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Meta-analysis with cluster-robust variance estimation

James E. Pustejovsky

2024-06-20

This vignette demonstrates how to use the clubSandwich package to conduct a meta-analysis of dependent effect sizes with robust variance estimation. Tests of meta-regression coefficients and F-tests of multiple-coefficient hypotheses are calculated using small-sample corrections proposed by Tipton (2015) and Tipton and Pustejovsky (2015). The example uses a dataset of effect sizes from a Campbell Collaboration systematic review of dropout prevention programs, conducted by Sandra Jo Wilson and colleagues (2011).

The original analysis included a meta-regression with covariates that capture methodological, participant, and program characteristics. The regression specification used here is similar to Model III from Wilson et al. (2011), but treats the evaluator_independence and implementation_quality variables as categorical rather than interval-level. Also, the original analysis clustered at the level of the sample (some studies reported results from multiple samples), whereas here we cluster at the study level. The meta-regression can be fit in several different ways. We first demonstrate using the robumeta package (Fisher & Tipton, 2015) and then using the metafor package (Viechtbauer, 2010).

robumeta model

library(clubSandwich)
library(robumeta)
data(dropoutPrevention)

# clean formatting
names(dropoutPrevention)[7:8] <- c("eval","implement")
levels(dropoutPrevention$eval) <- c("independent","indirect","planning","delivery")
levels(dropoutPrevention$implement) <- c("low","medium","high")
levels(dropoutPrevention$program_site) <- c("community","mixed","classroom","school")
levels(dropoutPrevention$study_design) <- c("matched","unmatched","RCT")
levels(dropoutPrevention$adjusted) <- c("no","yes")

m3_robu <- robu(LOR1 ~ study_design + attrition + group_equivalence + adjusted
                + outcome + eval + male_pct + white_pct + average_age
                + implement + program_site + duration + service_hrs, 
                data = dropoutPrevention, studynum = studyID, var.eff.size = varLOR, 
                modelweights = "HIER")
print(m3_robu)
## RVE: Hierarchical Effects Model with Small-Sample Corrections 
## 
## Model: LOR1 ~ study_design + attrition + group_equivalence + adjusted + outcome + eval + male_pct + white_pct + average_age + implement + program_site + duration + service_hrs 
## 
## Number of clusters = 152 
## Number of outcomes = 385 (min = 1 , mean = 2.53 , median = 1 , max = 30 )
## Omega.sq = 0.24907 
## Tau.sq = 0.1024663 
## 
##                           Estimate   StdErr t-value  dfs    P(|t|>) 95% CI.L 95% CI.U Sig
## 1           X.Intercept.  0.016899 0.615399  0.0275 16.9 0.97841541 -1.28228  1.31608    
## 2  study_designunmatched -0.002626 0.185142 -0.0142 40.5 0.98875129 -0.37667  0.37141    
## 3        study_designRCT -0.086872 0.140044 -0.6203 38.6 0.53869676 -0.37024  0.19650    
## 4              attrition  0.118889 0.247228  0.4809 15.5 0.63732597 -0.40666  0.64444    
## 5      group_equivalence  0.502463 0.195838  2.5657 28.7 0.01579282  0.10174  0.90318  **
## 6            adjustedyes -0.322480 0.125413 -2.5713 33.8 0.01470796 -0.57741 -0.06755  **
## 7        outcomeenrolled  0.097059 0.139842  0.6941 16.5 0.49727848 -0.19862  0.39274    
## 8      outcomegraduation  0.147643 0.134938  1.0942 30.2 0.28253825 -0.12786  0.42315    
## 9  outcomegraduation.ged  0.258034 0.169134  1.5256 16.3 0.14632629 -0.10006  0.61613    
## 10          evalindirect -0.765085 0.399109 -1.9170  6.2 0.10212896 -1.73406  0.20389    
## 11          evalplanning -0.920874 0.346536 -2.6574  5.6 0.04027061 -1.78381 -0.05794  **
## 12          evaldelivery -0.916673 0.304303 -3.0124  4.7 0.03212299 -1.71432 -0.11903  **
## 13              male_pct  0.167965 0.181538  0.9252 16.4 0.36824526 -0.21609  0.55202    
## 14             white_pct  0.022915 0.149394  0.1534 21.8 0.87950385 -0.28704  0.33287    
## 15           average_age  0.037102 0.027053  1.3715 21.2 0.18458247 -0.01913  0.09333    
## 16       implementmedium  0.411779 0.128898  3.1946 26.7 0.00358205  0.14714  0.67642 ***
## 17         implementhigh  0.658570 0.123874  5.3164 34.6 0.00000635  0.40699  0.91015 ***
## 18     program_sitemixed  0.444384 0.172635  2.5741 28.6 0.01550504  0.09109  0.79768  **
## 19 program_siteclassroom  0.426658 0.159773  2.6704 37.4 0.01115192  0.10303  0.75028  **
## 20    program_siteschool  0.262517 0.160519  1.6354 30.1 0.11236814 -0.06525  0.59028    
## 21              duration  0.000427 0.000873  0.4895 36.7 0.62736846 -0.00134  0.00220    
## 22           service_hrs -0.003434 0.005012 -0.6852 36.7 0.49752503 -0.01359  0.00672    
## ---
## Signif. codes: < .01 *** < .05 ** < .10 *
## ---
## Note: If df < 4, do not trust the results

