Overview of Monitoring Clinical Trials Scott S. Emerson, M.D., Ph.D. Professor of Biostatistics...
-
Upload
mervyn-powers -
Category
Documents
-
view
216 -
download
0
Transcript of Overview of Monitoring Clinical Trials Scott S. Emerson, M.D., Ph.D. Professor of Biostatistics...
Overview of Monitoring Clinical Trials
Overview of Monitoring Clinical Trials
Scott S. Emerson, M.D., Ph.D.Professor of Biostatistics University of Washington
August 5, 2006
Scott S. Emerson, M.D., Ph.D.Professor of Biostatistics University of Washington
August 5, 2006
22
TopicsTopics
• Goals / Disclaimers• Clinical trial setting / Study design• Stopping rules• Sequential inference• Adaptive designs
• Goals / Disclaimers• Clinical trial setting / Study design• Stopping rules• Sequential inference• Adaptive designs
33
Goals / DisclaimersGoals / Disclaimers
GoalsGoals
44
DemystificationDemystification
• All we are doing is statistics– Planning a study
– Gathering data
– Analyzing it
• All we are doing is statistics– Planning a study
– Gathering data
– Analyzing it
55
Sequential StudiesSequential Studies
• All we are doing is statistics– Planning a study
• Added dimension of considering time required– Gathering data
• Sequential sampling allows early termination– Analyzing it
• The same old inferential techniques• The same old statistics• But new sampling distribution
• All we are doing is statistics– Planning a study
• Added dimension of considering time required– Gathering data
• Sequential sampling allows early termination– Analyzing it
• The same old inferential techniques• The same old statistics• But new sampling distribution
66
Distinctions without DifferencesDistinctions without Differences
• Sequential sampling plans– Group sequential stopping rules– Error spending functions– Conditional / predictive power
• Statistical treatment of hypotheses– Superiority / Inferiority / Futility– Two-sided tests / bioequivalence
• Sequential sampling plans– Group sequential stopping rules– Error spending functions– Conditional / predictive power
• Statistical treatment of hypotheses– Superiority / Inferiority / Futility– Two-sided tests / bioequivalence
77
Perpetual Motion MachinesPerpetual Motion Machines
• Discerning the hyperbole in much of the recent statistical literature– “Self-designing” clinical trials– Other adaptive clinical trial designs
• (But in my criticisms, I do use a more restricted definition than some in my criticisms)
• Discerning the hyperbole in much of the recent statistical literature– “Self-designing” clinical trials– Other adaptive clinical trial designs
• (But in my criticisms, I do use a more restricted definition than some in my criticisms)
88
Key IssueKey Issue
You better think (think)
about what you’re
trying to do…
-Aretha Franklin
You better think (think)
about what you’re
trying to do…
-Aretha Franklin
99
Evaluation of Trial DesignEvaluation of Trial Design
• When planning an expensive (in time or money) clinical trial, there is no substitute for planning– Will your clinical trial satisfy (as much as possible) the
various collaborating disciplines with respect to the primary endpoint?
• The major part of this question can be answered at the beginning of the clinical trial
• When planning an expensive (in time or money) clinical trial, there is no substitute for planning– Will your clinical trial satisfy (as much as possible) the
various collaborating disciplines with respect to the primary endpoint?
• The major part of this question can be answered at the beginning of the clinical trial
1010
Goals / DisclaimersGoals / Disclaimers
DisclaimersDisclaimers
1111
Conflict of InterestConflict of Interest
• Commercially available software for sequential clinical trials– S+SeqTrial (Emerson)– PEST (Whitehead)– EaSt (Mehta)– ?SAS
• Commercially available software for sequential clinical trials– S+SeqTrial (Emerson)– PEST (Whitehead)– EaSt (Mehta)– ?SAS
1212
Personal DefectsPersonal Defects
• Physical• Personality
– In the perjorative sense of the words• Then:
– A bent twig
• Now:– Old and male– University professor
1313
A More Descriptive TitleA More Descriptive Title
• All my talks
The Use of Statistics to Answer
Scientific Questions (Confessions of a Former Statistician)
• All my talks
The Use of Statistics to Answer
Scientific Questions (Confessions of a Former Statistician)
1414
A More Descriptive TitleA More Descriptive Title
• All my talks
The Use of Statistics to Answer
Scientific Questions (Confessions of a Former Statistician)
• Group sequential talks
The Use of Statistics to Answer
Scientific Questions Ethically and Efficiently (Confessions of a Former Statistician)
• All my talks
The Use of Statistics to Answer
Scientific Questions (Confessions of a Former Statistician)
• Group sequential talks
The Use of Statistics to Answer
Scientific Questions Ethically and Efficiently (Confessions of a Former Statistician)
1515
Science vs StatisticsScience vs Statistics
• Recognizing the difference between– The parameter space
• What is the true scientific relationship?– The sample space
• What data did you gather?
• Recognizing the difference between– The parameter space
• What is the true scientific relationship?– The sample space
• What data did you gather?
1616
Science vs StatisticsScience vs Statistics
• Recognizing the difference between– The true scientific relationship
• Summary measures of the effect – Means, medians, geometric means, proportions…
– The precision with which you know the true effect• Power• P values, posterior probabilities
• Recognizing the difference between– The true scientific relationship
• Summary measures of the effect – Means, medians, geometric means, proportions…
– The precision with which you know the true effect• Power• P values, posterior probabilities
1717
Reporting InferenceReporting Inference
• At the end of the study analyze the data• Report three measures (four numbers)
– Point estimate– Interval estimate– Quantification of confidence / belief in hypotheses
• At the end of the study analyze the data• Report three measures (four numbers)
– Point estimate– Interval estimate– Quantification of confidence / belief in hypotheses
1818
Reporting Frequentist InferenceReporting Frequentist Inference
• Three measures (four numbers)– Consider whether the observed data might
reasonably be expected to be obtained under particular hypotheses
• Point estimate: minimal bias? MSE?• Confidence interval: all hypotheses for which the
data might reasonably be observed• P value: probability such extreme data would have
been obtained under the null hypothesis– Binary decision: Reject or do not reject the null according
to whether the P value is low
• Three measures (four numbers)– Consider whether the observed data might
reasonably be expected to be obtained under particular hypotheses
• Point estimate: minimal bias? MSE?• Confidence interval: all hypotheses for which the
data might reasonably be observed• P value: probability such extreme data would have
been obtained under the null hypothesis– Binary decision: Reject or do not reject the null according
to whether the P value is low
1919
Reporting Bayesian InferenceReporting Bayesian Inference
• Three measures (four numbers)– Consider the probability distribution of the parameter
conditional on the observed data• Point estimate: Posterior mean, median, mode• Credible interval: The “central” 95% of the
posterior distribution • Posterior probability: probability of a particular
hypothesis conditional on the data– Binary decision: Reject or do not reject the null according
to whether the posterior probability is low
• Three measures (four numbers)– Consider the probability distribution of the parameter
conditional on the observed data• Point estimate: Posterior mean, median, mode• Credible interval: The “central” 95% of the
posterior distribution • Posterior probability: probability of a particular
hypothesis conditional on the data– Binary decision: Reject or do not reject the null according
to whether the posterior probability is low
2020
Parallels Between Tests, CIsParallels Between Tests, CIs
• If the null hypothesis not in CI, reject null• (Using same level of confidence)
• Relative advantages– Test only requires sampling distn under null– CI requires sampling distn under alternatives– CI provides interpretation when null is not rejected
• If the null hypothesis not in CI, reject null• (Using same level of confidence)
• Relative advantages– Test only requires sampling distn under null– CI requires sampling distn under alternatives– CI provides interpretation when null is not rejected
2121
Scientific InformationScientific Information
– “Rejection” uses a single level of significance• Different settings might demand different criteria
– P value communicates statistical evidence, not scientific importance
– Only confidence interval allows you to interpret failure to reject the null:
• Distinguish between– Inadequate precision (sample size)– Strong evidence for null
– “Rejection” uses a single level of significance• Different settings might demand different criteria
– P value communicates statistical evidence, not scientific importance
– Only confidence interval allows you to interpret failure to reject the null:
• Distinguish between– Inadequate precision (sample size)– Strong evidence for null
2222
Hypothetical ExampleHypothetical Example
• Clinical trials of treatments for hypertension– Screening trials for four candidate drugs
• Measure of treatment effect is the difference in average SBP at the end of six months treatment
• Drugs may differ in– Treatment effect (goal is to find best)– Variability of blood pressure
• Clinical trials may differ in conditions– Sample size, etc.
