Applying Bayesian evidence synthesis in comparative effectiveness research
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Applying Bayesian evidence synthesis in comparative effectiveness research
David Ohlssen (Novartis Pharmaceticals Corporation)
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Overview
Part 1 Bayesian DIA CER sub-team
Part 2 Overview of Bayesian evidence synthesis
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Part 1 Bayesian DIA CER sub-team
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Team Members
Chair: David Ohlssen
Co-chair: Haijun Ma
Other team members:• Fanni Natanegara, George Quartey, Mark Boye, Ram Tiwari, Yu
Chang
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Problem Statement
Comparative effectiveness research (CER) is designed to inform health-care decisions by providing evidence on the effectiveness, benefits, and harms of different treatment options
Timely research and dissemination of CER results to be used by clinicians, patients, policymakers, and health plans and other payers to make informed decisions at both the individual and population levels
Bayesian approaches provide a natural framework for combining information from a variety of sources in comparative effectiveness research
• Rapid technical development as evident by a recent flurry of publications
Limited understanding on how Bayesian techniques should be applied in practice
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Objectives
Encourage the appropriate application of Bayesian approaches to the problem of comparative effectiveness.
Input into ongoing initiatives on comparative effectiveness within medical products development setting through white papers/publications and session at future meetings
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Project Scope
Analysis of patient benefit risk using existing data
Initially focused on
1) The use of Bayesian evidence synthesis techniques such as mixed treatment comparisons
2) Joint Modeling in benefit risk assessment
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Current aims for 2012
Literature review of Bayesian methods in CER – Q4 2012
To gain an understanding and appreciation of other CER working groups – Q4 2012• Decide on the list of CER working groups to contact
• Understand the objectives, status of each group
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Part 2 Overview of Bayesian evidence synthesis
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Introduction Evidence synthesis in drug development
The ideas and principles behind evidence synthesis date back to the work of Eddy et al; 1992
However, wide spread application has been driven by the need for quantitative health technology assessment:• cost effectiveness
• comparitive effectiveness
Ideas often closely linked with Bayesian principles and methods:• Good decision making should ideally be based on all relevant
information
• MCMC computation
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Recent developments in comparative effectiveness
Health agencies have increasing become interested in health technology assessment and the comparative effectiveness of various treatment options
Statistical approaches include extensions of standard meta-analysis models allowing multiple treatments to be compared
FDA Partnership in Applied Comparative Effectiveness Science (PACES) -including projects on utilizing historical data in clinical trials and subgroup analysis
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Aims of this talkEvidence synthesis
Introduce some basic concepts Illustration through a series of applications:
• Motivating public health example
• Network meta-analysis
• Using historical data in the design and analysis of clinical trials
• Subgroup analysis
Focus on principles and understanding of critical assumptions rather than technical details
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Basic conceptsFramework and Notation for evidence synthesis
Y1 Y2 YS Y1,..,YS Data from S sources
1,…, SSource-specific parameters/effects of interest(e.g. a mean difference)
Question related to 1,…, S
(e.g. average effect, or effect in a new study)
1
2
S?
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Strategies for HIV screening
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Ades and Cliffe (2002)
HIV: synthesizing evidence from multiple sources
Aim to compare strategies for screening for HIV in pre-natal clinics:• Universal screening of all women,
• or targeted screening of current injecting drug users (IDU) or women born in sub-Saharan Africa (SSA)
Use synthesis to determine the optimal policy
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Key parametersAdes and Cliffe (2002)
a- Proportion of women born in sub-Saharan Africa (SSA)
b Proportion of women who are intravenous drug users (IDU)
c HIV infection rate in SSA
d HIV infection rate in IDU
e HIV infection rate in non-SSA, non-IDU
f Proportion HIV already diagnosed in SSA
g Proportion HIV already diagnosed in IDU
h Proportion HIV already diagnosed in non-SSA, non-IDU
NO direct evidence concerning e and h!
