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Introduction to Design of Genomic Clinical Trials Richard Simon, D.Sc. Chief, Biometric Research Branch National Cancer Institute

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Presentation on theme: "Introduction to Design of Genomic Clinical Trials Richard Simon, D.Sc. Chief, Biometric Research Branch National Cancer Institute"— Presentation transcript:

1 Introduction to Design of Genomic Clinical Trials Richard Simon, D.Sc. Chief, Biometric Research Branch National Cancer Institute http://brb.nci.nih.gov

2 Biometric Research Branch Website brb.nci.nih.gov Powerpoint presentations Powerpoint presentations Reprints & Technical Reports Reprints & Technical Reports BRB-ArrayTools software BRB-ArrayTools software Web based Sample Size Planning Web based Sample Size Planning

3 Outline Introduction Introduction Biomarkers Biomarkers Validation Validation Targeted enrichment design Targeted enrichment design Stratification designs Stratification designs Prospective-Retrospective Designs Prospective-Retrospective Designs Prognostic biomarkers Prognostic biomarkers Clinical Trial Designs with adaptive identification of indication for treatment Clinical Trial Designs with adaptive identification of indication for treatment Development and Validation of Classifiers with High Dimensional Data Development and Validation of Classifiers with High Dimensional Data

4 Different Kinds of Biomarkers Endpoint biomarker Endpoint biomarker A measurement made on a patient before, during and after treatment to determine whether the treatment is working A measurement made on a patient before, during and after treatment to determine whether the treatment is working Surrogate endpoint Surrogate endpoint Pharmacodynamic Pharmacodynamic Intermediate endpoint Intermediate endpoint Prognostic biomarkers Prognostic biomarkers Measured before treatment to indicate long-term outcome for patients untreated or receiving standard treatment Measured before treatment to indicate long-term outcome for patients untreated or receiving standard treatment Single arm study of patients receiving a particular rx can identify patients with good prognosis on that rx Single arm study of patients receiving a particular rx can identify patients with good prognosis on that rx Those patients may not benefit from that rx but they don’t need additional rx Those patients may not benefit from that rx but they don’t need additional rx Predictive biomarkers Predictive biomarkers Measured before treatment to identify who will benefit from a particular treatment Measured before treatment to identify who will benefit from a particular treatment Single arm study with response endpoint Single arm study with response endpoint RCT with survival or dfs endpoint RCT with survival or dfs endpoint

5 Cardiac Arrhythmia Supression Trial Ventricular premature beats was proposed as a surrogate for survival Ventricular premature beats was proposed as a surrogate for survival Antiarrythmic drugs supressed ventricular premature beats but killed patients at approximately 2.5 times that of placebo Antiarrythmic drugs supressed ventricular premature beats but killed patients at approximately 2.5 times that of placebo

6 Surrogate Endpoints It is extremely difficult to properly validate a biomarker as a surrogate for clinical outcome. It is extremely difficult to properly validate a biomarker as a surrogate for clinical outcome. It is not sufficient to demonstrate that the surrogate is correlated with clinical outcome It is not sufficient to demonstrate that the surrogate is correlated with clinical outcome That responders live longer than non-responders does not establish response as a valid surrogate endpoint That responders live longer than non-responders does not establish response as a valid surrogate endpoint Proper validation requires a series of randomized trials with both the candidate biomarker and clinical outcome measured Proper validation requires a series of randomized trials with both the candidate biomarker and clinical outcome measured Demonstrate that differences between randomized treatment arm with regard to the candidate surrogate are consistent with differences with regard to clinical outcome Demonstrate that differences between randomized treatment arm with regard to the candidate surrogate are consistent with differences with regard to clinical outcome

7 It is often more difficult and time consuming to properly “validate” an endpoint as a surrogate than to use the clinical endpoint in phase III trials It is often more difficult and time consuming to properly “validate” an endpoint as a surrogate than to use the clinical endpoint in phase III trials

8 Using Intermediate Endpoints Not Established as Surrogates of Clinical Benefit Biomarkers can be useful in phase I/II studies as measures of treatment effect Biomarkers can be useful in phase I/II studies as measures of treatment effect they need not be validated as surrogates for clinical benefit they need not be validated as surrogates for clinical benefit Unvalidated surrogates can also be used for interim “futility analyses” of phase III trials (e.g. seamless phase II/III). The trial should continue accrual and follow-up to evaluate true endpoint if treatment effect on biomarker is sufficient Unvalidated surrogates can also be used for interim “futility analyses” of phase III trials (e.g. seamless phase II/III). The trial should continue accrual and follow-up to evaluate true endpoint if treatment effect on biomarker is sufficient Conditional surrogate endpoints Conditional surrogate endpoints Can be used for developing predictive biomarkers in phase II studies or in adaptive signature designs Can be used for developing predictive biomarkers in phase II studies or in adaptive signature designs

