Breast Imaging to Monitor the Response to Treatment
Transcript of Breast Imaging to Monitor the Response to Treatment
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Breast Imaging to Monitor the Response to Treatment
Nola Hylton, PhDUniversity of California, San Francisco
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OVERVIEWOVERVIEW
• Conventional imaging methods for evaluating response (mammography and ultrasound)
• Emerging role of MRI for monitoring treatment response
• Functional imaging methods as in-vivo biomarkers (DCE-MRI, PET)
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Conventional imaging:Conventional imaging:agreement with pathological residual agreement with pathological residual
disease sizedisease size
• No large prospective studies evaluating conventional imaging
• Small studies have shown variable results for agreement between imaging and pathology
• Retrospective analysis of conventional imaging and physical exam in MD Anderson neoadjuvant chemotherapy trials (Chagpar et al, Ann Surg, 2006)
– Included a comparison of published studies
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Conventional imaging for measuring treatment response
MD Anderson study
• 189 patients participating in 1 of 2 NACT trials
• Single direction tumor diameter measured by
physical exam (PE), ultrasound (US) and/or
mammography
• Residual disease size by imaging and physical exam
compared to residual pathologic tumor size Chagpar et al, Ann Surg, 2006
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Correlation of Tumor Measurements
*Spearman rank correlation coefficients.PE indicates physical examination; US, ultrasonography; M, mammography
0.41--M vs. pathology
0.42--US vs. pathology
0.42--PE vs. pathology
0.350.58US vs. M
0.260.40PE vs. M
0.280.45PE vs. US
Postneoadjuvant Chemotherapy
Preneoadjuvant Chemotherapy
Comparison
Correlation Between Measurements*
Only moderate correlation of imaging with pathologic residual disease, similar among imaging methods.Correlations between imaging measurements decreased from pre- to post-treatment. Chagpar et al, Ann Surg, 2006
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Agreement with pathology by size category(0, 0.1-1.0, 1.1-2.0, > 2.0 cm)
0.35Mammography
0.30Ultrasound
0.24Physical Exam
Weighted KappaClinical measurement
Poor agreement between clinical measurements and pathologic measurements
Chagpar et al, Ann Surg, 2006
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False negatives and false positives rates
20% (24/119)
10% (14/137)
57% (73/127)
False Negative Rate (%)
46% (16/35)Mammography
65% (26/40)Ultrasound
20% (5/40)Physical Exam
False Positive Rate (%)
Clinical measurement
Ultrasound had highest rate of false positives; physical exam had highest rate of false negatives.
Chagpar et al, Ann Surg, 2006
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Correlation with pathologic tumor size among other published studies
0.410.420.42189Chagpar et al (2006)
0.330.290.68141Fiorentino et al (2001)
0.550.560.5757Akashi-Tanaka et al (2001)
100
16
35
n
0.65
0.61
0.94
Mammography
0.60
0.85
0.96
Ultrasound
0.73Herrada et al (1997)
0.74Gawne-Caine et al (1995)
0.88Fourouhi et al (1994)
Physical Exam
Study
Correlation is highly variable among studies; close correspondence within studies.
Chagpar et al, Ann Surg, 2006
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Accuracy of conventional imaging for estimating residual disease:
• Imaging correlation with pathology only fair (r2 =
.41-.42)
• No strong evidence that mammography or US
perform significantly better than physical exam
for measuring estimating residual disease after
chemotherapy– Large prospective trials (NSABP B18, B27) have not incorporated
imaging for measuring response, but have relied on physical exam
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Breast MRIBreast MRI for assessing residual for assessing residual disease and response to treatmentdisease and response to treatment
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Breast MRIBreast MRI for staging extent of for staging extent of disease predisease pre--treatmenttreatment
• MRI prior to chemotherapy has shown greater
accuracy than mammography and ultrasound
for estimating disease extent, particularly when
multi-focal disease or DCIS is present
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Example: patient with a palpable mass; dense breast; Example: patient with a palpable mass; dense breast; mammography shows a mammography shows a spiculated spiculated mass and area of mass and area of suspicious calcificationssuspicious calcifications
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HypoHypo--echoic, echoic, spiculated spiculated mass on ultrasoundmass on ultrasound
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Multiple enhancingMultiple enhancing masses on MRImasses on MRI
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Extensive multiExtensive multi--focal and multifocal and multi--centric diseasecentric disease
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Breast MRIBreast MRI for staging residual for staging residual disease postdisease post--treatmenttreatment
• MRI following chemotherapy is less
effective, but still performs with greater
accuracy than conventional imaging or
clinical exam
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MRI versus conventional imagingfor estimating residual disease
*Comparison given by correlation coefficient.†Comparison by concurrence criteria.