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A subset of some of the data used in the synthesisAdes and Cliffe (2002)
HIV prevalence, women not born in SSA,1997-8
[db + e(1 − a − b)]/(1 − a) 74 / 136139
Overall HIV prevalence in pregnant women, 1999
ca + db + e(1 − a − b) 254 / 102287
Diagnosed HIV in SSA women as a proportion of all diagnosed HIV, 1999
fca/[fca + gdb + he(1 − a − b)] 43 / 60
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Implementation of the evidence synthesisAdes and Cliffe (2002)
The evidence was synthesized by placing all data sources within a single Bayesian model
Easy to code in WinBUGS
Key assumption – consistency of evidence across the different data sources
Can be checked by comparing direct and indirect evidence at various “nodes” in the graphical model (Conflict p-value)
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Network meta-analysis
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Motivation for Network Meta-Analysis
There are often many treatments for health conditions
Published systematic reviews and meta-analyses typically focus on pair-wise comparisons• More than 20 separate Cochrane reviews for adult smoking
cessation
• More than 20 separate Cochrane reviews for chronic asthma in adults
An alternative approach would involve extending the standard meta-analysis techniques to accommodate multiple treatment
This emerging field has been described as both network meta-analysis and mixed treatment comparisons
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Network meta-analysis graphic
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A
B
C
D
E
F
G
H
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Network meta-analysis – key assumptions
Three key assumptions (Song et al., 2009):
Homogeneity assumption – Studies in the network MA which compare the same treatments must be sufficiently similar.
Similarity assumption – When comparing A and C indirectly via B, the patient populations of the trial(s) investigating A vs B and those investigating B vs C must be sufficiently similar.
Consistency assumption – direct and indirect comparisons, when done separately, must be roughly in agreement.
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Example 2 Network meta-analysisTrelle et al (2011) - Cardiovascular safety of non-steroidal anti-inflammatory drugs:
Primary Endpoint was myocardial infarction
Data synthesis 31 trials in 116 429 patients with more than 115 000 patient years of follow-up were included.
A Network random effects meta-analysis were used in the analysis
Critical aspect – the assumptions regarding the consistency of evidence across the network
How reasonable is it to rank and compare treatments with this technique?
placebo
Lumiracoxib
Ibuprofen
Celecoxib
naproxen
rofecoxib
Diclofenac
Etoricoxib
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Results from Trelle et alMyocardial infarction analysis
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Treatment RR estimate lower limit upper limitCelecoxib 1.35 0.71 2.72Diclofenac 0.82 0.29 2.20Etoricoxib 0.75 0.23 2.39Ibuprofen 1.61 0.50 5.77
Lumiracoxib 2.00 0.71 6.21Naproxen 0.82 0.37 1.67Rofecoxib 2.12 1.26 3.56
Authors' conclusion: Although uncertainty remains, little evidence exists to suggest that any of the investigated drugs are safe in cardiovascular terms. Naproxen seemed least harmful.
Relative risk with 95% confidence interval compared to placebo
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Comments on Trelle et al
Drug doses could not be considered (data not available).
Average duration of exposure was different for different trials.
Therefore, ranking of treatments relies on the strong assumption that the risk ratio is constant across time for all treatments
The authors conducted extensive sensitivity analysis and the results appeared to be robust
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Additional Example Using Network meta-analysis for Phase IIIB Probability of success in a pricing trial
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placebo
Combination product
A
C
B
D
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Use of Historical controls
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IntroductionObjective and Problem Statement
Design a study with a control arm / treatment arm(s)
Use historical control data in design and analysis
Ideally: smaller trial comparable to a standard trial
Used in some of Novartis phase I and II trials
Design options
• Standard Design: “n vs. n”
• New Design: “n*+(n-n*) vs. n” with n* = “prior sample size”
How can the historical information be quantified?
How much is it worth?
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The Meta-Analytic-Predictive ApproachFramework and Notation
Y1 Y2 YH
Y1,..,YH Historical control data from H trials
1,…, H
Control “effects” (unknown)
?‘Relationship/Similarity’ (unknown)no relation… same effects
*Effect in new trial (unknown)Design objective: [ * | Y1,…,YH ]
Y*Data in new study(yet to be observed)
1
2
H?