9 Prognostic & Predictive Biomarkers Many cancer treatments benefit only a minority of patients to whom they are administered Many cancer treatments benefit only a minority of patients to whom they are administered Particularly true for molecularly targeted drugs Particularly true for molecularly targeted drugs Being able to predict which patients are likely to benefit would Being able to predict which patients are likely to benefit would save patients from unnecessary toxicity, and enhance their chance of receiving a drug that helps them save patients from unnecessary toxicity, and enhance their chance of receiving a drug that helps them Help control medical costs Help control medical costs Improve the success rate of clinical drug development Improve the success rate of clinical drug development

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11 Prognostic and Predictive Biomarkers in Oncology Single gene or protein measurement Single gene or protein measurement e.g. HER2 protein staining 2+ or 3+ e.g. HER2 protein staining 2+ or 3+ HER2 amplification HER2 amplification KRAS mutation KRAS mutation Scalar index or classifier that summarizes contributions of multiple genes/proteins Scalar index or classifier that summarizes contributions of multiple genes/proteins Empirically determined based on genome-wide correlating gene expression to patient outcome after treatment Empirically determined based on genome-wide correlating gene expression to patient outcome after treatment

12 Prognostic Factors in Oncology Most prognostic factors are not used because they are not therapeutically relevant Most prognostic factors are not used because they are not therapeutically relevant Most prognostic factor studies do not have a clear medical objective Most prognostic factor studies do not have a clear medical objective They use a convenience sample of patients for whom tissue is available. They use a convenience sample of patients for whom tissue is available. Generally the patients are too heterogeneous to support therapeutically relevant conclusions Generally the patients are too heterogeneous to support therapeutically relevant conclusions

13 Pusztai et al. The Oncologist 8:252-8, 2003 939 articles on “prognostic markers” or “prognostic factors” in breast cancer in past 20 years 939 articles on “prognostic markers” or “prognostic factors” in breast cancer in past 20 years ASCO guidelines only recommend routine testing for ER, PR and HER-2 in breast cancer ASCO guidelines only recommend routine testing for ER, PR and HER-2 in breast cancer “With the exception of ER or progesterone receptor expression and HER-2 gene amplification, there are no clinically useful molecular predictors of response to any form of anticancer therapy.” “With the exception of ER or progesterone receptor expression and HER-2 gene amplification, there are no clinically useful molecular predictors of response to any form of anticancer therapy.”

14 Prognostic Biomarkers Can be Therapeutically Relevant <10% of node negative ER+ breast cancer patients require or benefit from the cytotoxic chemotherapy that they receive <10% of node negative ER+ breast cancer patients require or benefit from the cytotoxic chemotherapy that they receive OncotypeDx OncotypeDx 21 gene RTPCR assay for FFPE tissue 21 gene RTPCR assay for FFPE tissue

15 Key Features of OncotypeDx Development Identification of important therapeutic decision context Identification of important therapeutic decision context Prognostic marker development was based on patients with node negative ER positive breast cancer receiving tamoxifen as only systemic treatment Prognostic marker development was based on patients with node negative ER positive breast cancer receiving tamoxifen as only systemic treatment Use of patients in NSABP clinical trials Use of patients in NSABP clinical trials Staged development and validation Staged development and validation Separation of data used for test development from data used for test validation Separation of data used for test development from data used for test validation Development of robust assay with rigorous analytical validation Development of robust assay with rigorous analytical validation 21 gene RTPCR assay for FFPE tissue 21 gene RTPCR assay for FFPE tissue Quality assurance by single reference laboratory operation Quality assurance by single reference laboratory operation

16 B-14 Results—Relapse-Free Survival 338 pts 149 pts 181 pts p<0.0001 Paik et al, SABCS 2003

17 Predictive Biomarkers In the past often studied as un-focused post-hoc subset analyses of RCTs. In the past often studied as un-focused post-hoc subset analyses of RCTs. Numerous subsets examined Numerous subsets examined Same data used to define subsets for analysis and for comparing treatments within subsets Same data used to define subsets for analysis and for comparing treatments within subsets No control of type I error No control of type I error

