PET in Sarcoma Imaging Treatment Response CTOS 2004 Montreal J.F. Eary, M.D. University of Washington
Defining Tumor Response Conventional Imaging Conventional Imaging Tumor shrinkage, disappearance Tumor shrinkage, disappearance Tumor qualitative change Tumor qualitative change Clinical Exam Clinical Exam
Defining Tumor Response Clinical Questions 1. How early can response be detected? 2. Which is the best treatment agent? 3. Is an image response a surrogate for effectiveness of therapy? 4. Can patient outcome be inferred? 5. Does image response predict for patient outcome?
Tumor Response 1. Slowed growth 2. Stasis 3. Necrosis - coagulative, liquefactive 4. Hemorrhage 5. Serious fluid accumulations 6. Granulation tissue formation 7. Scar formation 8. Loss of vascularity 9. Loss of malignant elements
Re-Defining Tumor Response Quantitative tumor biological parameters 1. Metabolism 2. Receptor quantity 3. Proliferation 4. Uptake of thymidine agents
PET Contributions to Tumor Response Assessment 1. Quantitative 2. High spatial resolution 3. Biologically relevant imaging agents
Using PET to answer important questions in oncology– What are the critical differences between normal, malignant, and treated tissue? How can this information be used to understand the biochemical processes by which therapy kills or fails to kill cells? From all of the available options, what will be the best treatment for an individual patient?
PET Measurement as a Surrogate Endpoint for Patient Outcome Tumor staging and grading, including heterogeneity Following response to treatment Identifying the cause of resistance in the individual patient Prediction / detection of normal tissue damage Assessing metastases / metastatic potential
Factors in Response and Resistance Surface Receptors Octreotide Proliferative Rate Thymidine & Analogs Glycolytic Rate FDG Hypoxia FMISO, EF1, ATSM Efflux Pumps MIBI, Verapamil, Colchicine Nuclear Receptors FES, FDHT
18 FDG is the most important PET procedure 2-fluoro-2-deoxy-D-glucose FDG reflects altered tissue metabolism More than just “grading” images.
High Grade Sarcoma: Near Complete Response to Chemotherapy
ESFT: Response assessed by PET Before chemotherapy After chemotherapy
High Grade Sarcoma: Tumor Progression during Chemotherapy
Survival Based on Initial SUV Time (months) Pre SUV<7 Pre SUV>7 Survival Probability
Survival Based on Post-Chemotherapy SUV
FDG PET in Chondrosarcoma
STS Survival Based on Change in Tumor SUV after Neoadjuvant Chemotherapy
STS Survival based on 40% change in SUV after Neoadjuvant ChemoRx
Can We Predict Response to Treatment? Quantitative FDG imaging Quantitative FDG imaging FMISO FMISO C-11 Thymidine C-11 Thymidine C-11 Verapamil C-11 Verapamil Quantitative FDG imaging Quantitative FDG imaging FMISO FMISO C-11 Thymidine C-11 Thymidine C-11 Verapamil C-11 Verapamil
High Grade Sarcoma: Heterogeneous Response to Chemotherapy
3-D Ellipsoidal Model for Homogeneous Tumors Utilization U(x) as a function of position (x) is given by U(x) = g[ (x-m)’A(x-m) ] m is the relative location A is a shape matrix g is a monotone level function
Multivariate Survival Analysis Variable (Standardized) %Change in Risk 95% C.I. P-value SUV (13,54) Heterogeneity(Elliptical) (11,68) Heterogeneity (Boundary- Elliptical) (-54,542)0.42 N=179 (71 deaths) Volume, RD, Boundary Morphology, Age: All not significant
Liposarcoma PET Studies FDG Blood Volume Thymidine
PET Imaging of Factors that Limit Response to Therapy Hypoxia Hypoxia Direct effects: resistance to rads, chemo Direct effects: resistance to rads, chemo Indirect: genetic instability Indirect: genetic instability VEGF, mutant p53 VEGF, mutant p53 Multi Drug Resistance Multi Drug Resistance via P-glycoprotein via P-glycoprotein high energy requirement high energy requirement
PET IMAGING HIGH GRADE LEIOMYOSARCOMA 18 F-FMISO SUV MAX =3.2SUV MAX =13.6 FDG FMISO : identify treatment resistant tumors FMISO : identify response/re-oxygenation FMISO : select patients for Tirpazamine therapy
PET and Pharmacokinetics: [ 11 C]-verapamil as a marker for the transport of anti-HIV drugs Hypothesis: Blocking P-gp will increase the delivery of anti-HIV nucleosides to the brain (Sagittal images of a macaque) No inhibitor After Cyclosporine (P-pg inhibitor) Brain Uptake
[18F]-FBA-annexin V Images Rats were injected with 0.5 mCi and imaged for 10 min beginning at 60 min after injection. Apoptosis of liver was induced by injection of cycloheximide (5 mg/kg, 4 hr). Normal Apoptosis
Molecular Imaging Answers Early indicators of the effectiveness of therapy will improve care-- Reduce ineffective medication use Reduce ineffective medication use Reduce unhelpful procedures Reduce unhelpful procedures Reduce cost Reduce cost Improve survival and quality of life Improve survival and quality of life
DNA Microarrays DNA Microarrays