DIGITAL vs. FILM-SCREEN MAMMOGRAPHY
by EDWARD L. NICKOLOFF, D.Sc. DEPARTMENT OF RADIOLOGY COLUMBIA UNIVERSITY NEW YORK, N.Y. 10032
�GOALS
• COMPARE THE VARIOUS DIGITAL SYSTEMS TO FILM-SCREEN SYSTEMS • DETERMINE SOME KEY DIFFERENCES BETWEEN THE SYSTEMS: IMAGE QUALITY, RADIATION DOSES, OPERATIONAL FEATURES & PHYSICS TESTING ISSUES • IDENTIFY ADVANTAGES & DIS-ADVANTAGES OF EACH MAMMOGRAPHY SYSTEM
�THE EQUIPMENT
GE 2000-D DIGITAL
GE DMR FILMSCREEN
�THE EQUIPMENT
LORAD CCD DIGITAL -SELENIA SIMILAR
LORAD M IV PLATINUM FILM-SCREEN
�Fischer Imaging SenoScan FFDM System
�DIGITAL MAMMOGRAPHY DETECTORS
�GE 2000-D IGITAL MAMMOGRAPHY UNIT
Contact Leads For Read-Out Electronics Contact Fingers Amorphous Silicon Array
Scintillator (CsI)
Glass Substrate
FROM GE
�LORAD CCD DIGITAL MAMMOGRAPHY UNIT
CARBON FIBER RECEPTOR SURFACE CsI
SCINTILLATOR
40 m LIGHT PIPE LIGHT PIPE LIGHT PIPE
10 m CCD CCD
CIRCUIT BOARD
�AMORPHOUS SELENIUM DETECTORS
�AMORPHOUS SELENIUM DETECTOR
READOUT
VOLTAGE
-- --
IONIZATION
�DETECTOR ASSEMBLY MOVES IN AN ARC
Cesium Iodide
CsI SCINTILLATOR
Fiber Optic Plate 4 CCD’s
Fischer Imaging Corporation
�WORK LOAD EFFICIENCY COMPARISON
�Digital Mammography - Productivity
Conventional Exam With Film
1:30 Patient in Room First Exposure 4:45 Last Exposure 2:15 First Film Out of Processor 8% Repeat Rate :05 Last Film Out of Processor :10 QC :30 Release Patient
12:10 min
Exam Using Digital Detector
1:30 Patient in Room First Exposure & QC 1:45 Last Exposure & QC :45 Release Patient / Send Study To WS
4:00 min
Minimal Repeats
Estimated > 60% Reduction In Exam Times From GE
�MY EFFICIENCY ESTIMATE
• FILM-SCREEN SYSTEMS
– TALK WITH PATIENT & POSITION FOR 4 FILMS = 6 MINUTES – MARK CASSETTES WITH I.D. & BAR CODE STUDY = 1 MINUTES – WALK TO PROCESSOR WITH CASSETTES = 2 MINUTES – INSERT CASSETTES IN DAYLIGHT LOADER COUPLED TO PROCESSOR & WAIT FOR PROCESSED FILMS = 7 MINUTES – QC FILM & PLACE IN JACKET = 1 MINUTES – TALK TO PATIENT, RADIOLOGIST AND WAIT TO DRESS & LEAVE = 2 – 4 MINUTES
• TOTAL = 20 MINUTES
�MY EFFICIENY ESTIMATE
• DIGITAL MAMMOGRAPHY
