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Molecularly Targeted Therapy in Lung Cancer: Hype, Hope, Myths and Reality

Molecularly Targeted Therapy in Lung Cancer: Hype, Hope, Myths and Reality. Martin J. Edelman, MD University of Maryland Greenebaum Cancer Center. Advanced NSCLC: The State of the Art. What is Targeted Therapy?.

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Molecularly Targeted Therapy in Lung Cancer: Hype, Hope, Myths and Reality

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  1. Molecularly Targeted Therapy in Lung Cancer: Hype, Hope, Myths and Reality Martin J. Edelman, MD University of Maryland Greenebaum Cancer Center

  2. Advanced NSCLC: The State of the Art

  3. What is Targeted Therapy? • If we use the analogy of pesticides: empiric therapy would be “Raid” while targeted therapy is the “Roach Hotel.” Dr. David Gandara • A “smart” bomb versus a “cluster” bomb. Dr. Nevin Murray

  4. Targeted Therapy: A definition • Drugs targeted at pathways, processes and physiology which are uniquely disrupted in cancer cells: • Receptors • Genes • Angiogenesis • Tumor pH • Get real, these pathways etc. are not so distinct.

  5. Self-sufficiency in growth signals Insensitivity to anti-growth signals Evading apoptosis Sustained angiogenesis Tissue invasion & metastasis Limitless replicative potential Six Essential Alterationsin Cell Physiology in Malignancy Hanahan & Weinberg, Cell 100:57 (2000) Targets for classical drugs? Targets for novel drugs?

  6. Myth #1: Targeted therapy is new (or what were we thinking?) • DNA is not a bad target. • Tubulin is a very good target. • Specific receptor targeting: tamoxifen etc. • Sometimes you design for one target and hit another: estramustine.

  7. 1,0 p=0.02 0,9 0,8 0,7 0,6 Cumulative survival 0,5 0,4 0,3 0,2 0,1 0,0 0 2 4 6 8 10 12 14 16 Months after diagnosis Dumontet, 2002 Survival by B-Tubulin III Phenotype In Taxane-treated NSCLC

  8. Better Identify and Utilize the Drugs We Already Have: GILT Standard Arm Docetaxel/Cisplatin RANDOMIZE Genomic Arm Beta tubulin ERCC1 Regimen - - Doc/CDDP - + Doc/Gem + - Gem/CDDP + + Gem/CPT-11

  9. New Anti-tubulins: Epothilones Computer model of beta-tubulin mutations Taxane Epothilone Giannakakou et al. Proc. Natl. Acad. Sci. USA 2000, 97, 2904

  10. Myth #2: Imatinib Mesylate is the “Proof of Principle” for these Drugs • Imatinib Mesylate targets the bcr-abl TK very specifically. • Bcr-abl is the root cause of CML, essentially a “monogenetic disease”

  11. 1.0 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 Myeloid (n=21) Lymphoid (n=14) 0 100 200 300 400 Imatinib Mesylate: The Exception that Proves the Rule… Time to Relapse in Patients with Myeloid or Lymphoid Blast Crisis Who Had a Response to STI571 Probability of Relapse • Orange arrows indicate patients still enrolled in the study and in remission at the • time of the last follow-up • White arrows indicate the day on which patients were removed from the study NEJM 344: 1038, 2001

  12. Targeted Therapy in the Common Solid Tumors: The Reality

  13. But what about Trastuzumab? • Degree of benefit is relatively modest. • Population is enriched by Herceptest. • Drug would have <10% RR if entire population treated

  14. Why the Difference? • Most solid tumors have complex genetics, not one or two hits but 20+. The more advanced the tumor, the greater the heterogeneity. • Molecular heterogeneity. • Hitting one narrow target is not likely to be that beneficial.

  15. Tumors Progressively Make More Angiogenesis Stimulators bFGF bFGF VEGF bFGF VEGF PDGF bFGF VEGF PDGFIL-8 Relf et al., Cancer Research, 57:953, 1997

  16. How to hit the target • If you know the target, and there is only one target you can be very specific. • If you don’t really know or it’s a really big target, a larger weapon may be needed.