• Clinical trials of treatments for hypertension– Screening trials for four candidate drugs
• Measure of treatment effect is the difference in average SBP at the end of six months treatment
• Drugs may differ in– Treatment effect (goal is to find best)– Variability of blood pressure
• Clinical trials may differ in conditions– Sample size, etc.
2323
Reporting P valuesReporting P values
Study P value
A 0.1974
B 0.1974
C 0.0099
D 0.0099
Study P value
A 0.1974
B 0.1974
C 0.0099
D 0.0099
2424
Point EstimatesPoint Estimates
Study SBP Diff
A 27.16
B 0.27
C 27.16
D 0.27
Study SBP Diff
A 27.16
B 0.27
C 27.16
D 0.27
2525
Point EstimatesPoint Estimates
Study SBP Diff P value
A 27.16 0.1974
B 0.27 0.1974
C 27.16 0.0099
D 0.27 0.0099
Study SBP Diff P value
A 27.16 0.1974
B 0.27 0.1974
C 27.16 0.0099
D 0.27 0.0099
2626
Confidence IntervalsConfidence Intervals
Study SBP Diff 95% CI P value
A 27.16 -14.14, 68.46 0.1974
B 0.27 -0.14, 0.68 0.1974
C 27.16 6.51, 47.81 0.0099
D 0.27 0.06, 0.47 0.0099
Study SBP Diff 95% CI P value
A 27.16 -14.14, 68.46 0.1974
B 0.27 -0.14, 0.68 0.1974
C 27.16 6.51, 47.81 0.0099
D 0.27 0.06, 0.47 0.0099
2727
Interpreting NonsignificanceInterpreting Nonsignificance
• Studies A and B are both “nonsignificant”– Only study B ruled out clinically important differences– The results of study A might reasonably have been
obtained if the treatment truly lowered SBP by as much as 68 mm Hg
• Studies A and B are both “nonsignificant”– Only study B ruled out clinically important differences– The results of study A might reasonably have been
obtained if the treatment truly lowered SBP by as much as 68 mm Hg
2828
Interpreting SignificanceInterpreting Significance
• Studies C and D are both statistically significant results– Only study C demonstrated clinically important
differences– The results of study D are only frequently obtained if
the treatment truly lowered SBP by 0.47 mm Hg or less
• Studies C and D are both statistically significant results– Only study C demonstrated clinically important
differences– The results of study D are only frequently obtained if
the treatment truly lowered SBP by 0.47 mm Hg or less
2929
Bottom LineBottom Line
• If ink is not in short supply, there is no reason not to give point estimates, CI, and P value
• If ink is in short supply, the confidence interval provides most information– (but sometimes a confidence interval cannot be easily
obtained, because the sampling distribution is unknown under the null)
• If ink is not in short supply, there is no reason not to give point estimates, CI, and P value
• If ink is in short supply, the confidence interval provides most information– (but sometimes a confidence interval cannot be easily
obtained, because the sampling distribution is unknown under the null)
3030
But: Impact of “Three over n”But: Impact of “Three over n”
• The sample size is also important– The pure statistical fantasy
• The P value and CI account for the sample size– The scientific reality
• We need to be able to judge what proportion of the population might have been missed in our sample
– There might be “outliers” in the population– If they are not in our sample, we will not have correctly
estimated the variability of our estimates
• The “Three over n” rule provides some guidance
• The sample size is also important– The pure statistical fantasy
• The P value and CI account for the sample size– The scientific reality
• We need to be able to judge what proportion of the population might have been missed in our sample
– There might be “outliers” in the population– If they are not in our sample, we will not have correctly
estimated the variability of our estimates
• The “Three over n” rule provides some guidance
3131
Full Report of AnalysisFull Report of Analysis
Study n SBP Diff 95% CI P value
A 20 27.16 -14.14, 68.46 0.1974
B 20 0.27 -0.14, 0.68 0.1974
C 80 27.16 6.51, 47.81 0.0099
D 80 0.27 0.06, 0.47 0.0099
Study n SBP Diff 95% CI P value
A 20 27.16 -14.14, 68.46 0.1974
B 20 0.27 -0.14, 0.68 0.1974
C 80 27.16 6.51, 47.81 0.0099
D 80 0.27 0.06, 0.47 0.0099
3232
Interpreting a “Negative Study”Interpreting a “Negative Study”
• This then highlights issues related to the interpretation of a study in which no statistically significant difference between groups was found– We have to consider the “differential diagnosis” of
possible situations in which we might observe nonsignificance
• This then highlights issues related to the interpretation of a study in which no statistically significant difference between groups was found– We have to consider the “differential diagnosis” of
possible situations in which we might observe nonsignificance
3333
General approachGeneral approach
• Refined scientific question– We compare the distribution of some response
variable differs across groups• E.g., looking for an association between smoking
and blood pressure by comparing distribution of SBP between smokers and nonsmokers
– We base our decisions on a scientifically appropriate summary measure
• E.g., difference of means, ratio of medians, …
• Refined scientific question– We compare the distribution of some response
variable differs across groups• E.g., looking for an association between smoking
and blood pressure by comparing distribution of SBP between smokers and nonsmokers
– We base our decisions on a scientifically appropriate summary measure
• E.g., difference of means, ratio of medians, …
3434
Interpreting a “Negative Study”Interpreting a “Negative Study”
• Possible explanations for no statistically significant difference in
• There is no true difference in the distribution of response across groups
• There is a difference in the distribution of response across groups, but the value of is the same for both groups
– (i.e., the distributions differ in some other way)
• There is a difference in the value of between the groups, but our study was not precise enough
– A “type II error” from low “statistical power”
• Possible explanations for no statistically significant difference in
• There is no true difference in the distribution of response across groups
• There is a difference in the distribution of response across groups, but the value of is the same for both groups
– (i.e., the distributions differ in some other way)
• There is a difference in the value of between the groups, but our study was not precise enough
– A “type II error” from low “statistical power”
3535
Interpreting a “Positive Study”Interpreting a “Positive Study”
• Analogous interpretations when we do find a statistically significant difference in
• There is a true difference in the value of • There is no true difference in , but we were
unlucky and observed spuriously high or low results
– Random chance leading to a “type I error”» The p value tells us how unlucky we would have had
to have been – (Used a statistic that allows other differences in the distn
to be misinterpreted as a difference in » E.g., different variances causing significant t test)
• Analogous interpretations when we do find a statistically significant difference in
• There is a true difference in the value of • There is no true difference in , but we were
unlucky and observed spuriously high or low results
– Random chance leading to a “type I error”» The p value tells us how unlucky we would have had
to have been – (Used a statistic that allows other differences in the distn
to be misinterpreted as a difference in » E.g., different variances causing significant t test)
3636
Bottom LineBottom Line
• I place greatest emphasis on estimation rather than hypothesis testing
• When doing testing, I take more of a decision theoretic view– I argue this is more in keeping with the scientific
method• (Ask me about The Scientist Game)
• All these principles carry over to sequential testing
• I place greatest emphasis on estimation rather than hypothesis testing
• When doing testing, I take more of a decision theoretic view– I argue this is more in keeping with the scientific
method• (Ask me about The Scientist Game)
• All these principles carry over to sequential testing
3737
Group Sequential MethodsGroup Sequential Methods
• Scientific measures– Decision theoretic
• Statement of hypotheses• Criteria for early stopping based on point and
interval estimates– Proper inference for estimation
• Purely statistical measures– Focus on type I errors– Error spending functions– Conditional / predictive power
• Scientific measures– Decision theoretic
• Statement of hypotheses• Criteria for early stopping based on point and
interval estimates– Proper inference for estimation
• Purely statistical measures– Focus on type I errors– Error spending functions– Conditional / predictive power
3838
Clinical Trial SettingClinical Trial Setting
3939
Clinical TrialsClinical Trials
• Experimentation in human volunteers– Investigates a new treatment/preventive agent
• Safety: » Are there adverse effects that clearly outweigh any
potential benefit?