– TALK WITH PATIENT & POSITION FOR 4 IMAGES = 6 MINUTES – KEY IN COMPUTER INFORMATION & I.D. & BAR CODE STUDY = 2 MINUTES – REVIEW IMAGES AND TRANSMIT TO RADIOLOGIST REVIEW STATION = 2 MINUTES – TALK TO PATIENT, RADIOLOGIST AND WAIT TO DRESS & LEAVE = 2 - 4 MINUTES
• TOTAL = 13 MINUTES
�COMMENTS ON RELATIVE EFFICIENCY
• ONE DIGITAL MAMMO CAN EASILY REPLACE TWO FILM-SCREEN MAMMO UNITS • ROUTINE RT QC IS BETTER … IN COMPUTER • FEW DRIFTS WITH DIGITAL UNIT • FEWER REPEATS WITH DIGITAL UNIT
�RADIATION DOSES FOR MAMMOGRAPHY UNITS
�COMPARISON OF RADIATION DOSES (GE DMR FILM-SCREEN vs. GE 2000-D DIGITAL)
400
AVERAGE GLANDUALAR DOSE (mRADS)
350 300 250 200 150 100 50 0 2 3 4 5 6 THICKNESS OF BR-12 (cm)
DIGITAL AOP STANDARD FILM AoP STANDARD
7
DIGITAL AoP CONTRAST FILM AoP CONTRAST
DIGITAL AoP DOSE FILM AoP DOSE
�COMPARISON OF RADIATION DOSES (LORAD FILM-SCREEN WITH DIGITAL)
600
AVERAGE GLANDUALAR DOSE (mRADS)
500 400 300 200 100 0 2 3 4 5 6 THICKNESS OF BR-12 (cm) 7 8
CCD DIGITAL AT 28 kVp FILM AUTO-FILTER 200 mAs LIMIT FILM AUTO-TIME
CCD DIGITAL WITH kVp ADJUST FILM AUTO-kVp AUTO-mAs LORAD SELENIA DIGITAL
�SUMMARY OF MAMMO DOSES
• IN GENERAL, THE RADIATION DOSE FOR FILM-SCREEN & DIGITAL MODES WERE SIMILAR • HOWEVER, DIGITAL DETECTORS ARE VERY EFFICIENT EVEN WITH HIGH ENERGY XRAYS... SO HIGHER KVP’s AND FILTRATION WERE USED.... RESULTING IN SLIGHTLY LOWER RAD DOSES • FILM CONTRAST MODES DELIVERED MORE RAD DOSE BECAUSE IT USED LOWER KVP’S
�SUMMARY OF RADIATION DOSES
• BEWARE, UNLIKE FILM-SCREEN, DIGITAL DETECTORS CAN OPERATE OVER A WIDE RANGE OF RAD DOSES & NOISE IMPROVES AT HIGHER DOSES • DIGITAL IMAGES WITH HIGHER RADIATION DOSES LOOK BETTER • PHYSICISTS MUST GUARD AGAINST ABUSE !!
��GOALS OF AUTO AEC SYSTEMS
• UTILIZE EXPOSURE TIMES <2.5 SEC • UTILIZE Dg < 300 mrads FOR < 4.2 cm COMPRESSED BREAST THICKNESS • INCREASE Dg < 150 mrads @ +1 cm • USE HIGHER kVp’S FOR THICKER / DENSE BREASTS • MAINTAIN “ESE” < 10,000 mR • IF AVAILABLE, USE Rh ANODE AND/OR FILTER FOR THICKER / DENSE BREASTS
�AUTOMATED AEC SYSTEMS
• USE DYNAMIC MEASUREMENTS DURING AN EXPOSURE TO SET PARAMETERS
– ANODE – FILTER – kVp – mAs