  17. But all is not lost… • Return to the fundamental assumption. • Targeted therapy works when you can identify and validate the target. • Need to enrich the population for the target: Herceptin • May need to hit more than one target • Importance of trial design

  18. Leveraging your opponents weight, or how targeted therapy can work with other treatments and toss the opponent out of the ring

  19. Arachidonic Acid Metabolism Cell membrane phospholipids Sphingomyelin Neutral sphingomyelinase Arachidonic Acid Ceramide COX 1,2 5-HPETE 12-HPETE 15-HPETE Celecoxib 5LO Prostaglandins 12HETE 15HETE 5HETE Zileuton LTA4 LTB4 LTC4 LTD4 LTE4

  20. CALGB 300203:Gemcitabine/ Carboplatin + Eicosanoid Modulators PD Off study Carboplatin AUC =5.5 Gemcitabine 1000 mg/m2 Zileuton 600 mgpo qid Stage IIIB (pleural effusion), IV NSCLC PS 0-1 Adequate organ fcn SD, PR CR Eicosanoid modulator until progression Carboplatin AUC =5 Gemcitabine 1000 mg/m2 Celecoxib 400 mg po bid Carboplatin AUC =5.5 Gemcitabine 1000 mg/m2 Zileuton 600 mgpo qid Celecoxib 400 mg po bid Correlates: IHC, CYFRA VEGF levels MJ Edelman, PI

  21. Issues in Trial Design • How to screen drugs • Identify logical targets • Identify whether target acquired and neutralized. • Identify the population with the target. • Was the target important. • Beware collateral damage.

  22. The Phase I Trial • Traditionally, based upon the idea that good medicine tastes bad. • A little is good, more is better. • Clearly false • If you know the target, you can find the dose. • Demonstrate target inhibition • Downstream effects • Pharmacokinetic parameters

  23. Molecular Target Measurements • Enzyme activity measurements • e.g., DT-diaphorase, P450’s • Gene mutation status • e.g., Ras, p53 • Protein levels • e.g., Thymidylate synthase • mRNA levels • e.g., Microarray • Other • e.g., Phosphorylation status of a protein

  24. Clinical Trial Design WithBiologic Endpoints • Evaluate for target effect as active concentration is approached • Expand cohort when any biologic effect seen • reproducibility of effect • importance of well defined confidence interval • Escalate dose • until maximal expected effect is seen • until maximal effect occurs in maximal fraction of patients • Additional steps to confirm • effect is maximal • rate of effect is maximal

  25. Phase I of Targeted Agent: Use of Enzyme Inhibition to Determine Dose The Oncologist, 2002 7:401-409

  26. Phase I Trial of a Targeted Agent: Use of Target Inhibition to Determine Dose

  27. Trial Design: The Value of the Phase II Study • Early optimism led to the assumption that one could go directly from Phase I to III. • Unless a home run is assured, not a good idea. Decisions made in haste are repented at leisure • Phase II designs with “go and no go” endpoints. • New Phase II designs • Randomized Phase II • Enrichment designs • Discontinuation designs

  28. Powering the Phase II Trial • Response rate is a crude intermediate marker. The various Phase II approaches are adaptable to any endpoint. • Power for TTP, survival or a molecular marker. • But whatever you do, identify an endpoint.

  29. False Positive Trials • Patient self-selection • Physician selection: incentives for entry • Assessment of responses: the power of wishful thinking • And of course, inadvertent enrichment for the target

  30. Phase III Trials: The Problem of Molecular HeterogeneityImpact on Clinical Trials Outcome • Histologic diagnosis remains a key eligibility criterion. • Tumors with indistinguishable histology demonstrated quite different responses to therapy. • Do solid tumors possess different “destinies” based on their molecular profiles?

  31. Anaplastic Oligodendroglioma • Proportion of genetic subtypes differ in different cohorts of patients. • in recurrent disease: 90% 1p LOH • in newly dx’d disease: 60% 1p LOH • Genetic subtype is age dependent. • 1p LOH more common in young pts • older pts predominate in trials

  32. 1.0 0.8 0.6 Survival Probability 1p LOH 0.4 0.2 Neither 1p LOH nor TP53 0 0 50 100 150 200 Months Molecular Subtypes of Anaplastic Oligodendrogliomas: Implication for Patient Management at DiagnosisY. Ino et al. Clin Cancer Res 7:839,2001

  33. False Negative Trials • Overestimation of a therapeutic effect due to enrichment of phase II studies for a treatment sensitive subtype. • Dilution of a beneficial effect in responding patients by large numbers of nonresponding patients. • Reversal of a beneficial effect in responders by negative effect in nonresponders.

  34. a b Identify Specific Subsets • The promise of genomic and proteomic technology. • This enriches the population. • We already do this: • PML • CML • Breast cancer

  35. Pharmacogenomics

  36. Targeted Therapy: The Future • Modern biology has identified a host of new potential targets for cancer therapy • Drugs interacting with these targets are available. • The benefit of these agents is dependant upon the criticality of the target. More than one target may need to be inhibited. • New agents may “tip the balance” when combined with chemotherapy, radiation.

  37. Targeted Therapy: The Future (cont’d) • The design and careful assessment of new agents in Phase I and II trials will result in better understanding of the potential population and magnitude of benefit for any particular agent. • Phase II trials should guide the decision for Phase III. • Phase III trials with a good chance of success can then be accomplished.

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