| Title: | Quantifying Systematic Heterogeneity in Meta-Analysis |
| Version: | 0.2.2 |
| Description: | Quantifying systematic heterogeneity in meta-analysis using R. The M statistic aggregates heterogeneity information across multiple variants to, identify systematic heterogeneity patterns and their direction of effect in meta-analysis. It's primary use is to identify outlier studies, which either show "null" effects or consistently show stronger or weaker genetic effects than average across, the panel of variants examined in a GWAS meta-analysis. In contrast to conventional heterogeneity metrics (Q-statistic, I-squared and tau-squared) which measure random heterogeneity at individual variants, M measures systematic (non-random) heterogeneity across multiple independently associated variants. Systematic heterogeneity can arise in a meta-analysis due to differences in the study characteristics of participating studies. Some of the differences may include: ancestry, allele frequencies, phenotype definition, age-of-disease onset, family-history, gender, linkage disequilibrium and quality control thresholds. See https://magosil86.github.io/getmstatistic/ for statistical statistical theory, documentation and examples. |
| Depends: | R (≥ 3.1.0) |
| License: | MIT + file LICENSE |
| URL: | https://magosil86.github.io/getmstatistic/ |
| BugReports: | https://github.com/magosil86/getmstatistic/issues |
| LazyData: | true |
| Imports: | ggplot2 (≥ 1.0.1), gridExtra (≥ 0.9.1), gtable (≥ 0.1.2), metafor (≥ 1.9-6), psych (≥ 1.5.1), stargazer (≥ 5.1) |
| Suggests: | foreign (≥ 0.8-62), knitr (≥ 1.10.5), testthat, covr, rmarkdown |
| RoxygenNote: | 7.1.1 |
| VignetteBuilder: | knitr |
| NeedsCompilation: | no |
| Packaged: | 2021-05-09 03:56:42 UTC; lmagosi |
| Author: | Lerato E Magosi [aut], Jemma C Hopewell [aut], Martin Farrall [aut], Lerato E Magosi [cre] |
| Maintainer: | Lerato E Magosi <magosil86@gmail.com> |
| Repository: | CRAN |
| Date/Publication: | 2021-05-09 05:10:15 UTC |
Helper function to draw table grobs.
Description
draw_table() Pre and post version: 2.0.0 gridExtra packages
handle drawing tables differently. draw_table() determines
the installed version of gridExtra and applies the appropriate
syntax. If gridExtra version < 2.0.0 then it uses old gridExtra
syntax to build table Grob(graphical object) else uses new syntax.
draw_table()
Usage
draw_table(body, heading, ...)
Arguments
body |
A dataframe. Table body. |
heading |
A string. Table title. |
... |
Further arguments to control the gtable. |
Details
prints tables without rownames.
Acknowledgements
Thanks to Ryan Welch, https://github.com/welchr/LocusZoom/issues/16
Examples
library(gridExtra)
## Not run:
# Table of iris values
iris_dframe <- head(iris)
title_iris_dframe <- paste("Table: Length and width measurements (cm) of sepals and petals,",
"for 50 flowers from 3 species of iris (setosa, versicolor,",
"and virginica).\n", sep = " ")
# Wrap title text at column 60
title_iris_dframe <- sapply(strwrap(title_iris_dframe, width = 60, simplify = FALSE),
paste, collapse = "\n")
# Draw table
table_influential_studies <- draw_table(body = iris_dframe, heading = title_iris_dframe)
# Table of mtcars values
mtcars_dframe <- head(mtcars)
title_mtcars_dframe <- paste("Table: Motor Trend US magazine (1974) automobile statistics",
"for fuel consumption, \nautomobile design and performance.\n",
sep = " ")
# Wrap title text at column 60
title_mtcars_dframe <- sapply(strwrap(title_mtcars_dframe, width = 60, simplify = FALSE),
paste, collapse = "\n")
# Draw table
table_influential_studies <- draw_table(body = mtcars_dframe, heading = title_mtcars_dframe)
## End(Not run)
Quantifying Systematic Heterogeneity in Meta-Analysis.
Description
getmstatistic computes M statistics to assess the contribution
of each participating study in a meta-analysis. The M statistic
aggregates heterogeneity information across multiple variants to, identify
systematic heterogeneity patterns and their direction of effect in
meta-analysis. It's primary use is to identify outlier studies, which either
show "null" effects or consistently show stronger or weaker genetic effects
than average, across the panel of variants examined in a GWAS meta-analysis.