• Efficacy: » Can the treatment alter the disease process in a
beneficial way?
• Effectiveness: » Would adoption of the treatment as a standard affect
morbidity / mortality in the population?
• Experimentation in human volunteers– Investigates a new treatment/preventive agent
• Safety: » Are there adverse effects that clearly outweigh any
potential benefit?
• Efficacy: » Can the treatment alter the disease process in a
beneficial way?
• Effectiveness: » Would adoption of the treatment as a standard affect
morbidity / mortality in the population?
4040
Clinical Trial DesignClinical Trial Design
• Finding an approach that best addresses the often competing goals: Science, Ethics, Efficiency– Basic scientists: focus on mechanisms– Clinical scientists: focus on overall patient health– Ethical: focus on patients on trial, future patients– Economic: focus on profits and/or costs– Governmental: focus on validity of marketing claims– Statistical: focus on questions answered precisely – Operational: focus on feasibility of mounting trial
• Finding an approach that best addresses the often competing goals: Science, Ethics, Efficiency– Basic scientists: focus on mechanisms– Clinical scientists: focus on overall patient health– Ethical: focus on patients on trial, future patients– Economic: focus on profits and/or costs– Governmental: focus on validity of marketing claims– Statistical: focus on questions answered precisely – Operational: focus on feasibility of mounting trial
4141
Statistical PlanningStatistical Planning
• Satisfy collaborators as much as possible– Discriminate between relevant scientific hypotheses
• Scientific and statistical credibility– Protect economic interests of sponsor
• Efficient designs• Economically important estimates
– Protect interests of patients on trial• Stop if unsafe or unethical• Stop when credible decision can be made
– Promote rapid discovery of new beneficial treatments
• Satisfy collaborators as much as possible– Discriminate between relevant scientific hypotheses
• Scientific and statistical credibility– Protect economic interests of sponsor
• Efficient designs• Economically important estimates
– Protect interests of patients on trial• Stop if unsafe or unethical• Stop when credible decision can be made
– Promote rapid discovery of new beneficial treatments
4242
Refine Scientific HypothesesRefine Scientific Hypotheses
– Target population
• Inclusion, exclusion, important subgroups
– Intervention
• Dose, administration (intention to treat)
– Measurement of outcome(s)
• Efficacy/effectiveness, toxicity
– Statistical hypotheses in terms of some summary measure of outcome distribution
• Mean, geometric mean, median, odds, hazard, etc.
– Criteria for statistical credibility
• Frequentist (type I, II errors) or Bayesian
– Target population
• Inclusion, exclusion, important subgroups
– Intervention
• Dose, administration (intention to treat)
– Measurement of outcome(s)
• Efficacy/effectiveness, toxicity
– Statistical hypotheses in terms of some summary measure of outcome distribution
• Mean, geometric mean, median, odds, hazard, etc.
– Criteria for statistical credibility
• Frequentist (type I, II errors) or Bayesian
4343
Statistics to Address VariabilityStatistics to Address Variability
• At the end of the study:– Frequentist and/or Bayesian data analysis to assess
the credibility of clinical trial results• Estimate of the treatment effect
– Single best estimate– Precision of estimates
• Decision for or against hypotheses– Binary decision– Quantification of strength of evidence
• At the end of the study:– Frequentist and/or Bayesian data analysis to assess
the credibility of clinical trial results• Estimate of the treatment effect
– Single best estimate– Precision of estimates
• Decision for or against hypotheses– Binary decision– Quantification of strength of evidence
4444
Statistical Sampling PlanStatistical Sampling Plan
• Ethical and efficiency concerns are addressed through sequential sampling– During the conduct of the study, data are analyzed at
periodic intervals and reviewed by the DMC– Using interim estimates of treatment effect
• Decide whether to continue the trial• If continuing, decide on any modifications to
– scientific / statistical hypotheses and/or– sampling scheme
• Ethical and efficiency concerns are addressed through sequential sampling– During the conduct of the study, data are analyzed at
periodic intervals and reviewed by the DMC– Using interim estimates of treatment effect
• Decide whether to continue the trial• If continuing, decide on any modifications to
– scientific / statistical hypotheses and/or– sampling scheme
4545
Sample Size DeterminationSample Size Determination
• Based on sampling plan, statistical analysis plan, and estimates of variability, compute– Sample size that discriminates hypotheses with
desired power, or– Hypothesis that is discriminated from null with desired
power when sample size is as specified, or– Power to detect the specific alternative when sample
size is as specified
• Based on sampling plan, statistical analysis plan, and estimates of variability, compute– Sample size that discriminates hypotheses with
desired power, or– Hypothesis that is discriminated from null with desired
power when sample size is as specified, or– Power to detect the specific alternative when sample
size is as specified
4646
Sample Size ComputationSample Size Computation
) : testsample (Fixed
:units sampling Required
unit sampling 1 within y Variabilit
ealternativDesign
when cesignifican of Level
power with detected :1)(n test level edStandardiz
2/1
201
2
1
0
zz
Vn
V
4747
When Sample Size ConstrainedWhen Sample Size Constrained
• Often (usually?) logistical constraints impose a maximal sample size– Compute power to detect specified alternative
– Compute alternative detected with high power
• Often (usually?) logistical constraints impose a maximal sample size– Compute power to detect specified alternative
– Compute alternative detected with high power
n
V 01
01such that Find V
n
4848
Stopping RulesStopping Rules
Monitoring a TrialMonitoring a Trial
4949
Need for Monitoring a Trial• Ethical concerns
– Patients already on trial• Avoid harm; maintain informed consent
– Patients not on trial• Facilitate rapid introduction of treatments
• Efficiency concerns– Minimize costs
• Number of patients accrued, followed• Calendar time
5050
Working Example Working Example
• Fixed sample two-sided tests– Test of a two-sided alternative (+ > 0 > - )
• Upper Alternative: H+: + (superiority)
• Null: H0: = 0 (equivalence)
• Lower Alternative: H -: - (inferiority)
– Decisions:
• Reject H0 , H - (for H+) T cU
• Reject H+ , H - (for H0) cL T cU
• Reject H+ , H0 (for H -) T cL
• Fixed sample two-sided tests– Test of a two-sided alternative (+ > 0 > - )
• Upper Alternative: H+: + (superiority)
• Null: H0: = 0 (equivalence)
• Lower Alternative: H -: - (inferiority)
– Decisions:
• Reject H0 , H - (for H+) T cU
• Reject H+ , H - (for H0) cL T cU
• Reject H+ , H0 (for H -) T cL
5151
Sample Path for a StatisticSample Path for a Statistic
5252
Fixed Sample Methods WrongFixed Sample Methods Wrong
• Simulated trials under null stop too often• Simulated trials under null stop too often
5353
Simulated Trials (Pocock)Simulated Trials (Pocock)