35%26%19%71%31Yeh et al (2005)†
43%
0.71
0.48
--
--
US
38%52%63%51Balu-Maestro et al (2002)†
----0.8221Montemurro et al (2005)*
----0.8938Akazawa et al (2006)*
21
20
n
--
0.63
Mammo
0.61
0.72
Physical Exam
0.75Rosen et al (2003)*
0.93Weatherall et al (2001)*
MRIStudy
Consistent finding showing greater agreement of MRI with pathology compared to PE and conventional imaging.
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MRI false negatives postMRI false negatives post--treatmenttreatment
• MRI is effective for measuring the degree of tumor
response, but can miss residual disease, particularly
for good responders– Denis et al, EJSO 2004; Wasser et al, Eur Radiol 2003; Warren et al, Br J
Cancer, 2004, Yeh et al, AJR 2005
• Complete response on post-chemotherapy MRI
cannot be used to rule out surgery
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Disease extent after chemotherapy Disease extent after chemotherapy by MRIby MRI
Pre-chemo
Post-chemo
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Dynamic contrastDynamic contrast--enhanced (DCE) MRIenhanced (DCE) MRI
•• T1T1--weighted imaging performed with injection of gadoliniumweighted imaging performed with injection of gadolinium--based contrast agentbased contrast agent
•• Time course of contrast enhancement analyzed to estimateTime course of contrast enhancement analyzed to estimatepharmacokinetic parameters related to tumor permeability and pharmacokinetic parameters related to tumor permeability and blood volume (blood volume (kktranstrans, , vvee))
Signal Intensity versus 30-second temporal reso
0
50
100
150
200
250
300
350
0 100 200 300 400 500 600 700
Time (second
AIF
Tumor ROI
Tumor ROI
Normal
T=0 T=15’ T=30’
T=1’45” T=2’45” T=3’45”
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Pre-contrast S0 Late post-contrastEarly post-contrast
DCEDCE--MRIMRI combines anatomic staging combines anatomic staging with functional assessmentwith functional assessment
t
S
t1 t2t0
permeability
high
moderate
low
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MRI for Monitoring Response to Pre-operative Treatment
• MRI staging accuracy has led to increased interest in using MRI to assess response to treatment
⇒ Conventional imaging has not been fully explored in this role
• Functional information can be obtained as part of the clinical exam
⇒ No extra exams required
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Tracking tumorTracking tumor change during treatmentchange during treatment
MRI before chemotherapy
MRI after 1 cycle of chemotherapy
Assess tumor size:Assess tumor size:
Assess tumor Assess tumor vascularityvascularity::
MRI after full course of chemotherapy
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Pre-treatmentPre-treatment
Tumor response by MRITumor response by MRIPost-treatmentPost-treatment
Complete response(Volume change = 100%) Can greater
accuracy incapturing sizechange lead to better survival stratification?