Usage
getmstatistic(beta_in, lambda_se_in, study_names_in, variant_names_in, ...)
## Default S3 method:
getmstatistic(
beta_in,
lambda_se_in,
study_names_in,
variant_names_in,
save_dir = getwd(),
tau2_method = "DL",
x_axis_increment_in = 0.02,
x_axis_round_in = 2,
produce_plots = TRUE,
verbose_output = FALSE,
...
)
Arguments
beta_in |
A numeric vector of study effect-sizes e.g. log odds-ratios. |
lambda_se_in |
A numeric vector of standard errors, genomically corrected at study-level. |
study_names_in |
A character vector of study names. |
variant_names_in |
A character vector of variant names e.g. rsIDs. |
... |
Further arguments. |
save_dir |
A character scalar specifying a path to the directory where plots should be stored (optional). Required if produce_plots = TRUE. |
tau2_method |
A character scalar, method to estimate heterogeneity: either "DL" or "REML" (Optional). Note: The REML method uses the iterative Fisher scoring algorithm (step length = 0.5, maximum iterations = 10000) to estimate tau2. |
x_axis_increment_in |
A numeric scalar, value by which x-axis of M scatterplot will be incremented (Optional). |
x_axis_round_in |
A numeric scalar, value to which x-axis labels of M scatterplot will be rounded (Optional). |
produce_plots |
A boolean to generate plots (optional). |
verbose_output |
An optional boolean to display intermediate output. |
Details
In contrast to conventional heterogeneity metrics (Q-statistic, I-squared and tau-squared) which measure random heterogeneity at individual variants, M measures systematic (non-random) heterogeneity across multiple independently associated variants.
Systematic heterogeneity can arise in a meta-analysis due to differences in the study characteristics of participating studies. Some of the differences may include: ancestry, allele frequencies, phenotype definition, age-of-disease onset, family-history, gender, linkage disequilibrium and quality control thresholds. See the getmstatistic website for statistical theory, documentation and examples.
getmstatistic uses summary data i.e. study effect-sizes and their
corresponding standard errors to calculate M statistics (One M
for each study in the meta-analysis).
In particular, getmstatistic employs the inverse-variance weighted
random effects regression model provided in the metafor R package
to extract SPREs (standardized predicted random effects) which are then
aggregated to formulate M statistics.
Value
Returns a list containing:
Mstatistic_expected_mean , A numeric scalar for the expected mean for M
Mstatistic_expected_sd , A numeric scalar for the expected standard deviation for M
number_studies , A numeric scalar for the number of studies
number_variants , A numeric scalar for the number of variants
Mstatistic_crit_alpha_0_05 , A numeric scalar of the critical M value at the 5 percent significance level.
M_dataset (dataframe) A dataset of the computed M statistics, which includes the following fields:
M , Mstatistic
M_sd , standard deviation of M
M_se , standard error of M
lowerbound , lowerbound of M 95
upperbound , upperbound of M 95
bonfpvalue , 2-sided bonferroni pvalues of M
qvalue , false discovery rate adjusted pvalues of M
tau2 , tau_squared, DL estimates of between-study heterogeneity
I2 , I_squared, proportion of total variation due to between study variance
Q , Cochran's Q
xb , fitted values excluding random effects
usta , standardized predicted random effect (SPRE)
xbu , fitted values including random effects
stdxbu , standard error of prediction (fitted values) including random effects
hat , diagonal elements of the projection hat matrix
study , study numbers
snp , variant numbers
beta_mean , average variant effect size
oddsratio , average variant effect size as oddsratio
beta_n , number of variants in each study
influential_studies_0_05 (dataframe) A dataset of influential studies significant at the 5 percent level.
weaker_studies_0_05 (dataframe) A dataset of under-performing studies significant at the 5 percent level.
Methods (by class)
-
default: Computes M statistics
See Also
rma.uni function in metafor for random
effects model, and https://magosil86.github.io/getmstatistic/ for
getmstatistic website.