• Three equally spaced level .05 analysesPattern of Proportion Significant
Significance 1st 2nd 3rd Ever
1st only .03046 .03046
1st, 2nd .00807 .00807 .00807
1st, 3rd .00317 .00317 .00317
1st, 2nd, 3rd .00868 .00868 .00868 .00868
2nd only .01921 .01921
2nd, 3rd .01426 .01426 .01426
3rd only .02445 .02445
Any pattern .05038 .05022 .05056 .10830
• Three equally spaced level .05 analysesPattern of Proportion Significant
Significance 1st 2nd 3rd Ever
1st only .03046 .03046
1st, 2nd .00807 .00807 .00807
1st, 3rd .00317 .00317 .00317
1st, 2nd, 3rd .00868 .00868 .00868 .00868
2nd only .01921 .01921
2nd, 3rd .01426 .01426 .01426
3rd only .02445 .02445
Any pattern .05038 .05022 .05056 .10830
5454
Pocock Level 0.05Pocock Level 0.05
• Three equally spaced level .022 analysesPattern of Proportion Significant
Significance 1st 2nd 3rd Ever
1st only .01520 .01520
1st, 2nd .00321 .00321 .00321
1st, 3rd .00113 .00113 .00113
1st, 2nd, 3rd .00280 .00280 .00280 .00280
2nd only .01001 .01001
2nd, 3rd .00614 .00614 .00614
3rd only .01250 .01250
Any pattern .02234 .02216 .02257 .05099
• Three equally spaced level .022 analysesPattern of Proportion Significant
Significance 1st 2nd 3rd Ever
1st only .01520 .01520
1st, 2nd .00321 .00321 .00321
1st, 3rd .00113 .00113 .00113
1st, 2nd, 3rd .00280 .00280 .00280 .00280
2nd only .01001 .01001
2nd, 3rd .00614 .00614 .00614
3rd only .01250 .01250
Any pattern .02234 .02216 .02257 .05099
5555
Unequally Spaced AnalysesUnequally Spaced Analyses
• Level .022 analyses at 10%, 20%, 100% of dataPattern of Proportion Significant
Significance 1st 2nd 3rd Ever
1st only .01509 .01509
1st, 2nd .00521 .00521 .00521
1st, 3rd .00068 .00068 .00068
1st, 2nd, 3rd .00069 .00069 .00069 .00069
2nd only .01473 .01473
2nd, 3rd .00165 .00165 .00165
3rd only .01855 .01855
Any pattern .02167 .02228 .02157 .05660
• Level .022 analyses at 10%, 20%, 100% of dataPattern of Proportion Significant
Significance 1st 2nd 3rd Ever
1st only .01509 .01509
1st, 2nd .00521 .00521 .00521
1st, 3rd .00068 .00068 .00068
1st, 2nd, 3rd .00069 .00069 .00069 .00069
2nd only .01473 .01473
2nd, 3rd .00165 .00165 .00165
3rd only .01855 .01855
Any pattern .02167 .02228 .02157 .05660
5656
Varying Critical Values (OBF)Varying Critical Values (OBF)
• Level 0.10 O’Brien-Fleming (1979); equally spaced tests at .003, .036, .087
Pattern of Proportion Significant
Significance 1st 2nd 3rd Ever
1st only .00082 .00082
1st, 2nd .00036 .00036 .00036
1st, 3rd .00037 .00037 .00037
1st, 2nd, 3rd .00127 .00127 .00127 .00127
2nd only .01164 .01164
2nd, 3rd .02306 .02306 .02306
3rd only .06223 .01855
Any pattern .00282 .03633 .08693 .09975
• Level 0.10 O’Brien-Fleming (1979); equally spaced tests at .003, .036, .087
Pattern of Proportion Significant
Significance 1st 2nd 3rd Ever
1st only .00082 .00082
1st, 2nd .00036 .00036 .00036
1st, 3rd .00037 .00037 .00037
1st, 2nd, 3rd .00127 .00127 .00127 .00127
2nd only .01164 .01164
2nd, 3rd .02306 .02306 .02306
3rd only .06223 .01855
Any pattern .00282 .03633 .08693 .09975
5757
Error Spending: Pocock 0.05Error Spending: Pocock 0.05
Pattern of Proportion Significant
Significance 1st 2nd 3rd Ever
1st only .01520 .01520
1st, 2nd .00321 .00321 .00321
1st, 3rd .00113 .00113 .00113
1st, 2nd, 3rd .00280 .00280 .00280 .00280
2nd only .01001 .01001
2nd, 3rd .00614 .00614 .00614
3rd only .01250 .01250
Any pattern .02234 .02216 .02257 .05099
Incremental error .02234 .01615 .01250
Cumulative error .02234 .03849 .05099
Pattern of Proportion Significant
Significance 1st 2nd 3rd Ever
1st only .01520 .01520
1st, 2nd .00321 .00321 .00321
1st, 3rd .00113 .00113 .00113
1st, 2nd, 3rd .00280 .00280 .00280 .00280
2nd only .01001 .01001
2nd, 3rd .00614 .00614 .00614
3rd only .01250 .01250
Any pattern .02234 .02216 .02257 .05099
Incremental error .02234 .01615 .01250
Cumulative error .02234 .03849 .05099
5858
Stopping RulesStopping Rules
DefinitionsDefinitions
5959
QuestionQuestion
• Under what conditions should we stop the study early?
• Under what conditions should we stop the study early?
6060
Scientific ReasonsScientific Reasons
• Safety• Efficacy• Harm• Approximate equivalence• Futility
• Safety• Efficacy• Harm• Approximate equivalence• Futility
6161
Statistical CriteriaStatistical Criteria
• Extreme estimates of treatment effect• Statistical significance (Frequentist)
– At final analysis: Curtailment– Based on experimentwise error
• Group sequential rule• Error spending function
• Statistical credibility (Bayesian)• Probability of achieving statistical significance /
credibility at final analysis– Condition on current data and presumed treatment effect
• Extreme estimates of treatment effect• Statistical significance (Frequentist)
– At final analysis: Curtailment– Based on experimentwise error
• Group sequential rule• Error spending function
• Statistical credibility (Bayesian)• Probability of achieving statistical significance /
credibility at final analysis– Condition on current data and presumed treatment effect
6262
Sequential Sampling IssuesSequential Sampling Issues
– Design stage• Choosing sampling plan which satisfies desired
operating characteristics– E.g., type I error, power, sample size requirements
– Monitoring stage• Flexible implementation to account for assumptions
made at design stage– E.g., adjust sample size to account for observed variance
– Analysis stage• Providing inference based on true sampling
distribution of test statistics
– Design stage• Choosing sampling plan which satisfies desired
operating characteristics– E.g., type I error, power, sample size requirements
– Monitoring stage• Flexible implementation to account for assumptions
made at design stage– E.g., adjust sample size to account for observed variance
– Analysis stage• Providing inference based on true sampling
distribution of test statistics
6363
Prespecified Stopping PlansPrespecified Stopping Plans
• Prior to collection of data, specify– Scientific and statistical hypotheses of interest– Statistical criteria for credible evidence– Rule for determining maximal statistical information
• E.g., fix power, maximal sample size, or study time– Randomization scheme– Rule for determining schedule of analyses
• E.g., according to sample size, statistical information, or calendar time
– Rule for determining conditions for early stopping• E.g., boundary shape function for stopping rule
• Prior to collection of data, specify– Scientific and statistical hypotheses of interest– Statistical criteria for credible evidence– Rule for determining maximal statistical information
• E.g., fix power, maximal sample size, or study time– Randomization scheme– Rule for determining schedule of analyses
• E.g., according to sample size, statistical information, or calendar time
– Rule for determining conditions for early stopping• E.g., boundary shape function for stopping rule
6464
Sampling Plan: General ApproachSampling Plan: General Approach
– Perform analyses when sample sizes N1. . . NJ
• Can be randomly determined
– At each analysis choose stopping boundaries
• aj < bj < cj < dj
– Compute test statistic Tj=T(X1. . . XNj)
• Stop if Tj < aj (extremely low)
• Stop if bj < Tj < cj (approximate equivalence)
• Stop if Tj > dj (extremely high)
• Otherwise continue (maybe adaptive modification of analysis schedule, sample size, etc.)
