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Issues in the Analysis of Failure Time Data

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Title: Issues in the Analysis of Failure Time Data


1
Issues in the Analysis of Failure Time Data
  • Rebecca Betensky
  • Harvard School of Public Health
  • FDA/Industry Statistical Workshop
  • September 19, 2003

2
Current Issues in Failure Time Studies
  • Unrecognized heterogeneity
  • Bivariate estimation of safety and efficacy
  • Dependent interval censoring
  • Dependent truncation

3
Unrecognized Heterogeneity
  • Highly relevant as genetic discoveries are and
    are not being made
  • Known to undermine the power of clinical trials
  • Calls for adaptive designs

4
Background
  • Histologic diagnosis is principal eligibility
    criterion for clinical trials in oncology. Based
    on assumption that cancers that seem
    histologically identical constitute a single
    disease.
  • This notion is false cancers of single
    histologic type often respond differently to
    treatment, likely due to biologic differences.

5
  • In neuro-oncology, at least 3 genetic subtypes of
    anaplastic oligodendroglioma have been identified
    (1pLOH, TP53 mutation).
  • These clinically distinct subtypes are
    indistinguishable microscopically.
  • Identification of molecular subtypes and the use
    of molecular signatures to direct treatment is
    becoming part of clinical practice in
    neuro-oncology.

6
  • If molecular heterogeneity implies that only some
    patients in a clinical trial will respond to
    treatment, important implications for the design
    and interpretations of clinical trials.

7
  • North American and European Intergroup trials
    comparing chemoRT versus RT for patients with AO
    nearing completion.
  • Trials were designed prior to discovery of 3
    clinically distinct genetic subtypes
  • 1pLOH good response and survival
  • 1p intact, no TP53 mutation poor response and
    survival
  • 1p intact, TP53 mutation intermediate response
    and survival

8
  • Proportions of these genetic subtypes differ
    across cohorts in uncontrolled Phase II studies
    proportion of 1pLOH is 90, versus 60 among all
    newly diagnosed cases.
  • Leads to unrealistic design assumptions for Phase
    III trials.

9
  • Investigators now question whether these trials
    might have been under-powered due to this
    unrecognized heterogeneity.
  • Both consortia collected tumor tissue on all
    randomized cases post hoc clinical molecular
    correlative studies will be feasible and may
    enhance interpretation.

10
In Statistical Terms
  • The investigators assume that the data follow a
    simple proportional hazards model
  • However, the data really follow a different
    proportional hazards model

11
Resulting Hazard Ratios
  • Under the simple model, the hazard ratio for
    treatment is exp(?1).
  • Under the true model, the hazard ratio is a
    complicated function of t, and thus the derived
    model for treatment is not a proportional hazards
    model.

12
Illustrative Scenarios
  • In all cases, assume true effect of treatment is
    to increase survival of patients with genetic
    subtype 1.
  • Treatment is equally effective for genetic
    subtypes 1 and 2.
  • Treatment is ineffective for genetic subtype 2.
  • Treatment is detrimental.

13
Sample Size Calculation
  • In pilot data, genetic subtype 1 comprises 90 of
    the population.
  • Under simple model, 5 years of accrual, 3 years
    of follow-up, median survival of 4 years not on
    treatment, require 286 subjects to detect an
    increase of 50 in median survival with 80 power.

14
Power Calculations
  • For a sample size of 286 cases, we evaluate power
    of the simple logrank test to detect survival
    differences between the two groups, given the
    true statistical model.
  • Hazard functions are no longer propotional
    simple formulas no longer apply.

15
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16
Frailty Model
  • Unrecognized heterogeneity can undermine the
    power of a randomized trial to detect a
    beneficial treatment.
  • There will frequently be an interaction between
    treatment and the omitted covariate when it
    describes a genetic subtype.

17
  • Realistically, heterogeneity is likely to confer
    a continuum of relative risk.
  • Assume each individual has a distinct realization
    of a frailty that modifies his/her hazard.
  • Allow frailty to interact with treatment.

18
Statistical Model
  • Now, the true model is expressed as
  • where, bF(b?).

19
Numerical Studies
  • Accrual period a1
  • Follow-up period f0.5,1,1.5,2
  • ?0(t)1
  • ?0,0.1,0.2,,1.0
  • bN(0,?) and exp(b)gamma(?-1,?-1)
  • ?0.3, ?0.3

20
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21
Results
  • With interaction, ARE decreases with increasing
    variance of b, and for fixed ?, ARE decreases
    with mean time to censoring (with less censoring,
    more of an opportunity for heterogeneity to have
    an impact).
  • Without interaction, ARE remains close to 1 over
    ? and mean times to censoring.

22
  • Power decreases with ?, and for fixed ?, with
    mean time to censoring moreso with interaction.
  • This said, frailty may increase the power of the
    log rank test, due to its dual action
  • The frailty tends to attenuate the treatment
    effect ? decreasing the power
  • The frailty tends to increase the baseline hazard
    ? increasing the power relative to the sample
    size based on the non-frailty model, especially
    when using the weighted log rank test.

23
Bivariate Estimation of Safety and Efficacy
  • Often both endpoints of equal importance
  • Often highly dependent
  • Desirable to jointly estimate
  • Especially true within the context of
    sequentially designed clinical trials

24
Efficacy and Safety Data
  • Efficacy
  • Continuous time to event subject to right
    censoring
  • Survival time
  • Safety
  • Discrete measure also subject to right censoring
  • rounds of chemotherapy tolerable to cancer
    patients
  • Tumor grade when stereotactic biopsy is used

25
Data Structure
26
Estimator
27
Properties of the Estimator
  • NPML by invariance property
  • Completely non-parametric
  • Results in very little negative mass
  • Computationally simple
  • Closed-form covariance estimator

28
Simulation Study
  • Campbell Földes (1982) estimator
  • Simulated (X,Y) and (C,D) times using Gumbel
    (1960) bivariate exponential distribution
  • Tried both continuous and discretized
    times

29
Simulation Results
30
Simulation Results
31
E2290 Data
32
E2290 Data
33
Sequential Analysis
34
Sequential Estimator
35
Properties of Sequential Estimator
  • Covariance estimate with respect to calendar time
    t
  • First bivariate survival estimator with
    sequential application
  • Other estimators for sequential analysis of
    safety and efficacy data rely on summary
    statistics or assumptions that are inappropriate
    for bivariate right-censored data.

36
Conclusions
  • A number of issues arise in bivariate survival
    estimation we chose to focus on computational
    simplicity and closed-form covariance estimation.
  • The form of our estimator and its
    interpretability allows for practical application
    in sequential clinical trials.

37
Dependent Interval Censoring
  • In certain situations can test for dependent
    censoring (not true for right censored or current
    status data).
  • Use frailty models to handle dependence.

38
Dependent Truncation
  • With truncated data, view only part of the
    population of interest.
  • Important assumption is quasi-independence, i.e.
    independence of failure and truncation over the
    observable region.
  • Can test for quasi-independence!
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