Note that robumeta produces small-sample corrected standard errors and t-tests, and so there is no need to repeat those calculations with clubSandwich. The eval variable has four levels, and it might be of interest to test whether the average program effects differ by the degree of evaluator independence. The null hypothesis in this case is that the 10th, 11th, and 12th regression coefficients are all equal to zero. A small-sample adjusted F-test for this hypothesis can be obtained as follows. The vcov = "CR2" option means that the standard errors will be corrected using the bias-reduced linearization estimator described in Tipton and Pustejovsky (2015).

Wald_test(m3_robu, constraints = constrain_zero(10:12), vcov = "CR2")
##  test Fstat df_num df_denom  p_val sig
##   HTZ  2.78      3     16.8 0.0732   .

By default, the Wald_test function provides an F-type test with degrees of freedom estimated using the approximate Hotelling’s \(T^2_Z\) method. The test has less than 17 degrees of freedom, even though there are 152 independent studies in the data, and has a p-value that is not quite significant at conventional levels. The low degrees of freedom are a consequence of the fact that one of the levels of evaluator independence has only a few effect sizes in it:

table(dropoutPrevention$eval)
## 
## independent    indirect    planning    delivery 
##           6          33          43         303

metafor model

clubSandwich also works with models fit using the metafor package. Here we re-fit the same regression specification, but use REML to estimate the variance components (robumeta uses a method-of-moments estimator), as well as a somewhat different weighting scheme than that used in robumeta.

library(metafor)
m3_metafor <- rma.mv(LOR1 ~ study_design + attrition + group_equivalence + adjusted
                      + outcome + eval
                      + male_pct + white_pct + average_age
                      + implement + program_site + duration + service_hrs, 
                      V = varLOR, random = list(~ 1 | studyID, ~ 1 | studySample),
                     data = dropoutPrevention)
summary(m3_metafor)
## 
## Multivariate Meta-Analysis Model (k = 385; method: REML)
## 
##    logLik   Deviance        AIC        BIC       AICc   
## -489.0357   978.0714  1026.0714  1119.5371  1029.6217   
## 
## Variance Components:
## 
##             estim    sqrt  nlvls  fixed       factor 
## sigma^2.1  0.2274  0.4769    152     no      studyID 
## sigma^2.2  0.1145  0.3384    317     no  studySample 
## 
## Test for Residual Heterogeneity:
## QE(df = 363) = 1588.4397, p-val < .0001
## 
## Test of Moderators (coefficients 2:22):
## QM(df = 21) = 293.8694, p-val < .0001
## 
## Model Results:
## 
##                        estimate      se     zval    pval    ci.lb    ci.ub      
## intrcpt                  0.5296  0.7250   0.7304  0.4651  -0.8915   1.9506      
## study_designunmatched   -0.0494  0.1722  -0.2871  0.7741  -0.3870   0.2881      
## study_designRCT          0.0653  0.1628   0.4010  0.6884  -0.2538   0.3843      
## attrition               -0.1366  0.2429  -0.5623  0.5739  -0.6126   0.3395      
## group_equivalence        0.4071  0.1573   2.5877  0.0097   0.0988   0.7155   ** 
## adjustedyes             -0.3581  0.1532  -2.3371  0.0194  -0.6585  -0.0578    * 
## outcomeenrolled         -0.2831  0.0771  -3.6709  0.0002  -0.4343  -0.1320  *** 
## outcomegraduation       -0.0913  0.0657  -1.3896  0.1646  -0.2201   0.0375      
## outcomegraduation/ged    0.6983  0.0805   8.6750  <.0001   0.5406   0.8561  *** 
## evalindirect            -0.7530  0.4949  -1.5214  0.1282  -1.7230   0.2171      
## evalplanning            -0.7700  0.4869  -1.5814  0.1138  -1.7242   0.1843      
## evaldelivery            -1.0016  0.4600  -2.1774  0.0294  -1.9033  -0.1000    * 
## male_pct                 0.1021  0.1715   0.5951  0.5518  -0.2341   0.4382      
## white_pct                0.1223  0.1804   0.6777  0.4979  -0.2313   0.4758      
## average_age              0.0061  0.0291   0.2091  0.8344  -0.0509   0.0631      
## implementmedium          0.4738  0.1609   2.9445  0.0032   0.1584   0.7892   ** 
## implementhigh            0.6318  0.1471   4.2965  <.0001   0.3436   0.9201  *** 
## program_sitemixed        0.3289  0.2413   1.3631  0.1729  -0.1440   0.8019      
## program_siteclassroom    0.2920  0.1736   1.6821  0.0926  -0.0482   0.6321    . 
## program_siteschool       0.1616  0.1898   0.8515  0.3945  -0.2104   0.5337      
## duration                 0.0013  0.0009   1.3423  0.1795  -0.0006   0.0031      
## service_hrs             -0.0003  0.0047  -0.0654  0.9478  -0.0096   0.0090      
## 
## ---
## Signif. codes:  0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1