– Boundaries for modification of sampling plan
– Perform analyses when sample sizes N1. . . NJ
• Can be randomly determined
– At each analysis choose stopping boundaries
• aj < bj < cj < dj
– Compute test statistic Tj=T(X1. . . XNj)
• Stop if Tj < aj (extremely low)
• Stop if bj < Tj < cj (approximate equivalence)
• Stop if Tj > dj (extremely high)
• Otherwise continue (maybe adaptive modification of analysis schedule, sample size, etc.)
– Boundaries for modification of sampling plan
6565
Boundary ScalesBoundary Scales
• Choices for test statistic Tj – Sum of observations– Point estimate of treatment effect– Normalized (Z) statistic– Fixed sample P value– Error spending function– Bayesian posterior probability– Conditional probability– Predictive probability
• Choices for test statistic Tj – Sum of observations– Point estimate of treatment effect– Normalized (Z) statistic– Fixed sample P value– Error spending function– Bayesian posterior probability– Conditional probability– Predictive probability
6666
Correspondence Among ScalesCorrespondence Among Scales
• Choices for test statistic Tj – All of those choices for test statistics can be shown to
be transformations of each other– Hence, a stopping rule for one test statistic is easily
transformed to a stopping rule for a different test statistic
– We regard these statistics as representing different scales for expressing the boundaries
• Choices for test statistic Tj – All of those choices for test statistics can be shown to
be transformations of each other– Hence, a stopping rule for one test statistic is easily
transformed to a stopping rule for a different test statistic
– We regard these statistics as representing different scales for expressing the boundaries
6767
Boundary Scales: Notation• One sample inference about means
– Generalizable to most other commonly used models
jj
N
J
N
NNX
xxj
NNN
H
iidXX
j
2
1
1
00
21
,~ rule stopping a of absencein
:sassumption onalDistributi
,, :analysisth at Data
,, after Analyses
: :hypothesis Null
,,, :modely Probabilit
6868
Partial Sum ScalePartial Sum Scale
• Uses:– Cumulative number of events
• Boundary for 1 sample test of proportion– Convenient when computing density
• Uses:– Cumulative number of events
• Boundary for 1 sample test of proportion– Convenient when computing density
jN
i ij xs1
6969
MLE ScaleMLE Scale
j
jN
i iNj N
sxx
j
j
1
1
• Uses:– Natural (crude) estimate of treatment effect
7070
Normalized (Z) Statistic ScaleNormalized (Z) Statistic Scale
0
jjj
xNz
• Uses:– Commonly computed in analysis routines
7171
Fixed Sample P Value ScaleFixed Sample P Value Scale
• Uses:– Commonly computed in analysis routine– Robust to use with other distributions for estimates of
treatment effect
• Uses:– Commonly computed in analysis routine– Robust to use with other distributions for estimates of
treatment effect
due
z
zp
uj
jj
22
2
11
1
7272
Error Spending ScaleError Spending Scale
• Uses:– Implementation of stopping rules with flexible
determination of number and timing of analyses
];Pr
;,Pr[1 1
1
1
1
,,
djj
j
i
i
kdkdkckbkakii
udj
sS
SdSE
7373
Bayesian Posterior ScaleBayesian Posterior Scale
• Uses:– Bayesian inference (unaffected by stopping)– Posterior probability of hypotheses
• Uses:– Bayesian inference (unaffected by stopping)– Posterior probability of hypotheses
22
2222*
,,1**
2
1
|Pr
,~on distributiPrior
j
jjj
N
N
xNN
XXB
N
jj
7474
Conditional Power ScaleConditional Power Scale
• Uses:– Conditional power
– Probability of significant result at final analysis conditional on data so far (and hypothesis)
– Futility of continuing under specific hypothesis
jJ
jXJ
jXJXj
X
NN
xNtN
XtXtC
t
jJ
JJ
J
**
*;*
*
1
|Pr,
mean of valueedHypothesiz
analysis finalat Threshold
7575
Conditional Power Scale (MLE)Conditional Power Scale (MLE)
• Uses:– Conditional power– Futility of continuing under specific hypothesis
jJ
jXJ
jjXJtj
j
X
NN
xtN
xXtXC
x
t
J
JJX
J
1
|Pr,
mean of valueedHypothesiz
analysis finalat Threshold
;*
*
7676
Predictive Power ScalePredictive Power Scale
2222
222
2
1
|,|Pr
,~on distributiPrior
analysis finalat Threshold
jJjJ
jjJjXjJ
jjXjXj
X
NNNN
xNNxtNN
dXXtXtH
N
t
J
JJ
J
• Uses:– Futility of continuing study
7777
Predictive Power (Flat Prior)Predictive Power (Flat Prior)
jJNN
jXJ
jjXjXj
X
NN
xtN
dXXtXtH
N
t
j
J
J
JJ
J
1
|,|Pr
,~on distributiPrior
analysis finalat Threshold
2
• Uses:– Futility of continuing study
7878
Boundary ScalesBoundary Scales
• Stopping rule for one test statistic is easily transformed to a rule for another statistic
• “Group sequential stopping rules”– Sum of observations– Point estimate of treatment effect– Normalized (Z) statistic
– Fixed sample P value– Error spending function
• Bayesian posterior probability • Stochastic Curtailment
– Conditional probability– Predictive probability
• Stopping rule for one test statistic is easily transformed to a rule for another statistic
• “Group sequential stopping rules”– Sum of observations– Point estimate of treatment effect– Normalized (Z) statistic
– Fixed sample P value– Error spending function
• Bayesian posterior probability • Stochastic Curtailment
– Conditional probability– Predictive probability
7979
Which Scale: My ViewWhich Scale: My View
• Statistically
• Scientifically
• Statistically
• Scientifically
8080
Which Scale: My ViewWhich Scale: My View
• Statistically– It doesn’t really matter
• Scientifically– You see what a difference it makes
• Statistically– It doesn’t really matter
• Scientifically– You see what a difference it makes
8181
Spectrum of Stopping RulesSpectrum of Stopping Rules
– Down columns: Early stopping vs no early stopping– Across rows: One-sided vs two-sided decisions
– Down columns: Early stopping vs no early stopping– Across rows: One-sided vs two-sided decisions
8282
Unified Family:Spectrum of Boundary ShapesUnified Family:Spectrum of Boundary Shapes• All of the rules depicted have the same type I
error and power to detect the design alternative• All of the rules depicted have the same type I
error and power to detect the design alternative
8383
Error Spending FunctionsError Spending Functions
• My view: Poorly understood even by the researchers who advocate them– There is no such thing as THE Pocock or O’Brien-
Fleming error spending function• Depends on type I or type II error• Depends on number of analyses• Depends on spacing of analyses
• My view: Poorly understood even by the researchers who advocate them– There is no such thing as THE Pocock or O’Brien-
Fleming error spending function• Depends on type I or type II error• Depends on number of analyses• Depends on spacing of analyses
8484
OBF, Pocock Error SpendingOBF, Pocock Error Spending
8585
Stochastic CurtailmentStochastic Curtailment
• Stopping boundaries chosen based on predicting future data– My objections will be discussed later
• Stopping boundaries chosen based on predicting future data– My objections will be discussed later
8686
Major IssueMajor Issue
• Frequentist operating characteristics are based on the sampling distribution– Stopping rules do affect the sampling distribution of
the usual statistics • MLEs are not normally distributed• Z scores are not standard normal under the null
– (1.96 is irrelevant)
• The null distribution of fixed sample P values is not uniform
– (They are not true P values)
• Frequentist operating characteristics are based on the sampling distribution– Stopping rules do affect the sampling distribution of
the usual statistics • MLEs are not normally distributed• Z scores are not standard normal under the null
– (1.96 is irrelevant)
• The null distribution of fixed sample P values is not uniform
– (They are not true P values)
8787
Sampling Distribution of MLESampling Distribution of MLE
8888
Sampling Distribution of MLESampling Distribution of MLE
8989
Sampling DistributionsSampling Distributions
9090
Sequential Sampling: The PriceSequential Sampling: The Price
• It is only through full knowledge of the sampling plan that we can assess the full complement of frequentist operating characteristics– In order to obtain inference with maximal precision
and minimal bias, the sampling plan must be well quantified
– (Note that adaptive designs using ancillary statistics pose no special problems if we condition on those ancillary statistics.)