• INVOLVES LOOK-UP TABLES (LUT) BASED UPON PATIENT BREAST
�TECHNIQUES BASED UPON AVERAGE GLANDULAR DOSE MEASUREMENTS IN BR-12
CO M PR ES SED BR E AS T THIC K NES S (C M ) X -R AY TU B E P O TEN TIAL (kV p)
< 3 3 - 4 4 - 5 5 - 6 6 - 7 7 - 8
25 26 27 28 29 31
-
26 27 28 29 30 32
�COMPARISON OF kVp & ANODE / FILTER FOR FILM-SCREEN vs. DIGITAL GE MAMMO IN AoP CONTRAST MODE
35
kVp UTILIZED
30
25
20 0 1 2 3 4 5 6 7 8 THICKNESS OF BR-12 (cm)
FILM Mo/Mo DIGITAL Mo/Mo FILM Mo/Rh DIGITAL Mo/Rh FILM Rh/Rh DIGITAL Rh/Rh
�COMPARISON OF RADIATION DOSES (GE DMR FILM-SCREEN vs. GE 2000-D DIGITAL )
500 450
AVERAGE GRANDULAR DOSE (mRADS)
400 350 300 250 200 150 100 50 0
2 3 4 5 6 THICKNESS OF BR-12 (cm)
DIGITAL AoP CONTRAST FILM AoP CONTRAST
7
8
�COMPARISON OF kVp & ANODE / FILTER FOR FILM vs. DIGITAL GE IN AoP STANDARD
34 32
kVp UTILIZED
30 28 26 24 22 20 0 1 2 3 4 5 THICKNESS BR-12 (cm)
FILM Mo/Rh DIGITAL Mo/Rh
6
7
8
FILM Mo/Mo DIGITAL Mo/Mo
FILM Rh/Rh DIGITAL Rh/Rh
�COMPARISON OF RADIATION DOSE (GE DMR FILM-SCREEN vs. GE 2000-D DIGITAL)
450
AVERAGE GLANDULAR DOSE (mrads)
400 350 300 250 200 150 100 50 0 2 3 4 5 6 PHANTOM THICKNESS (cm) 7 8
DIGITAL AOP STANDARD
FILM AoP STANDARD
�AutoCell:
Breast w/Photo Cells
DDD
Digital vs FilmScreen
�SUMMARY OF AEC SYSTEMS
• DIGITAL SYSTEMS USE HIGHER kVp’S THAN FILM-SCREEN SYSTEMS • DIGITAL SYSTEMS USE ANODE / FILTERS WHICH PROVIDE HIGHER ENERGY XRAYS • DIGITAL SYSTEM ARE MORE FLEXIBLE WITH AEC SENSOR AREA • DIGITAL SYSTEM ARE EXPECTED TO BE SLIGHTLY LESS DOSE • DIGTIAL SYSTEMS CAN BE ADJUSTED FOR A RANGE OF DOSES
�HIGH CONTRAST SPATIAL RESOLUTION
�WHAT AFFECTS HIGH CONTRAST SPATIAL RESOLUTION?
•
X-RAY TUBE FOCAL SPOT SIZE – DIMENSION – GEOMETRY … MAGNIFICATION, SID – L = M / [ (M -1) x f ] – INTENSITY DISTRIBUTION • IMAGE RECEPTOR INHERENT LIMITS – FILM-SCREEN – DIGITAL SYSTEM
�CONTACT FILM-SCREEN MAMMOGRAPHY SPATIAL RESOLUTION AS A FUNCTION OF BREAST THICKNESS & FOCAL SPOT SIZE
25
OVERALL SPATIAL RESOLUTION (LP/mm)
20 15 10 5 0 0 1 2 3 4 5 6 7 8 9 10 BREAST THICKNESS (CM)
F=0.3 mmf=0.6mm f=0.6 mm f=1.2 mm
�1.5x MAG FILM-SCREEN MAMMOGRAPHY SPATIAL RESOLUTION AS A FUNCTION OF BREAST THICKNESS & FOCAL SPOT SIZE