metafor produces model-based standard errors, t-tests, and confidence intervals. The coef_test function from clubSandwich will calculate robust standard errors and robust t-tests for each of the coefficients:

coef_test(m3_metafor, vcov = "CR2")
##                  Coef.  Estimate       SE  t-stat d.f. (Satt) p-val (Satt) Sig.
##                intrcpt  0.529569 0.724851  0.7306       20.08      0.47347     
##  study_designunmatched -0.049434 0.204152 -0.2421       58.42      0.80952     
##        study_designRCT  0.065272 0.149146  0.4376       53.17      0.66342     
##              attrition -0.136575 0.306429 -0.4457       10.52      0.66485     
##      group_equivalence  0.407108 0.210917  1.9302       23.10      0.06595    .
##            adjustedyes -0.358124 0.136132 -2.6307       43.20      0.01176    *
##        outcomeenrolled -0.283124 0.237199 -1.1936        7.08      0.27108     
##      outcomegraduation -0.091295 0.091465 -0.9981        9.95      0.34188     
##  outcomegraduation/ged  0.698328 0.364882  1.9138        8.02      0.09188    .
##           evalindirect -0.752994 0.447670 -1.6820        6.56      0.13929     
##           evalplanning -0.769968 0.403898 -1.9063        6.10      0.10446     
##           evaldelivery -1.001648 0.355989 -2.8137        4.89      0.03834    *
##               male_pct  0.102055 0.148410  0.6877        9.68      0.50782     
##              white_pct  0.122255 0.141470  0.8642       16.88      0.39961     
##            average_age  0.006084 0.033387  0.1822       15.79      0.85772     
##        implementmedium  0.473789 0.148660  3.1871       22.44      0.00419   **
##          implementhigh  0.631842 0.138073  4.5761       28.68      < 0.001  ***
##      program_sitemixed  0.328941 0.196848  1.6710       27.47      0.10607     
##  program_siteclassroom  0.291952 0.146014  1.9995       42.70      0.05195    .
##     program_siteschool  0.161640 0.171700  0.9414       29.27      0.35420     
##               duration  0.001270 0.000978  1.2988       31.96      0.20332     
##            service_hrs -0.000309 0.004828 -0.0641       49.63      0.94915

Note that coef_test assumed that it should cluster based on studyID, which is the outer-most random effect in the metafor model. This can be specified explicitly by including the option cluster = dropoutPrevention$studyID in the call.

The F-test for degree of evaluator independence uses the same syntax as before:

Wald_test(m3_metafor, constraints = constrain_zero(10:12), vcov = "CR2")
##  test Fstat df_num df_denom  p_val sig
##   HTZ  2.71      3     18.3 0.0753   .

Despite some differences in weighting schemes, the p-value is very close to the result obtained using robumeta.

References

Fisher, Z., & Tipton, E. (2015). robumeta: An R-package for robust variance estimation in meta-analysis. arXiv:1503.02220

Tipton, E. (2015). Small sample adjustments for robust variance estimation with meta-regression. Psychological Methods, 20(3), 375-393. https://doi.org/10.1037/met0000011

Tipton, E., & Pustejovsky, J. E. (2015). Small-sample adjustments for tests of moderators and model fit using robust variance estimation in meta-regression. Journal of Educational and Behavioral Statistics, 40(6), 604-634. https://doi.org/10.3102/1076998615606099

Viechtbauer, W. (2010). Conducting meta-analyses in R with the metafor package. Journal of Statistical Software, 36(3), 1-48. URL: https://doi.org/10.18637/jss.v036.i03

Wilson, S. J., Lipsey, M. W., Tanner-Smith, E., Huang, C. H., & Steinka-Fry, K. T. (2011). Dropout prevention and intervention programs: Effects on school completion and dropout Among school-aged children and youth: A systematic review. Campbell Systematic Reviews, 7(1), 1-61. https://doi.org/10.4073/csr.2011.8

These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.