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Introduction to Costeffectiveness Analysis

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Derive the statistics on the bootstrap sample (e.g. mean, ICER) ... Derive the mean ( b) and standard deviation (sb) from the. 1000 ICERs. b = Si(ICERbi) / 1000, ... – PowerPoint PPT presentation

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Title: Introduction to Costeffectiveness Analysis


1
Introduction to Cost-effectiveness Analysis
  • Ming-Yu Fan, PhD
  • January 30, 2008

2
Outline
  • Increasing interest in C-E analysis
  • Incremental Cost-Effectiveness Ratio (ICER)
  • Methods for constructing confidence intervals
  • A simulation study

3
Increasing interest in CEA
  • On PubMed, the keyword cost-effectiveness
  • retrieves 49710 citations
  • The keyword cost-effectiveness ratio retrieves
  • 3193 citations
  • 1080 publications using incremental cost-
  • effectiveness ratio
  • () These numbers were obtained on 1/28/08. On
    1/30/08, they are 49734, 3195, and 1082

4
Measures for cost-effectiveness
  • Incremental Cost-Effectiveness Ratio (ICER)
  • ICER (C1 - C2) / (E1 - E2)
  • (C1, E1) (cost, effect) in the
    intervention/treatment group
  • (C2, E2) (cost, effect) in the control/usual
    care group
  • Net Health Benefits (NHB)
  • NHB E C/?
  • ? a rate of substitution of dollars for health
  • INHB(?) NHB1(?) - NHB2(?)

5
ICER C-E plane
  • ICER (C1 - C2) / (E1 - E2) ?C / ?E

6
ICER cont.
  • Best scenario Quadrant IV ? intervention is
    effective and cost-saving
  • Worst scenario Quadrant II ? intervention is
    worse than usual care and costs more
  • Most common scenario Quadrant I ? intervention
    is more effective than usual care and costs more

7
Methodological challenge
  • Notation
  • µC E(?C), µE E(?E)
  • VC Var(?C), VE Var(?E)
  • Cov Covariance(?C, ?E)
  • Expected value (mean) of a ratio does not have a
    close form
  • E(?C/?E) E(?C) / E(?E) µC/µE
  • Variance of a ratio does not have a close form
  • Var(?C/?E)
  • Both approximations are based on Taylors
    expansion

8
Methodological challenge cont.
  • Conventional 95 confidence interval
  • (mean - 1.96se), (mean 1.96se)
  • Normal distribution or large sample size
  • Good estimation of mean and variance
  • ICER
  • Ratio is heavily skewed
  • Only approximated estimations of mean and
    variance are available

9
Alternative confidence intervals
  • Bootstrap methods
  • Fiellers method
  • Many simulation studies have shown that these two
    (especially Fiellers method) yield best results

10
Bootstrap procedure
  • Sample the data With Replacement until the same
    sample size is reached
  • Derive the statistics on the bootstrap sample
    (e.g. mean, ICER)
  • Repeat the procedure for many times (e.g. 1000)
  • Construct the confidence interval based on the
    statistics (e.g. using the 1000 ICERs)

11
Bootstrap - example
  • Original sample
  • DFD depression-free-days
  • Intervention
  • N 6
  • Mean DFD / year 190
  • Mean costs / year 8000
  • Usual Care
  • N 4
  • Mean DFD / year 130
  • Mean costs / year 7700
  • ICER
  • (8000-7700)/(190-130)
  • 5

12
Bootstrap sample 1
  • Bootstrapping IV and UC samples separately
  • Intervention
  • N 6
  • Mean DFD 193
  • Mean costs 8083
  • Usual Care
  • N 4
  • Mean DFD 120
  • Mean costs 7475
  • ICER
  • (8083-7475)/(193-120)
  • 8.3

13
Bootstrap sample 2
  • Bootstrapping IV/UC samples separately
  • Intervention
  • N 6
  • Mean DFD 183
  • Mean costs 7833
  • Usual Care
  • N 4
  • Mean DFD 140
  • Mean costs 7925
  • ICER
  • (7833-7925)/(183-140)
  • -2.1

14
Bootstrap example cont.
  • Total number of possible bootstrap samples
  • (66)(44) (46656)(256) 11,943,936
  • Total number of unique means/variances
  • 46235 16,170
  • Repeat the same bootstrapping procedure for 1000
    times, we
  • will obtain 1000 ICERs
  • These 1000 ICERs provide an approximate
    distribution of the
  • estimated ICER
  • We can make statistical inferences about the
    estimated ICER
  • using this approximate distribution

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16
Bootstrap methods
  • Percentile
  • Order the 1000 ICERs (from small to large)
  • Take the 25th and the 976th ICERs
  • The 95 confidence interval ICERb25, ICERb976
  • Normal
  • Derive the mean (µb) and standard deviation (sb)
    from the
  • 1000 ICERs
  • µb Si(ICERbi) / 1000,
  • (sb)2 Si(ICERbi - µb)2 / (1000-1)
  • The 95 confidence interval
  • (µb - 1.96sb), (µb 1.96sb)

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Bootstrap methods cont.
  • Bootstrap-t
  • Generate a t-statistic (tb (ICERb ICERs)/seb)
    within each bootstrap sample then follow the
    percentile method using the t-statistics
  • Better than the percentile method because the
    distribution of t-statistic is closer to a normal
    distribution than the distribution of ICERb
  • If the estimation of s.e. is biased, bootstrap-t
    might have worse coverage rate than
    bootstrap-percentile method
  • Bias-corrected accelerated (BCa)
  • Instead of (a/2) and (1-a/2) (e.g. 0.025 and
    0.975 for a 0.05), using a1 and a2 to get the
    percentiles
  • a1 and a2 are functions of bias-corrections and
    accelerated scalars

