metamean: Meta-analysis of single means
In meta: General Package for Meta-Analysis
metamean R Documentation
Meta-analysis of single means
Description
Calculation of an overall mean from studies reporting a single mean
using the inverse variance method for pooling; inverse variance
weighting is used for pooling.
Usage
metamean(
n,
mean,
sd,
studlab,
data = NULL,
subset = NULL,
exclude = NULL,
cluster = NULL,
rho = 0,
median,
q1,
q3,
min,
max,
method.mean = "Luo",
method.sd = "Shi",
approx.mean,
approx.sd,
sm = gs("smmean"),
method.ci = gs("method.ci.cont"),
level = gs("level"),
common = gs("common"),
random = gs("random") | !is.null(tau.preset),
overall = common | random,
overall.hetstat = if (is.null(gs("overall.hetstat"))) common | random else
gs("overall.hetstat"),
prediction = gs("prediction") | !missing(method.predict),
method.tau = gs("method.tau"),
method.tau.ci = gs("method.tau.ci"),
level.hetstat = gs("level.hetstat"),
tau.preset = NULL,
TE.tau = NULL,
tau.common = gs("tau.common"),
method.I2 = gs("method.I2"),
level.ma = gs("level.ma"),
method.random.ci = gs("method.random.ci"),
adhoc.hakn.ci = gs("adhoc.hakn.ci"),
level.predict = gs("level.predict"),
method.predict = gs("method.predict"),
adhoc.hakn.pi = gs("adhoc.hakn.pi"),
seed.predict = NULL,
null.effect = NA,
method.bias = gs("method.bias"),
backtransf = gs("backtransf"),
text.common = gs("text.common"),
text.random = gs("text.random"),
text.predict = gs("text.predict"),
text.w.common = gs("text.w.common"),
text.w.random = gs("text.w.random"),
title = gs("title"),
complab = gs("complab"),
outclab = "",
label.left = gs("label.left"),
label.right = gs("label.right"),
col.label.left = gs("col.label.left"),
col.label.right = gs("col.label.right"),
subgroup,
subgroup.name = NULL,
print.subgroup.name = gs("print.subgroup.name"),
sep.subgroup = gs("sep.subgroup"),
test.subgroup = gs("test.subgroup"),
prediction.subgroup = gs("prediction.subgroup"),
seed.predict.subgroup = NULL,
byvar,
adhoc.hakn,
keepdata = gs("keepdata"),
warn = gs("warn"),
warn.deprecated = gs("warn.deprecated"),
control = NULL,
...
)
Arguments
n
Number of observations.
mean
Estimated mean.
sd
Standard deviation.
studlab
An optional vector with study labels.
data
An optional data frame containing the study
information.
subset
An optional vector specifying a subset of studies to
be used.
exclude
An optional vector specifying studies to exclude
from meta-analysis, however, to include in printouts and forest
plots.
cluster
An optional vector specifying which estimates come
from the same cluster resulting in the use of a three-level
meta-analysis model.
rho
Assumed correlation of estimates within a cluster.
median
Median (used to estimate the mean and standard
deviation).
q1
First quartile (used to estimate the mean and standard
deviation).
q3
Third quartile (used to estimate the mean and standard
deviation).
min
Minimum (used to estimate the mean and standard
deviation).
max
Maximum (used to estimate the mean and standard
deviation).
method.mean
A character string indicating which method to
use to approximate the mean from the median and other statistics
(see Details).
method.sd
A character string indicating which method to use
to approximate the standard deviation from sample size, median,
interquartile range and range (see Details).
approx.mean
Approximation method to estimate means (see
Details).
approx.sd
Approximation method to estimate standard
deviations (see Details).
sm
A character string indicating which summary measure
("MRAW" or "MLN") is to be used for pooling of
studies.
method.ci
A character string indicating which method is used
to calculate confidence intervals for individual studies, see
Details.
level
The level used to calculate confidence intervals for
individual studies.
common
A logical indicating whether a common effect
meta-analysis should be conducted.
random
A logical indicating whether a random effects
meta-analysis should be conducted.
overall
A logical indicating whether overall summaries
should be reported. This argument is useful in a meta-analysis
with subgroups if overall results should not be reported.
overall.hetstat
A logical value indicating whether to print
heterogeneity measures for overall treatment comparisons. This
argument is useful in a meta-analysis with subgroups if
heterogeneity statistics should only be printed on subgroup
level.
prediction
A logical indicating whether a prediction
interval should be printed.
method.tau
A character string indicating which method is
used to estimate the between-study variance \tau^2 and its
square root \tau (see meta-package).
method.tau.ci
A character string indicating which method is
used to estimate the confidence interval of \tau^2 and
\tau (see meta-package).
level.hetstat
The level used to calculate confidence intervals
for heterogeneity statistics.
tau.preset
Prespecified value for the square root of the
between-study variance \tau^2.