*
Y*
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Example – meta-analytic predictive approach to form priors Application
prior information for control group in new study, corresponding to prior sample size n*
Random-effect meta-analysis
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Bayesian setup-using historical control data
Meta Analysis of Historical Data Study Analysis
Observed Control Response Rates
Historical Trial 1
Historical Trial 2
Historical Trial 3
Historical Trial 4
Historical Trial 5
Historical Trial 6
Historical Trial 7
Historical Trial 8
Meta-Analysis
Predictive Distribution of Control Response Rate in a
New Study
Bayesian Analysis
Observed Control
data
Observed Drugdata
Prior Distribution of Control Response
Rate
Prior Distribution
of drug response
rate
Placebo Drug
Posterior Distribution of Difference in Response
Posterior Distribution of Control Response Rate
Posterior Distribution of Drug Response Rate
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Utilization in a quick kill quick win PoC Design
With pPlacebo = 0.15, 10000 runs
Scenario
First interim Second interim Final Overall power
Stop for efficacy
Stop for futility
Stop for efficacy
Stop for futility
Claim efficacy
Fail
d = 0 1.6% 49.0% 1.4% 26.0% 0.2% 21.9% 3.2%
d = 0.2 33.9% 5.1% 27.7% 3.0% 8.8% 21.6% 70.4%
d = 0.5 96.0% 0.0% 4.0% 0.0% 0.0% 0.0% 100.0%
1st Interim
... ≥ 90%
2nd Interim
... ≥ 90%
Final analysis
... > 50%
Negative PoC if P(d < 0.2)...
... ≥ 70% ... ≥ 50% ... ≥ 50%Positive PoC if
P(d ≥ 0.2)...
With N=60, 2:1 Active:Placebo, IA’s after 20 and 40 patients
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R package available for design investigation
33 | Evidence synthesis in drug development
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Subgroup Analysis
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Introduction to Subgroup analysis
For biological reasons treatments may be more effective in some populations of patients than others• Risk factors
• Genetic factors
• Demographic factors
This motivates interest in statistical methods that can explore and identify potential subgroups of interest
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Challenges with exploratory subgroup analysisrandom high bias - Fleming 2010
Hazard Ratio Risk of Mortality
Analysis North Central Intergroup Group Treatment Study Group Study # 0035 (n = 162) (n = 619)
All patients 0.72 0.67
Female 0.57 0.85Male 0.91 0.50
Young 0.60 0.77Old 0.87 0.59
Effects of 5-Fluorouracil Plus Levamisole on PatientSurvival Presented Overall and Within Subgroups, by Sex and Age*
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Assumptions to deal with extremesJones et al (2011)
Similar methods to those used when combining historical data
However, the focus is on the individual subgroup parameters 1,......,G rather than the prediction of a new subgroup
1) Unrelated Parameters 1,......,G (u) Assumes a different treatment effect in each subgroup
2) Equal Parameters 1=...= G (c)
Assumes the same treatment effect in each subgroup
3) Compromise. Effects are similar/related to a certain degree (r)
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Comments on shrinkage estimation
This type of approach is sometimes called shrinkage estimation
Shrinkage estimation attempts to adjust for random high bias
When relating subgroups, it is often desirable and logical to use structures that allow greater similarity between some subgroups than others
A variety of possible subgroup structures can be examined to assess robustness
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Subgroup analysis– Extension to multiple studies Data summary from several studies
• Subgroup analysis in a meta-analytic context
• Efficacy comparison T vs. C
• Data from 7 studies
• 8 subgroups
• defined by 3 binary base-line covariates A, B, C
• A, B, C high (+) or low (-)
• describing burden of disease (BOD)
• Idea: patients with higher BOD at baseline might show better efficacy
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Graphical model Subgroup analysis involving several studies
1
2
G?
12 S
?Y1
Y2
YS
Y...
Y1,..,YS Data from S studies
Subgroup parameters1,…, G
• Main parameters of interest• Various modeling structures can be examined
Study-specific parameters1,…, S
• Parameters allow data to be combined from multiple studies
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Extension to multiple studiesExample 3: sensitivity analyses across a range of subgroup structures
41 | Evidence synthesis in drug development
• 8 subgroups
• defined by 3 binary base-line covariates A, B, C
• A, B, C high (+) or low (-)
• describing burden of disease (BOD)
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SummarySubgroup analysis
Important to distinguish between exploratory subgroup analysis and confirmatory subgroup analysis
Exploratory subgroup analysis can be misleading due to random high bias
Evidence synthesis techniques that account for similarity among subgroups will help adjust for random high bias
Examine a range of subgroup models to assess the robustness of any conclusions
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Conclusions
• There is general agreement that good decision making should be based on all relevant information
• However, this is not easy to do in a formal/quantitative way
• Evidence synthesis
- offers fairly well-developed methodologies
- has many areas of application
- is particularly useful for company-internal decision making (we have used and will increasingly use evidence synthesis in our phase I and II trials)
- has become an important tool when making public health policy decisions
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44 | Combining Information in Drug Development 2010
References
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Evidence Synthesis/Meta-Analysis
DerSimonian, Laird (1986). Meta-analysis in clinical trials. Controlled Clinical Trials, 7; 177-88
Gould (1991). Using prior findings to augment active-controlled trials and trials with small placebo groups. Drug Information J. 25 369--380.