18 16 14 12 10 8 6 4 2 0 0 1 2 3 4 5 6 7 8 9 10 BREAST THICKNESS (CM)
F=0.1 mm f=0.3 mm f=0.6 mm
OVERALL SPATIAL RESOLUTION (LP/mm)
�6
CONTACT DIGITAL MAMMOGRAPHY SPATIAL RESOLUTION AS A FUNCTION OF BREAST THICKNESS & FOCAL SPOT SIZE
OVERALL SPATIAL RESOLUTION (LP/mm)
5 4 3 2 1 0 0 1 2
F=0.3 mm
3 4 5 6 7 BREAST THICKNESS (cm)
f=0.6 mm
8
9
10
f=1.2 mm
�1.5x MAG DIGITAL MAMMOGRAPHY SPATIAL RESOLUTION AS A FUNCTION OF BREAST THICKNESS & FOCAL SPOT SIZE
9 8 7 6 5 4 3 2 1 0
OVERALL SPATIAL RESOLUTION (LP/mm)
0
1
2
F=0.1
3 4 5 6 7 8 BREAST THICKNESS (cm)
F=0.3
9
F=0.6
10
�PIN-HOLE CAMERA OF X-RAY FOCAL SPOT
���HIGH CONTRAST SPATIAL RESOLUTION (GE DMR FILM-SCREEN vs GE 2000-D DIGITAL)
18
SPATIAL RESOLUTION (LP/mm)
16 14 12 10 8 6 4 2 0 0 1 2 3 4 5 6 7 8 9 PHANTOM THICKNESS (cm)
DIGITAL MEASURED THEORY FILM-SCREEN FILM MEASURED THEORY DIGITAL
�HIGH CONTRAST SPATIAL RESOLUTION (LORAD MIV PLATINUM FILM-SCREEN vs LORAD CCD & SELENIA DIGITAL)
18
SPATIAL RESOLUTION (LP/mm)
16 14 12 10 8 6 4 2 0 0 1 2 3 4 5 6 7 8 PHANTOM THICKNESS (cm)
CCD DIGITAL MEASURED THEORY FILM-SCREEN SELENIA DIGITAL MEASURED FILM MEASURED THEORY CCD DIGITAL THEORY SELENIA DIGITAL
�SUMMARY OF HIGH CONTRAST SPATIAL RESOLUTION
• DIGITAL MAMMOGRAPHY UNITS HAVE LOWER SPATIAL RESOLUTION THAN THE FILM SCREEN UNITS ( 5 – 8 LP/mm) • MEASURED DIGITAL RESOLUTION WAS 30% TO 60% OF FILM-SCREEN RESOLUTION (15 – 20 LP/mm) • SPATIAL RESOLUTION DOES NOT TELL THE WHOLE STORY!
�Flat Panel-Light Sensor
scan line FET
Very High Fill Factor
Fill Factor= Sensitive Area
Pitch x Pitch
data line
Pitch
FROM GE
Pitch
�IMAGE RECEPTOR DEPENDENCE
• FILM-SCREEN SYSTEMS – DESIGN OF SCREEN (THICKNESS, DYES, REFLECTIVE LAYER, PHOSPHOR CRYSTALS) – TYPICALLY….. 15 TO 25 LP/mm • DIGITAL SYSTEMS – PITCH ( 25m To 100m ) – L = 1 / (2 x PITCH) – TYPICALLY …… 5 TO 10 LP/mm
�LOW CONTRAST DETECTABILITY
�LOW CONTRAST DETECTABILITY
�RMI 180 C-D PHANTOM
• NINE HOLE DEPTHS RANGE FROM 0.062 mm TO 1.0 mm • SUBJECT CONTRAST = EXP (-m T) • TEN HOLE DIAMETERS RANGE FROM 0.312 mm TO 7.07 mm