18 Statisticians have taught physicians not to trust subset analysis unless the overall treatment effect is significant Statisticians have taught physicians not to trust subset analysis unless the overall treatment effect is significant This was good advice for post-hoc data dredging subset analysis This was good advice for post-hoc data dredging subset analysis For many molecularly targeted cancer being developed, the subset analysis will be an essential component of the primary analysis and analysis of the subsets will not be contingent on demonstrating that the overall effect is significant For many molecularly targeted cancer being developed, the subset analysis will be an essential component of the primary analysis and analysis of the subsets will not be contingent on demonstrating that the overall effect is significant

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23 Mutations Copy number changes Translocations Expression profile Treatment

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25 Types of Validation for Prognostic and Predictive Biomarkers Analytical validation Analytical validation Pre-analytical and post-analytical robustness Pre-analytical and post-analytical robustness Clinical validation Clinical validation Does the biomarker predict what it’s supposed to predict for independent data Does the biomarker predict what it’s supposed to predict for independent data Clinical utility Clinical utility Does use of the biomarker result in patient benefit Does use of the biomarker result in patient benefit

26 Clinical Utility Benefits patient by improving treatment decisions Benefits patient by improving treatment decisions Depends on context of use of the biomarker Depends on context of use of the biomarker Treatment options and practice guidelines Treatment options and practice guidelines Other prognostic factors Other prognostic factors

27 Clinical Utility of Prognostic Biomarker Prognostic biomarker for identifying patients Prognostic biomarker for identifying patients for whom practice standards imply cytotoxic chemotherapy for whom practice standards imply cytotoxic chemotherapy who have good prognosis without chemotherapy who have good prognosis without chemotherapy Prospective trial to identify such patients and withhold chemotherapy Prospective trial to identify such patients and withhold chemotherapy TAILORx TAILORx “Prospective plan” for analysis of archived specimens from previous clinical trial in which patients did not receive chemotherapy “Prospective plan” for analysis of archived specimens from previous clinical trial in which patients did not receive chemotherapy OncotypeDx OncotypeDx

28 Marker Strategy Design

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30 MINDACT Design

31 Clinical Utility of Predictive Biomarker Predictive biomarker for identifying the patients who benefit from a specific regimen and/or the patients who do not Predictive biomarker for identifying the patients who benefit from a specific regimen and/or the patients who do not Prospective RCT of new regimen versus control with tissue prospectively collected and assayed and patients classified as test + or test – Prospective RCT of new regimen versus control with tissue prospectively collected and assayed and patients classified as test + or test – Sample size established to have enough test + patients for separate analysis of new regimen versus control and enough test – patients for separate analysis of new regimen versus control Sample size established to have enough test + patients for separate analysis of new regimen versus control and enough test – patients for separate analysis of new regimen versus control Focused analysis on a single completely prospectively defined biomarker classifier Focused analysis on a single completely prospectively defined biomarker classifier

32 Prospective Co-Development of Drugs and Companion Diagnostics 1. Develop a completely specified genomic classifier of the patients likely to benefit from a new drug Single gene/protein Single gene/protein Gene expression signature Gene expression signature Screen genes using microarrays Screen genes using microarrays Develop classifier for RT-PCR platform Develop classifier for RT-PCR platform Pre-clinical, phase II data, archived specimens from previous phase III studies Pre-clinical, phase II data, archived specimens from previous phase III studies 2. Establish analytical validity of the classifier 3. Use the completely specified classifier to design and analyze a new clinical trial to evaluate effectiveness of the new treatment with a pre-defined analysis plan that preserves the overall type-I error of the study.

33 Guiding Principle The data used to develop the classifier should be distinct from the data used to test hypotheses about treatment effect in subsets determined by the classifier The data used to develop the classifier should be distinct from the data used to test hypotheses about treatment effect in subsets determined by the classifier Developmental studies can be exploratory Developmental studies can be exploratory Studies on which treatment effectiveness claims are to be based should be definitive studies that test a treatment hypothesis in a patient population completely pre-specified by the classifier Studies on which treatment effectiveness claims are to be based should be definitive studies that test a treatment hypothesis in a patient population completely pre-specified by the classifier

34 New Drug Developmental Strategy I Restrict entry to the phase III trial based on the binary predictive classifier, i.e. targeted design Restrict entry to the phase III trial based on the binary predictive classifier, i.e. targeted design

35 Using phase II data, develop predictor of response to new drug Develop Predictor of Response to New Drug Patient Predicted Responsive New Drug Control Patient Predicted Non-Responsive Off Study

36 Developmental Strategy (II) Develop Predictor of Response to New Rx Predicted Non- responsive to New Rx Predicted Responsive To New Rx Control New RXControl New RX


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