What



Other approaches


Summary



average peripheral measurement

effect of table attenuation

50

100

50

1( )

mm

mm

CTDI D z dznT

mGy mm

c mGy × 100 mm = 100 c mGy.mm

For a chamber reading out in air kerma

100cK L

CTDIn T

kerma reading chamber length


100 mm

1507.3 mR

corrections

1. exposure to kerma correction 1507.3 mR / (114.5 mR/mGy) = 13.16 mGy

2. chamber reading air kerma 3. correction for nT

13.16 mGy x 100 mm = 1316 mGy.mm

1316 mGy.mm / 20 = 65.8 mGy (CTDI100)

nT = 20 mm (e.g.)

data are approximated beam

detected e =

detected

beam

penumbra

detector arrays


Dependency on collimated beam width (nT)


Dependency on collimated beam width (nT) (but MDCT has reduced use of this)

thin collimation thick collimation

impactscan.org (UK)

Sue Edyvean

Why

What


How: cone beam CDT systems (stationary table) IEC methods

Other approaches


Summary


Toshiba Aquillion 1: 320 x 0.5 mm = 160 mm

do

se

position

Z=0 -Z +Z

1( )CTDI D z dz

nT

50

100

50

1( )

mm

mm

CTDI D z dznT

100CTDI

CTDIe


100 mm

1507.3 mR

cone beam CT

nT > 100 mm

100CTDI

CTDIe

do

se

position

Z=0 -Z +Z

do

se

position

Z=0 -Z +Z

,( )

1

mc

free in air n T i

i

LCTDI D

n T

do

se

position

Z=0 -Z +Z

, ( 20 )c

free in air REF eg mm

K LCTDI

n T

50

,

100,

,50

1( )

( )

mm

free in air n T

REF

REF free in air REFmm

CTDICTDI D z dz

n T CTDI

Why

What



Other approaches


Summary


do

se

position

Z=0 -Z +Z

100 mm ion chamber

18 mm thimble chamber

CT perfusion (stationary table)

do

se

position

Z=0 -Z +Z

CTDIw

peak dose

Stationary table perfusion CT (j rotations)

dose = peak dose × j rotations

position

do

se

Z=0 -Z +Z

100 mm

Why

What



Other approaches


Summary



In general, it is best to say that doses are estimated, and not

calculated or measured. This conveys the proper notion that

CT dosimetry is an imprecise science, which it is.

Why

What



Other approaches


Summary


62

CTDI100mm

center periphery

CTDIw = 1/3 CTDIcenter + 2/3 CTDIperiphery

CTDIvol = CTDIw / pitch

DLP = CTDIvol x length irradiated

dose length product (mGy-cm)

measure CTDI100 [center]

measure CTDI100 [periphery]

The phantom is either a 16 cm diameter acrylic (head) or a 32 cm diameter (body) phantom

63

CTDI is a good measure of CT dose to a large plastic

phantom, but is not a stand-alone metric for patient dose

etcetera….

Med Phys 2003

Why

What



Other approaches


Summary


Patient Dosimetry in CTindico.ictp.it/event/a12208/session/4/contribution/3/...IEC methods Other...

Documents

Transcript of Patient Dosimetry in CTindico.ictp.it/event/a12208/session/4/contribution/3/...IEC methods Other...