• It is only through full knowledge of the sampling plan that we can assess the full complement of frequentist operating characteristics– In order to obtain inference with maximal precision
and minimal bias, the sampling plan must be well quantified
– (Note that adaptive designs using ancillary statistics pose no special problems if we condition on those ancillary statistics.)
9191
Familiarity and ContemptFamiliarity and Contempt
• For any known stopping rule, however, we can compute the correct sampling distribution with specialized software– From the computed sampling distributions we then
compute• Bias adjusted estimates• Correct (adjusted) confidence intervals• Correct (adjusted) P values
– Candidate designs can then be compared with respect to their operating characteristics
• For any known stopping rule, however, we can compute the correct sampling distribution with specialized software– From the computed sampling distributions we then
compute• Bias adjusted estimates• Correct (adjusted) confidence intervals• Correct (adjusted) P values
– Candidate designs can then be compared with respect to their operating characteristics
9292
Inferential MethodsInferential Methods
• Just extensions of methods that also work in fixed samples– But in fixed samples, many methods converge on the
same estimate, unlike in sequential designs
• Just extensions of methods that also work in fixed samples– But in fixed samples, many methods converge on the
same estimate, unlike in sequential designs
9393
Point EstimatesPoint Estimates
– Bias adjusted (Whitehead, 1986)• Assume you observed the mean of the sampling
distribution– Median unbiased (Whitehead, 1983)
• Assume you observed the median of the sampling distribution
– Truncation adapted UMVUE (Emerson & Fleming, 1990)
– (MLE is the naïve estimator: Biased and high MSE)
– Bias adjusted (Whitehead, 1986)• Assume you observed the mean of the sampling
distribution– Median unbiased (Whitehead, 1983)
• Assume you observed the median of the sampling distribution
– Truncation adapted UMVUE (Emerson & Fleming, 1990)
– (MLE is the naïve estimator: Biased and high MSE)
9494
Interval EstimatesInterval Estimates
• Quantile unbiased estimates– Assume you observed the 2.5th or 97.5th percentile
• Orderings of the outcome space– Analysis time or Stagewise
• Tend toward wider CI, but do not need entire sampling distribution
– Sample mean• Tend toward narrower CI
– Likelihood ratio• Tend toward narrower CI, but less implemented
• Quantile unbiased estimates– Assume you observed the 2.5th or 97.5th percentile
• Orderings of the outcome space– Analysis time or Stagewise
• Tend toward wider CI, but do not need entire sampling distribution
– Sample mean• Tend toward narrower CI
– Likelihood ratio• Tend toward narrower CI, but less implemented
9595
P valuesP values
• Orderings of the outcome space– Analysis time ordering
• Lower probability of low p-values• Insensitive to late occurring treatment effects
– Sample mean• High probability of lower p-values
– Likelihood ratio• Highest probability of low p-values
• Orderings of the outcome space– Analysis time ordering
• Lower probability of low p-values• Insensitive to late occurring treatment effects
– Sample mean• High probability of lower p-values
– Likelihood ratio• Highest probability of low p-values
9696
Evaluation of DesignsEvaluation of Designs
9797
Evaluation of DesignsEvaluation of Designs
• Process of choosing a trial design– Define candidate design
• Usually constrain two operating characteristics– Type I error, power at design alternative– Type I error, maximal sample size
– Evaluate other operating characteristics• Different criteria of interest to different investigators
– Modify design– Iterate
• Process of choosing a trial design– Define candidate design
• Usually constrain two operating characteristics– Type I error, power at design alternative– Type I error, maximal sample size
– Evaluate other operating characteristics• Different criteria of interest to different investigators
– Modify design– Iterate
9898
Which Operating CharacteristicsWhich Operating Characteristics
• The same regardless of the type of stopping rule – Frequentist power curve
• Type I error (null) and power (design alternative)– Sample size requirements
• Maximum, average, median, other quantiles• Stopping probabilities
– Inference at study termination (at each boundary)• Frequentist or Bayesian (under spectrum of priors)
– (Futility measures• Conditional power, predictive power)
• The same regardless of the type of stopping rule – Frequentist power curve
• Type I error (null) and power (design alternative)– Sample size requirements
• Maximum, average, median, other quantiles• Stopping probabilities
– Inference at study termination (at each boundary)• Frequentist or Bayesian (under spectrum of priors)
– (Futility measures• Conditional power, predictive power)
9999
At Design StageAt Design Stage
• In particular, at design stage we can know – Conditions under which trial will continue at each
analysis• Estimates
» (Range of estimates leading to continuation)
• Inference» (Credibility of results if trial is stopped)
• Conditional and predictive power
– Tradeoffs between early stopping and loss in unconditional power
• In particular, at design stage we can know – Conditions under which trial will continue at each
analysis• Estimates
» (Range of estimates leading to continuation)
• Inference» (Credibility of results if trial is stopped)
• Conditional and predictive power
– Tradeoffs between early stopping and loss in unconditional power
100100
Case StudyCase Study
• Randomized, placebo controlled Phase III study of antibody to endotoxin
• Intervention: Single administration• Endpoint: Difference in 28 day mortality rates
– Placebo arm: estimate 30% mortality– Treatment arm: hope for 23% mortality
• Analysis: Large sample test of binomial proportions– Frequentist based inference– Type I error: one-sided 0.025– Power: 90% to detect θ < -0.07– Point estimate with low bias, MSE; 95% CI
• Randomized, placebo controlled Phase III study of antibody to endotoxin
• Intervention: Single administration• Endpoint: Difference in 28 day mortality rates
– Placebo arm: estimate 30% mortality– Treatment arm: hope for 23% mortality
• Analysis: Large sample test of binomial proportions– Frequentist based inference– Type I error: one-sided 0.025– Power: 90% to detect θ < -0.07– Point estimate with low bias, MSE; 95% CI
101101
Boundaries and Power Curves Boundaries and Power Curves
• O’Brien-Fleming, Pocock boundary shape functions when J= 4 analyses and maintain power
• O’Brien-Fleming, Pocock boundary shape functions when J= 4 analyses and maintain power
102102
Impact of Interim AnalysesImpact of Interim Analyses
• Required increased maximal sample size in order to maintain power– Maximal sample size with 4 analyses
• O’Brien-Fleming: N= 1773 ( 4.3% increase)• Pocock : N= 2340 (37.6% increase)
– Need to consider• Average sample size• Probability of continuing past 1700 subjects• Conditions under which continue past 1700 subjects
• Required increased maximal sample size in order to maintain power– Maximal sample size with 4 analyses
• O’Brien-Fleming: N= 1773 ( 4.3% increase)• Pocock : N= 2340 (37.6% increase)
– Need to consider• Average sample size• Probability of continuing past 1700 subjects• Conditions under which continue past 1700 subjects
103103
ASN, 75th %tile of Sample SizeASN, 75th %tile of Sample Size
• O’Brien-Fleming, Pocock boundary shape functions;J=4 analyses and maintain power
• O’Brien-Fleming, Pocock boundary shape functions;J=4 analyses and maintain power
104104
Inference (Same Max N)Inference (Same Max N)O'Brien-Fleming Pocock
N MLEBias AdjEstimate 95% CI P val MLE
Bias AdjEstimate 95% CI P val
Efficacy
425 -0.171 -0.163 (-0.224, -0.087) 0.000 -0.099 -0.089 (-0.152, -0.015) 0.010
850 -0.086 -0.080 (-0.130, -0.025) 0.002 -0.070 -0.065 (-0.114, -0.004) 0.018
1275 -0.057 -0.054 (-0.096, -0.007) 0.012 -0.057 -0.055 (-0.101, -0.001) 0.023
1700 -0.043 -0.043 (-0.086, 0.000) 0.025 -0.050 -0.050 (-0.099, 0.000) 0.025
Futility
425 0.086 0.077 (0.001, 0.139) 0.977 0.000 -0.010 (-0.084, 0.053) 0.371
850 0.000 -0.006 (-0.061, 0.044) 0.401 -0.029 -0.035 (-0.095, 0.014) 0.078
1275 -0.029 -0.031 (-0.079, 0.010) 0.067 -0.042 -0.044 (-0.098, 0.002) 0.029
1700 -0.043 -0.043 (-0.086, 0.000) 0.025 -0.050 -0.050 (-0.099, 0.000) 0.025
105105
At Design Stage: ExampleAt Design Stage: Example
• With O’Brien-Fleming boundaries having 90% power to detect a 7% absolute decrease in mortality– Maximum sample size of 1700– Continue past 1275 if crude difference in 28 day
mortality is between -2.9% and -5.7%– If we just barely stop for efficacy after 425 patients we