Examples
library(getmstatistic)
library(gridExtra)
# Basic M analysis using the heartgenes214 dataset.
# heartgenes214 is a multi-ethnic GWAS meta-analysis dataset for coronary artery disease.
# To learn more about the heartgenes214 dataset ?heartgenes214
# Running an M analysis on 20 GWAS significant variants (p < 5e-08) in the first 10 studies
heartgenes44_10studies <- subset(heartgenes214, studies <= 10 & fdr214_gwas46 == 2)
heartgenes20_10studies <- subset(heartgenes44_10studies,
variants %in% unique(heartgenes44_10studies$variants)[1:20])
# Set directory to store plots, this can be a temporary directory
# or a path to a directory of choice e.g. plots_dir <- "~/Downloads"
plots_dir <- tempdir()
getmstatistic_results <- getmstatistic(heartgenes20_10studies$beta_flipped,
heartgenes20_10studies$gcse,
heartgenes20_10studies$variants,
heartgenes20_10studies$studies,
save_dir = plots_dir)
getmstatistic_results
# Explore results generated by getmstatistic function
# Retrieve dataset of M statistics
dframe <- getmstatistic_results$M_dataset
str(dframe)
# Retrieve dataset of stronger than average studies (significant at 5% level)
getmstatistic_results$influential_studies_0_05
# Retrieve dataset of weaker than average studies (significant at 5% level)
getmstatistic_results$weaker_studies_0_05
# Retrieve number of studies and variants
getmstatistic_results$number_studies
getmstatistic_results$number_variants
# Retrieve expected mean, sd and critical M value at 5% significance level
getmstatistic_results$M_expected_mean
getmstatistic_results$M_expected_sd
getmstatistic_results$M_crit_alpha_0_05
# To view plots stored in a temporary directory, call `tempdir()` to view the directory path
tempdir()
# Additional examples: These take a little bit longer to run
## Not run:
# Set directory to store plots, this can be a temporary directory
# or a path to a directory of choice e.g. plots_dir <- "~/Downloads"
plots_dir <- tempdir()
# Run M analysis on all 214 lead variants
# heartgenes214 is a multi-ethnic GWAS meta-analysis dataset for coronary artery disease.
getmstatistic_results <- getmstatistic(heartgenes214$beta_flipped,
heartgenes214$gcse,
heartgenes214$variants,
heartgenes214$studies,
save_dir = plots_dir)
getmstatistic_results
# Subset the GWAS significant variants (p < 5e-08) in heartgenes214
heartgenes44 <- subset(heartgenes214, heartgenes214$fdr214_gwas46 == 2)
# Exploring getmstatistic options:
# Estimate heterogeneity using "REML", default is "DL"
# Modify x-axis of M scatterplot
# Run M analysis verbosely
getmstatistic_results <- getmstatistic(heartgenes44$beta_flipped,
heartgenes44$gcse,
heartgenes44$variants,
heartgenes44$studies,
save_dir = plots_dir,
tau2_method = "REML",
x_axis_increment_in = 0.03,
x_axis_round_in = 3,
produce_plots = TRUE,
verbose_output = TRUE)
getmstatistic_results
## End(Not run)
heartgenes214.
Description
heartgenes214 is a multi-ethnic GWAS meta-analysis dataset for coronary artery disease.
Usage
heartgenes214
Format
A data frame with seven variables:
beta_flippedEffect-sizes expressed as log odds ratios. Numeric
gcseStandard errors
studiesNames of participating studies
variantsNames of genetic variants/SNPs
casesNumber of cases in each participating study
controlsNumber of controls in each participating study
fdr214_gwas46Flag indicating GWAS significant variants, 1: Not GWAS-significant, 2: GWAS-significant
Details
It comprises summary data (effect-sizes and their corresponding standard errors) for 48 studies (68,801 cases and 123,504 controls), at 214 lead variants independently associated with coronary artery disease (P < 0.00005, FDR < 5%). Of the 214 lead variants, 44 are genome-wide significant (p < 5e-08). The meta-analysis dataset is based on individuals of: African American, Hispanic American, East Asian, South Asian, Middle Eastern and European ancestry.
The study effect-sizes have been flipped to ensure alignment of the effect alleles.
Standard errors were genomically corrected at the study-level.
Source
Magosi LE, Goel A, Hopewell JC, Farrall M, on behalf of the CARDIoGRAMplusC4D Consortium (2017) Identifying systematic heterogeneity patterns in genetic association meta-analysis studies. PLoS Genet 13(5): e1006755. https://doi.org/10.1371/journal.pgen.1006755.