�COMPARISON OF LOW CONTRAST DETECTION OF FILM-SCREEN vs. DIGITAL MAMMO SYSTEMS ---- GE 100
% 0F LOW CONTRAST TARGET VISUALIZED (%)
90 80 70 60 50 40 30 20 10 0 0 2 4 6 8 ACRYLIC THICKNESS OF PHANTOM (cm)
GE 2000-D DIGITAL Linear (GE 2000-D DIGITAL) GE DMR+FILM Linear (GE DMR+FILM)
10
�COMPARISON OF LOW CONTRAST DETECTION OF FILM-SCREEN vs. DIGITAL MAMMO SYSTEMS --- LORAD 100
% OF LOW CONTRAST TARGET VISUALIZED (%)
90 80 70 60 50 40 30 20 10 0 0 2 4 6 8 ACRYLIC THICKNESSOF PHANTOM (cm)
LORAD CCD DIGITAL Linear (LORAD CCD DIGITAL) Linear (LORAD SELENIA DIGITAL)
10
LORAD MIV + FILM LORAD SELENIA DIGITAL Linear (LORAD MIV + FILM)
�DIGITAL SYSTEM SIGNAL-TO-NOISE RATIO (SNR)
�DIGITAL MAMMOGRAPHY SYSTEMS SNR vs. RADIATION EXPOSURE 1000
SIGNAL-TO-NOISE RATIO (SNR)
y = 12.216x 100
0.5374
y = 9.759x 10
0.5552
1 0.1 1
LORAD DIGITAL Power (LORAD DIGITAL)
10
100
GE 2000-D DIGITAL Power (GE 2000-D DIGITAL)
1000
ENTRANCE RADIATION EXPOSURE (mR)
�OTHER CONSIDERATIONS
�DYNAMIC RANGE CONSIDERATIONS
�FILM-SCREEN CHARACTERISTIC CURVE -GE DMR WITH KODAK MIN-R 2000
4 3.5 3 2.5 2 1.5 1 0.5 0 0 0.5 1 1.5 2 2.5 LOG [EXPOSURE (mR)]
USEFUL RANGE = 78.9 mR / 8.9 mR = 8.7 28 kVp, 3 cm ACRYLIC, INTO BUCKY KODAK 270 RA PROCESSOR WITH KODAK CHEMISTRY FILM DYNAMIC RANGE
FILM DENSITY [O.D.]
�FILM-SCREEN CONTRAST GRADIENT -GE DMR WITH KODAK MIN-R 2000 FILM
4.5 4
FILM CONTRAST GRADIENT
3.5 3 2.5 2 1.5 1 0.5 0 0 0.5 1 1.5 2 2.5 3 3.5 4 FILM OPTICAL DENSITY (O.D.) FILM-SCREEN DYNAMIC
�DYNAMIC RANGE OF DIGITAL MAMMOGRAPHY -- GE 2000-D DIGITAL 10000
RELATIVE DIGITAL SIGNAL
DIGITAL DYNAMIC RANGE
1000
100
USEFUL RANGE = > 260 mR / 0.1 mR = > 2600
10
1
0.1
1
10
100
1000
ENTRANCE EXPOSURE ( mR)]
�LORAD 2000 DIGITAL MAMMOGRAPHY: SIGNAL vs RADIATION EXPOSURE
100000
DIGITAL DYNAMIC RANGE
SIGNAL (relative units)
10000
1000
100
USEFUL RANGE = 130 mR / 0.1 mR = 1300
10
1 0.1 1 10 100 1000 10000 ENTRANCE EXPOSURE (mR)
�TISSUE EQUALIZATIONS
�Thickness Compensation
GOAL: EQUALIZATION OF DENSITIES TO SKIN LINE. Algorithm: 1. Estimate the thickness of the breast at all pixels 2. Add a nearly-equivalent thickness [of water] to raise gray level.