will report• Estimated difference in mortality: -16.3%• 95% confidence interval: -8.7% to -22.4%• One-sided lower P < 0.0001
• With O’Brien-Fleming boundaries having 90% power to detect a 7% absolute decrease in mortality– Maximum sample size of 1700– Continue past 1275 if crude difference in 28 day
mortality is between -2.9% and -5.7%– If we just barely stop for efficacy after 425 patients we
will report• Estimated difference in mortality: -16.3%• 95% confidence interval: -8.7% to -22.4%• One-sided lower P < 0.0001
106106
Efficiency / Unconditional PowerEfficiency / Unconditional Power
• Futility: Tradeoffs between early stopping and loss of powerBoundaries Loss of Power Avg Sample Size
• Futility: Tradeoffs between early stopping and loss of powerBoundaries Loss of Power Avg Sample Size
107107
Stochastic CurtailmentStochastic Curtailment
• Boundaries transformed to conditional or predictive power– Key issue: Computations are based on assumptions
about the true treatment effect• Conditional power
– “Design”: based on hypotheses– “Estimate”: based on current estimates
• Predictive power– “Prior assumptions”
• Boundaries transformed to conditional or predictive power– Key issue: Computations are based on assumptions
about the true treatment effect• Conditional power
– “Design”: based on hypotheses– “Estimate”: based on current estimates
• Predictive power– “Prior assumptions”
108108
Conditional/Predictive PowerConditional/Predictive Power
Symmetric O’Brien-Fleming O’Brien-Fleming Efficacy, P=0.8 Futility
Conditional Power Predictive Power Conditional Power Predictive Power
N MLE Design Estimate Sponsor Noninf MLE Design Estimate Sponsor Noninf
Efficacy (rejects 0.00) Efficacy (rejects 0.00)
425 -0.171 0.500 0.000 0.002 0.000 -0.170 0.500 0.000 0.002 0.000
850 -0.085 0.500 0.002 0.015 0.023 -0.085 0.500 0.002 0.015 0.023
1275 -0.057 0.500 0.091 0.077 0.124 -0.057 0.500 0.093 0.077 0.126
Futility (rejects -0.0855) Futility (rejects -0.0866)
425 0.085 0.500 0.000 0.077 0.000 0.047 0.719 0.000 0.222 0.008
850 0.000 0.500 0.002 0.143 0.023 -0.010 0.648 0.015 0.247 0.063
1275 -0.028 0.500 0.091 0.241 0.124 -0.031 0.592 0.142 0.312 0.177
109109
So What?So What?
• Why not use stochastic curtailment?– Choice of thresholds poorly understood
• Do not correspond to unconditional power– Inefficient designs result
• Why not use stochastic curtailment?– Choice of thresholds poorly understood
• Do not correspond to unconditional power– Inefficient designs result
110110
111111
112112
Key IssuesKey Issues
• Very different probabilities based on assumptions about the true treatment effect– Extremely conservative O’Brien-Fleming boundaries
correspond to conditional power of 50% (!) under alternative rejected by the boundary
– Resolution of apparent paradox: if the alternative were true, there is less than .003 probability of stopping for futility at the first analysis
• Very different probabilities based on assumptions about the true treatment effect– Extremely conservative O’Brien-Fleming boundaries
correspond to conditional power of 50% (!) under alternative rejected by the boundary
– Resolution of apparent paradox: if the alternative were true, there is less than .003 probability of stopping for futility at the first analysis
113113
Apples with ApplesApples with Apples
• Can compare a group sequential rule to a fixed sample test providing– Same maximal sample size (N= 1700)– Same (worst case) average sample size (N= 1336)– Same power under the alternative (N= 1598)
• Consider probability of “discordant decisions”– Conditional probability (conditional power)– Unconditional probability (power)
• Can compare a group sequential rule to a fixed sample test providing– Same maximal sample size (N= 1700)– Same (worst case) average sample size (N= 1336)– Same power under the alternative (N= 1598)
• Consider probability of “discordant decisions”– Conditional probability (conditional power)– Unconditional probability (power)
114114
115115
Ordering of the Outcome SpaceOrdering of the Outcome Space
• Choosing a threshold based on conditional power can lead to nonsensical orderings based on unconditional power– Decisions based on 19% conditional power may be
more conservative than decisions based on 8% conditional power
– Can result in substantial inefficiency (loss of power)
• Choosing a threshold based on conditional power can lead to nonsensical orderings based on unconditional power– Decisions based on 19% conditional power may be
more conservative than decisions based on 8% conditional power
– Can result in substantial inefficiency (loss of power)
116116
Further CommentsFurther Comments
• Neither conditional power nor predictive power have good foundational motivation– Frequentists should use Neyman-Pearson paradigm
and consider optimal unconditional power across alternatives
• And conditional/predictive power is not a good indicator in loss of unconditional power
– Bayesians should use posterior distributions for decisions
• Neither conditional power nor predictive power have good foundational motivation– Frequentists should use Neyman-Pearson paradigm
and consider optimal unconditional power across alternatives
• And conditional/predictive power is not a good indicator in loss of unconditional power
– Bayesians should use posterior distributions for decisions
117117
ImplementationImplementation
• Methods have been described for flexible implementation of stopping rules when number and timing of analyses is random– Error spending function– Constrained boundaries
• Methods have been described for flexible implementation of stopping rules when number and timing of analyses is random– Error spending function– Constrained boundaries
118118
Adaptive Sampling PlansAdaptive Sampling Plans
119119
Sequential Sampling StrategiesSequential Sampling Strategies
• Two broad categories of sequential sampling– Prespecified stopping guidelines
– Adaptive procedures
• Two broad categories of sequential sampling– Prespecified stopping guidelines
– Adaptive procedures
120120
Adaptive Sampling PlansAdaptive Sampling Plans
• At each interim analysis, possibly modify– Scientific and statistical hypotheses of interest– Statistical criteria for credible evidence– Maximal statistical information– Randomization ratios– Schedule of analyses– Conditions for early stopping
• At each interim analysis, possibly modify– Scientific and statistical hypotheses of interest– Statistical criteria for credible evidence– Maximal statistical information– Randomization ratios– Schedule of analyses– Conditions for early stopping
121121
Adaptive Sampling: ExamplesAdaptive Sampling: Examples
• Prespecified on the scale of statistical information– E.g., Modify sample size to account for estimated
information (variance or baseline rates)
• No effect on type I error IF– Estimated information independent of estimate of
treatment effect» Proportional hazards,» Normal data, and/or» Carefully phrased alternatives
– And willing to use conditional inference» Carefully phrased alternatives
• Prespecified on the scale of statistical information– E.g., Modify sample size to account for estimated
information (variance or baseline rates)
• No effect on type I error IF– Estimated information independent of estimate of
treatment effect» Proportional hazards,» Normal data, and/or» Carefully phrased alternatives
– And willing to use conditional inference» Carefully phrased alternatives
122122
Estimate AlternativeEstimate Alternative
• If maximal sample size is maintained, the study discriminates between null hypothesis and an alternative measured in units of statistical information
• If maximal sample size is maintained, the study discriminates between null hypothesis and an alternative measured in units of statistical information
V
nV
n2
01
21
201
21
)()(
123123
Estimate Sample SizeEstimate Sample Size
• If statistical power is maintained, the study sample size is measured in units of statistical information
• If statistical power is maintained, the study sample size is measured in units of statistical information
201
21
201
21
)()(
V
nVn
124124
Adaptive Sampling: ExamplesAdaptive Sampling: Examples
– E.g., Proschan & Hunsberger (1995)• Modify ultimate sample size based on conditional
power– Computed under current best estimate (if high enough)
• Make adjustment to inference to maintain Type I error
– E.g., Proschan & Hunsberger (1995)• Modify ultimate sample size based on conditional
power– Computed under current best estimate (if high enough)
• Make adjustment to inference to maintain Type I error
125125
Incremental StatisticsIncremental Statistics
• Statistic at the j-th analysis a weighted average of data accrued between analyses
• Statistic at the j-th analysis a weighted average of data accrued between analyses
.
