Perform mediation analysis in the presence of high-dimensional mediators based on the potential outcome framework. Bayesian Mediation Analysis (BAMA), developed by Song et al (2019) and Song et al (2020), relies on two Bayesian sparse linear mixed models to simultaneously analyze a relatively large number of mediators for a continuous exposure and outcome assuming a small number of mediators are truly active. This sparsity assumption also allows the extension of univariate mediator analysis by casting the identification of active mediators as a variable selection problem and applying Bayesian methods with continuous shrinkage priors on the effects.
You can install bama from CRAN
install.packages("bama")or from Github via devtools
# install.packages(devtools)
devtools::install_github("umich-cphds/bama", built_opts = c())bama requires the R packages Rcpp and
RcppArmadillo, so you may want to install / update them
before downloading. If you decide to install bama from
source (eg github), you will need a C++ compiler that supports C++11. On
Windows this can accomplished by installing Rtools, and Xcode
on MacOS.
The Github version may contain new features or bug fixes not yet
present on CRAN, so if you are experiencing issues, you may want to try
the Github version of the package. ## Example problem bama
contains a semi-synthetic example data set, bama.data that
is used in this example. bama.data contains a continuous
response y and a continuous exposure a that is
mediated by 100 mediators, m[1:100].
library(bama)
# print just the first 10 columns
head(bama.data[,1:10])The mediators have an internal correlation structure that is based
off the covariance matrix from the Multi-Ethnic Study of Atherosclerosis
(MESA) data. However, bama does not model internal
correlation between mediators. Instead, bama employs
continuous Bayesian shrinkage priors to select mediators and assumes
that all the potential mediators contribute small effects in mediating
the exposure-outcome relationship, but only a small proportion of
mediators exhibit large effects.
We use no adjustment covariates in this example, so we just include the intercept. Also, in a real world situation, it may be beneficial to normalize the input data.
Y <- bama.data$y
A <- bama.data$a
# grab the mediators from the example data.frame
M <- as.matrix(bama.data[, paste0("m", 1:100)], nrow(bama.data))
# We just include the intercept term in this example as we have no covariates
C1 <- matrix(1, 1000, 1)
C2 <- matrix(1, 1000, 1)
beta.m <- rep(0, 100)
alpha.a <- rep(0, 100)
out <- bama(Y = Y, A = A, M = M, C1 = C1, C2 = C2, method = "BSLMM", seed = 1234,
burnin = 1000, ndraws = 1100, weights = NULL, inits = NULL,
control = list(k = 2, lm0 = 1e-04, lm1 = 1, l = 1))
# The package includes a function to summarise output from 'bama'
summary <- summary(out)
head(summary)
# Product Threshold Gaussian
ptgmod = bama(Y = Y, A = A, M = M, C1 = C1, C2 = C2, method = "PTG", seed = 1234,
burnin = 1000, ndraws = 1100, weights = NULL, inits = NULL,
control = list(lambda0 = 0.04, lambda1 = 0.2, lambda2 = 0.2))
mean(ptgmod$beta.a)
apply(ptgmod$beta.m, 2, mean)
apply(ptgmod$alpha.a, 2, mean)
apply(ptgmod$betam_member, 2, mean)
apply(ptgmod$alphaa_member, 2, mean)
# Gaussian Mixture Model
gmmmod = bama(Y = Y, A = A, M = M, C1 = C1, C2 = C2, method = "GMM", seed = 1234,
burnin = 1000, ndraws = 1100, weights = NULL, inits = NULL,
control = list(phi0 = 0.01, phi1 = 0.01))
mean(gmmmod$beta.a)
apply(gmmmod$beta.m, 2, mean)
apply(gmmmod$alpha.a, 2, mean)
mean(gmmmod$sigma.sq.a)
mean(gmmmod$sigma.sq.e)
mean(gmmmod$sigma.sq.g)Song, Y, Zhou, X, Zhang, M, et al. Bayesian shrinkage estimation of high dimensional causal mediation effects in omics studies. Biometrics. 2019; 1-11.