19
Katon et al. Arch Gen Psych. 2005
20
More about bootstrap
  • Why use bootstrap?
  • No need to assume the distribution family of the
    data
  • With todays computing power, bootstrap can be
    done
  • very easily and quickly
  • Good asymptotic properties
  • Commonly chosen number of repetitions 1000
  • The distribution of the bootstrap samples depends
    on the original sample size, not so much on the
    number of repetitions

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26
Other bootstrap procedure
  • Parametric procedure (e.g. assume a normal
    distribution)
  • Weighted bootstrap assigning different weights
    to different observations
  • Ex smaller weight for outliers
  • Bayesian approach

27
Fiellers method
  • Ratio is difficult to model
  • Mean and variance do not have a close form
  • Distribution is very skewed
  • Fieller suggested to transform the ICER into a
    linear variable
  • ICER R ?C / ?E
  • New statistic S ?C ?ER
  • The mean and variance of (?C ?ER) are very
    easy to derive

28
Fiellers method cont.
  • Notation
  • Mean of (?C ?ER) µs µ?C - µ?ER
  • Standard deviation of (?C ?ER) ss
  • By Central Limit Theorem
  • (?C ?ER) µs / ss is normally distributed
  • The 95 confidence interval for the statistic can
    be derived by

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Fiellers method cont.
  • With simple algebra, the inequality can be
    re-written as
  • aR2 bR c 0
  • where
  • a (?E)2 1.962 s2?E
  • b 2 ?E ?C 1.962 s?E?c
  • c (?C)2 1.962 s2?c
  • The upper and lower limits of the 95 confidence
    interval for
  • R (ICER) are the 2 boundaries that satisfy the
    inequality
  • The left hand side of the inequality represents a
    parabola

31
Fiellers method - example
32
Fiellers method - complications
  • aR2 bR c 0
  • 4 scenarios (and their solutions for R)
  • (1) a 0, (b2 4ac) 0 ? a close interval
  • (2) a lt 0, (b2 4ac) 0 ? an open interval
  • (3) a 0, (b2 4ac) lt 0 ? an empty set
  • (4) a lt 0, (b2 4ac) lt 0 ? the whole real line

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34
Fiellers method cont.
  • Why use Fiellers method
  • Several simulation studies have demonstrated that
    Fiellers
  • method yield better results than other method
  • Easy to compute
  • Unique results of the same data (contrast to
    bootstrap)
  • When does Fiellers method result in meaningless
  • confidence intervals?
  • Scenario (3) where a gt 0 and (b2 4ac) lt 0
    never happens
  • When a 0, the confidence interval is a closed
    interval

35
Fiellers method cont.
  • Whats the interpretation for a 0?
  • a (?E)2 1.962 s2?E 0
  • ? (?E/s?E )2 1.962
  • ? the incremental effect is statistically
    significant
  • When the incremental effect is not statistically
  • significant, it is not interesting clinical-wise
    to conduct cost-
  • effectiveness analysis. Statistically, it is
    appropriate to run analysis
  • using ICER and make inferences based on it

36
A simulation study
  • 3 distribution families
  • (1) Both effect and cost follow a normal
    distribution
  • (2) Both effect and cost follow a log-normal
    distribution
  • (right skewed)
  • (3) Effect ? normal Cost ? log-normal
  • For each distribution family, 162 different
    distributions
  • Sample size 50, 100, 400
  • Correlation coefficient between cost and effect
    -0.5, 0.1, 0.5
  • Ratio of the variances (control / intervention)
    1, 3
  • ICER 2000, 10000, 50000
  • 3 distances between the ICER and the origin
  • (relevant to the effect size)

37
Distance between ICER and origin
  • A and B have the same ICER

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40
Problem with ICER
  • Cant distinguish ICERs on quadrant I from
    quadrant III
  • Quadrant I positive intervention effect, more
    costly
  • Quadrant III negative intervention effect, cost
    saving
  • Cant distinguish ICERs on quadrant II from
    quadrant IV
  • Quadrant II negative intervention effect, more
    costly
  • Quadrant IV positive intervention effect, cost
    saving
  • Negative ICERs are difficult to interpret

41
Problem with ICER cont.
  • Example 3 studies comparing to the same control
    group
  • A ?E 10, ?C -1000
  • B ?E 10, ?C -500
  • C ?E 5, ?C -500
  • Pair-wise comparison
  • A is better than B (same effect, more
    cost-saving)
  • B is better than C (same cost-saving, more
    effective)
  • ? A gt B gt C
  • ICER
  • (A) ICER -100 (B) ICER -50 (C) ICER
    -100
  • ? A C gt B

42
Summary
  • ICER is an intuitive measure for
    cost-effectiveness analysis
  • but is only appropriate when
  • The incremental effect is statistically
    significant from 0
  • Both incremental effect and incremental cost are
    positive
  • The available methods might not be appropriate
    for other
  • scenarios
  • With large samples, normal method,
    bootstrap-percentile
  • method, and Fiellers method are all equally
    good
  • For small samples (or extremely skewed costs), my
  • preference is (1) Fiellers method (2)
    bootstrap-percentile (3)
  • normal method

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