Line-Profile through Breast
Original
TC-Processed
Compensation Thickness Breast Thickness
{
{
FROM GE
�Breast 3 RMLO no TE
FROM GE
�Breast 3 - RMLO TISSUE EQUILIZATION
�COMPUTERS IN MAMMOGRAPHY
• • • • • • Computer Aided Diagnosis (CAD) Data Compression PACS Image Enhancement Dual Energy Subtraction Tomosynthesis
�COMPUTER AIDED DIAGNOSIS
FROM : L CLARKE et al., Acad. Radiol. 1997
�GE C ompany Proprietary - Not for External Distribution
October 6, 1998
COMPUTER-AIDED DETECTION
Applications • Automated detection • Automated classification
TM Current ImageCheckerTM Performance • Flagged 85% of overlooked cancers • Flagged 83% of diagnosed cancers
Increase the sensitivity for cancer detection when combined with the radiologist
From GE
�DISPLAY MONITORS
�VDT verses VIEWBOX
• BRIGHTNESS
– VDT = 200 TO 400 LUX – VIEWBOX = 3000 - 4000 LUX
• VDT HAS WINDOWS & LEVELS FOR VARIABLE CONTRAST / BRIGHTNESS • COLOR TINT DIFFERENCES • CALIBRATION REQUIREMENTS & DRIFT
�MONITOR CHARACTERISTICS
THE SMPTE TEST PATTERN WITH 13 SHADES OF GRAYSCALE PATCHES WAS UTILIZED TO MEASURE THE GRAYSCALE “LUT “.
�SMPTE TEST PATTERN
VISIBILITY OF BARS EACH SHADE OF GRAY BLOCK DIFFERENT
LINES STRAIGHT
0% / 5% CONTRAST BLOCK VISIBLE
100% / 95% CONTRAST BLOCK VISIBLE
�IMAGE MANIPULATION
�LMLO - Full Zoom, no Invert
FROM GE
�LMLO - Full Zoom, Invert
FROM GE
�UNSHARP MASK ENHANCEMENT
DENSITY DENSITY
ORIGINAL
SMOOTH
DISTANCE
DISTANCE
DENSITY
ORIGINAL - SMOOTH
DENSITY
ORIGINAL + 4 DIFFERENCE
DISTANCE
DISTANCE
�Tomosynthesis
Series of low-dose images used to reconstruct tomography images at any level
FROM GE
�ADVANTAGES OF DIGITAL TECHNOLOGY
• LARGE DYNAMIC RANGE -- NOT TOO DARK OR TOO LIGHT • WINDOW & LEVEL CAPABILITY • IMAGE PROCESSING • FAST RETREIVAL & LAYOUT • LOWER REPEAT RATES • LESS PATIENT RADIATION DOSE • COMPUTER AIDED DIAGNOSIS (CAD) • TELERADIOLOGY CAPABILITY
�ADVANTAGES OF DIGITAL TECHNOLOGY
• BETTER SENSITIVITY & EARLY DETECTION • COMBINE WITH RIS/HIS DISPLAY • COMPACT IMAGE STORAGE • BETTER PATIENT TRACKING & BILLING • SERVICES TO REMOTE LOCATIONS • LATITUDE & CONTRAST
�DIS-ADVANTAGES OF DIGITAL TECHNOLOGY
• • • • • HIGH INITIAL COSTS HIGHER MAINTENANCE COSTS TECHNOLOGY OBSOLENCE ISSUES HIGH QUALITY SUPPORT PERSONNEL NEED FOR NETWORK & NETWORK SUPPORT • LOWER SPATIAL RESOLUTION • NETWORK TRANSFER SPEED LIMITS • MORE COMPLEX VIEWING PROCESS
�DIS-ADVANTAGES OF DIGITAL TECHNOLOGY
• ENTERING INCORRECT ID# CAN MISPLACE STUDIES & BILLING • PACS/NEMA COMPATABLE HARDWARE MAY NOT BE INSTALLED • INTRA-VENDOR COMPATABILITY • POWER / COMPONENT FAILURES • LONG-TERM DATA RETRIEVAL DELAYS • LACK OF INSTANT FLUORO REVIEW
�CONCLUSIONS
• DIGITAL IS MORE TIME EFFICIENT • RAD DOSE CAN BE SIMILAR • FILM-SCREEN HAS BETTER HIGH CONTRAST RESOLUTION & DIGITAL BETTER LOW CONTRAST SENSITIVITY • DIGITAL MAMMO SYSTEMS ARE MORE ROBUST:
– WIDER DYNAMIC RANGE – WINDOW / LEVEL ADJUSTMENT – COMPUTER IMAGE ENHANCEMENT
�ARRET