ˆˆ
*
1
**
1
*
j
k
j
kk
jj
k
j
kk
jN
ZNZ
N
N
126126
Conditional DistributionConditional Distribution
.1,0~|
1,/
~|
,~|ˆ
0**
*
0**
***
U
H
NP
NVNNZ
N
VNN
jj
j
jj
jjj
127127
Unconditional DistributionUnconditional Distribution
.Pr|PrPr0
****
n
jjjj nNNzZzZ
128128
Two Stage DesignTwo Stage Design
• Proschan & Hunsberger consider worst case– At first stage, choose sample size of second stage
• N2 = N2(Z1) to maximize type I error
– At second stage, reject if Z2 > a2
• Worst case type I error of two stage design
– Can be more than two times the nominal
• a2 = 1.96 gives type I error of 0.0616
• (Compare to Bonferroni results)
• Proschan & Hunsberger consider worst case– At first stage, choose sample size of second stage
• N2 = N2(Z1) to maximize type I error
– At second stage, reject if Z2 > a2
• Worst case type I error of two stage design
– Can be more than two times the nominal
• a2 = 1.96 gives type I error of 0.0616
• (Compare to Bonferroni results)
,
4
2/exp1
2)(2)(
2
ZZ
worst
aa
129129
Better ApproachesBetter Approaches
• Proschan and Hunsberger describe adaptations using restricted procedures to maintain experimentwise type I error– Must prespecify a conditional error function which
would maintain type I error
• Then find appropriate a2 for second stage based on N2 which can be chosen arbitrarily
– But still have loss of power
• Proschan and Hunsberger describe adaptations using restricted procedures to maintain experimentwise type I error– Must prespecify a conditional error function which
would maintain type I error
• Then find appropriate a2 for second stage based on N2 which can be chosen arbitrarily
– But still have loss of power
130130
Motivation for Adaptive DesignsMotivation for Adaptive Designs
• Scientific and statistical hypotheses of interest– Modify target population, intervention, measurement of
outcome, alternative hypotheses of interest– Possible justification
• Changing conditions in medical environment– Approval/withdrawal of competing/ancillary treatments– Diagnostic procedures
• New knowledge from other trials about similar treatments
• Evidence from ongoing trial– Toxicity profile (therapeutic index)– Subgroup effects
• Scientific and statistical hypotheses of interest– Modify target population, intervention, measurement of
outcome, alternative hypotheses of interest– Possible justification
• Changing conditions in medical environment– Approval/withdrawal of competing/ancillary treatments– Diagnostic procedures
• New knowledge from other trials about similar treatments
• Evidence from ongoing trial– Toxicity profile (therapeutic index)– Subgroup effects
131131
Motivation for Adaptive DesignsMotivation for Adaptive Designs
• Modification of other design parameters may have great impact on the hypotheses considered– Statistical criteria for credible evidence– Maximal statistical information– Randomization ratios– Schedule of analyses– Conditions for early stopping
• Modification of other design parameters may have great impact on the hypotheses considered– Statistical criteria for credible evidence– Maximal statistical information– Randomization ratios– Schedule of analyses– Conditions for early stopping
132132
Cost of Planning Not to PlanCost of Planning Not to Plan
• Major issues with use of adaptive designs– What do we truly gain?
• Can proper evaluation of trial designs obviate need?
– What can we lose?• Efficiency? (and how should it be measured?)• Scientific inference?
– Science vs Statistics vs Game theory – Definition of scientific/statistical hypotheses– Quantifying precision of inference
• Major issues with use of adaptive designs– What do we truly gain?
• Can proper evaluation of trial designs obviate need?
– What can we lose?• Efficiency? (and how should it be measured?)• Scientific inference?
– Science vs Statistics vs Game theory – Definition of scientific/statistical hypotheses– Quantifying precision of inference
133133
Prespecified Modification RulesPrespecified Modification Rules
• Adaptive sampling plans exact a price in statistical efficiency– Tsiatis & Mehta (2002)
• A classic prespecified group sequential stopping rule can be found that is more efficient than a given adaptive design
– Shi & Emerson (2003)• Fisher’s test statistic in the self-designing trial
provides markedly less precise inference than that based on the MLE
– To compute the sampling distribution of the latter, the sampling plan must be known
• Adaptive sampling plans exact a price in statistical efficiency– Tsiatis & Mehta (2002)
• A classic prespecified group sequential stopping rule can be found that is more efficient than a given adaptive design
– Shi & Emerson (2003)• Fisher’s test statistic in the self-designing trial
provides markedly less precise inference than that based on the MLE
– To compute the sampling distribution of the latter, the sampling plan must be known
134134
Conditional/Predictive PowerConditional/Predictive Power
• Additional issues with maintaining conditional or predictive power– Modification of sample size may allow precise
knowledge of interim treatment effect• Interim estimates may cause change in study
population– Time trends due to investigators gaining or losing
enthusiasm
• In extreme cases, potential for unblinding of individual patients
– Effect of outliers on test statistics
• Additional issues with maintaining conditional or predictive power– Modification of sample size may allow precise
knowledge of interim treatment effect• Interim estimates may cause change in study
population– Time trends due to investigators gaining or losing
enthusiasm
• In extreme cases, potential for unblinding of individual patients
– Effect of outliers on test statistics
135135
Final CommentsFinal Comments
• Adaptive designs versus prespecified stopping rules– Adaptive designs come at a price of efficiency and
(sometimes) scientific interpretation
– With adequate tools for careful evaluation of designs, there is little need for adaptive designs
• Adaptive designs versus prespecified stopping rules– Adaptive designs come at a price of efficiency and
(sometimes) scientific interpretation
– With adequate tools for careful evaluation of designs, there is little need for adaptive designs
136136
Bottom LineBottom Line
You better think (think)
about what you’re
trying to do…
-Aretha Franklin
You better think (think)
about what you’re
trying to do…
-Aretha Franklin
137137
ReferencesReferences
• Available on www.emersonstatistics.com– Frequentist evaluation– Bayesian evaluation (Stat Med)– On the use of stochastic curtailment– Issues in the use of adaptive designs (Stat Med)– Group sequential P values under non-proportional
hazards (Biometrics)– Implementation of group sequential rules using
constrained boundaries (Biometrics)