Partial response(Volume change = 69%)
Progressive disease(Volume change = -178%)
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Measurements other than longest Measurements other than longest diameter may also be informativediameter may also be informative
•• Tumor volumeTumor volume
•• Tumor morphologyTumor morphology
•• Vascular heterogeneityVascular heterogeneity
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Volumetric Size Assessment
S1
SER
BASELINE (pre-chemo):Longest diameter = 1.9 cmVolume = 7.4 cc
Change after 1 cycle AC:Longest diameter = 2.0 cmVolume = 6.5 cc
Change after 4 cycles AC:Longest diameter = 1.4 cmVolume = 3.9 cc
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Tumor MorphologyTumor Morphology
1 2 3 4 5
54321
80
60
40
20
0
00.10.20.30.40.50.60.70.80.91
1 2 3 4 5Imaging Pa
P<0.01
Baseline Imaging Patterns (IP)1 - 5:
% complete responders by IP Breast conservation rates by IP
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Heterogeneity of the microvasculatureHeterogeneity of the microvasculature
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ACRIN 6657Prospective Imaging Trial as part of the IProspective Imaging Trial as part of the I--SPY CollaborationSPY Collaboration
• The “I-SPY” trial combines serial imaging and tissue-based molecular markers for assessing response to pre-operative treatment
• ACRIN 6657 is testing MRI for measuring response to treatment– Compare to clinical response and path residual disease as a predictor
of disease-free survival
– Size is primary measurement; functional information about tumor vascularity also being explored
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II--SPY Trial DesignSPY Trial Design
Diagnosis
ChemotherapyChemotherapy
SURGERYFollowFollow--upup
Tissue and MRI/MRS
•• Patients enroll on both CALGB 150007Patients enroll on both CALGB 150007 (tissue markers) (tissue markers) and ACRIN 6657 (imaging)and ACRIN 6657 (imaging)
•• Tissue acquisition and imaging performed at comparable Tissue acquisition and imaging performed at comparable times during treatmenttimes during treatment–– PrePre--treatment,treatment, post 1 cyclepost 1 cycle anthracyclineanthracycline, between , between anthracycline anthracycline
and and taxane taxane regimens, andregimens, and postpost--chemochemo
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Functional imaging methods as inFunctional imaging methods as in--vivo biomarkers (DCEvivo biomarkers (DCE--MRI, PET)MRI, PET)
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Functional MRI as an Functional MRI as an Imaging BiomarkerImaging Biomarker
• Functional measurements by MRI (DCE-MRI, diffusion-weighted MRI, MR spectroscopy) can beused to make quantitative measurements of tumor biology (microvascular
permeability, water diffusion, choline concentration)
Contrast Enhanced T1-
WeightedADC MapKtrans, ve
1H MRS Choline
[tCho]
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DCE-MRI in Phase I trials
• A number of recent Phase I clinical trials have added DCE-MRI to measure effects of anti-angiogenic agents (Wedam et al, JCO 2006; O’Donnell et al, Br J Cancer 2005; Morgan et al, JCO 2003; Liu et al, JCO 2005)
– Most found correlations of ktrans, ve with treatment response endpoints
– Some mixed results; several evaluated MRI in multiple metastatic solid tumors; correlative studies - not powered to answer imaging question
– suggest potential for DCI-MRI as a biomarker of anti-tumor treatment
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FDG PET to Monitor Response to Neo-Adjuvant Chemotherapy
4 months RxPre-Rx 2 months RxSUV = 3.3SUV = 4.1SUV = 5.7
breastlesion
axillarynode
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Summary of Mid-Therapy Response Evaluation by PET
mCR: -46% SUVnot mCR: - 8% SUV
EC or ET24Schelling,
2000mCR: -86% SUVnot mCR: -40% SUV
CVAP30Smith, 2000
mCR: -65% MRFDGPR: -49% MRFDGNR: -40% MRFDG
FAC or AC (weekly)
35Mankoff, 2003
All: -51% SUVFAC15Bassa, 1996
R: -48% SUVNR: -19% SUV
AC11Wahl, 1993
ResultsRxNReference
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In Summary• Conventional imaging has shown only fair accuracy for
assessing response– Has not proven of greater accuracy than physical exam
• MRI establishing itself as a superior anatomic staging method, compared to mammography and ultrasound, for extent of primary tumor– Better agreement with pathology for residual disease assessment
– Complete response by MRI cannot obviate surgery
• Functional imaging techniques (DCE-MRI, MRS, PET, Optical imaging) hold promise for in vivo assessment of tumor biology - but are still investigational