Normand (1999). Meta-analysis: formulating, evaluating, combining, and reporting (Tutorial in Biostatistics). Statistics in Medicine 18: 321-359.See also Letters to the Editor by Carlin (2000) 19: 753-59, and Stijnen (2000) 19:759-761
Spiegelhalter et al. (2004); see main referenceStangl, Berry (eds) (2000). Meta-analysis in Medicine in Health Policy. Marcel DekkerSutton, Abrams, Jones, Sheldon, Song (2000). Methods for Meta-analysis in Medical
Research. John Wiley & Sons
Trelle et al., “Cardiovascular safety of non-steroidal anti-inflammatory drugs: network non-steroidal anti-inflammatory drugs: network meta-analysis,” BMJ 342 (January 11, 2011): c7086-c7086.
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Historical Controls
Ibrahim, Chen (2000). Power prior distributions for regression models.Statistical Science, 15: 46-60
Neuenschwander, Branson, Spiegelhalter (2009). A note on the power prior. Statistics in Medicine, 28: 3562-3566
Neuenschwander, Capkun-Niggli, Branson, Spiegelhalter. (2010). SummarizingHistorical Information on Controls in Clinical Trials. Clinical Trials, 7: 5-18
Pocock (1976). The combination of randomized and historical controls in clinical trials. Journal of Chronic Diseases, 29: 175-88
Spiegelhalter et al. (2004); see main reference
Thall, Simon (1990). Incorporating historical control data in planning phase II studies. Statistics in Medicine, 9: 215-28
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Subgroup AnalysesBerry, Berry (2004). Accounting for multiplicities in assessing drug safety:
a three-level hierarchical mixture model. Biometrics, 60: 418-26
Davis, Leffingwell (1990). Empirical Bayes estimates of subgroup effects in clinical trial. Controlled Clinical Trials, 11: 37-42
Dixon, Simon (1991). Bayesian subgroup analysis. Biometrics, 47: 871-81
Fleming (2010), “Clinical Trials: Discerning Hype From Substance,” Annals of Internal Medicine 153:400 -406.
Hodges, Cui, Sargent, Carlin (2007). Smoothing balanced single-error terms Analysis of Variance. Technometrics, 49: 12-25
Jones, Ohlssen, Neuenschwander, Racine, Branson (2011). Bayesian models for subgroup analysis in clinical trials. Clinical Trials Clinical Trials 8 129 -143
Louis (1984). Estimating a population of parameter values using Bayes and empirical Bayes methods. JASA, 79: 393-98
Pocock, Assman, Enos, Kasten (2002). Subgroup analysis, covariate adjustment and baseline comparisons in clinical trial reporting: current practic eand problems. Statistics in Medicine, 21: 2917–2930
Spiegelhalter et al. (2004); see main reference
Thall, Wathen, Bekele, Champlin, Baker, Benjamin (2003). Hierarchical Bayesian approaches to phase II trials in diseases with multiple subtypes, Statistics in Medicine, 22: 763-80
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Poisson network meta-analysis model
Model extension to K treatments : Lu, Ades (2004). Combination of direct and indirect evidence in mixed treatment comparisons, Statistics in Medicine, 23:3105-
3124.
Different choices for µ’s and ’s. They can be:
• common (over studies), fixed (unconstrained), or “random”
• Note: random ’s (K-1)-dimensional random effects distribution
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Acknowledgements
Stuart Bailey ,Björn Bornkamp, Beat Neuenschwander, Heinz Schmidli, Min Wu, Andrew Wright