TE.tau
Overall treatment effect used to estimate the
between-study variance tau-squared.
tau.common
A logical indicating whether tau-squared should
be the same across subgroups.
method.I2
A character string indicating which method is
used to estimate the heterogeneity statistic I^2. Either
"Q" or "tau2", can be abbreviated
(see meta-package).
level.ma
The level used to calculate confidence intervals
for meta-analysis estimates.
method.random.ci
A character string indicating which method
is used to calculate confidence interval and test statistic for
random effects estimate (see meta-package).
adhoc.hakn.ci
A character string indicating whether an
ad hoc variance correction should be applied in the case
of an arbitrarily small Hartung-Knapp variance estimate (see
meta-package).
level.predict
The level used to calculate prediction
interval for a new study.
method.predict
A character string indicating which method is
used to calculate a prediction interval (see
meta-package).
adhoc.hakn.pi
A character string indicating whether an
ad hoc variance correction should be applied for
prediction interval (see meta-package).
seed.predict
A numeric value used as seed to calculate
bootstrap prediction interval (see meta-package).
null.effect
A numeric value specifying the effect under the
null hypothesis.
method.bias
A character string indicating which test is to
be used. Either "Begg", "Egger", or
"Thompson", can be abbreviated. See function
metabias.
backtransf
A logical indicating whether results should be
back transformed in printouts and plots for sm = "MLN". If
TRUE (default), results will be presented as means; otherwise
logarithm of means will be shown.
text.common
A character string used in printouts and forest
plot to label the pooled common effect estimate.
text.random
A character string used in printouts and forest
plot to label the pooled random effects estimate.
text.predict
A character string used in printouts and forest
plot to label the prediction interval.
text.w.common
A character string used to label weights of
common effect model.
text.w.random
A character string used to label weights of
random effects model.
title
Title of meta-analysis / systematic review.
complab
Comparison label.
outclab
Outcome label.
label.left
Graph label on left side of null effect in forest plot.
label.right
Graph label on right side of null effect in forest plot.
col.label.left
The colour of the graph label on the left side of
the null effect.
col.label.right
The colour of the graph label on the right side of
the null effect.
subgroup
An optional vector to conduct a meta-analysis with
subgroups.
subgroup.name
A character string with a name for the
subgroup variable.
print.subgroup.name
A logical indicating whether the name of
the subgroup variable should be printed in front of the group
labels.
sep.subgroup
A character string defining the separator
between name of subgroup variable and subgroup label.
test.subgroup
A logical value indicating whether to print
results of test for subgroup differences.
prediction.subgroup
A logical indicating whether prediction
intervals should be printed for subgroups.
seed.predict.subgroup
A numeric vector providing seeds to
calculate bootstrap prediction intervals within subgroups. Must
be of same length as the number of subgroups.
byvar
Deprecated argument (replaced by 'subgroup').
adhoc.hakn
Deprecated argument (replaced by 'adhoc.hakn.ci').
keepdata
A logical indicating whether original data (set)
should be kept in meta object.
warn
A logical indicating whether warnings should be printed
(e.g., if studies are excluded from meta-analysis due to zero
standard deviations).
warn.deprecated
A logical indicating whether warnings should
be printed if deprecated arguments are used.
control
An optional list to control the iterative process to
estimate the between-study variance \tau^2. This argument
is passed on to rma.uni.
...
Additional arguments (to catch deprecated arguments).
Details
Common effect and random effects meta-analysis of single means to
calculate an overall mean; inverse variance weighting is used for
pooling. Note, you should use R function metacont to
compare means of pairwise comparisons instead of using
metamean for each treatment arm separately which will break
randomisation in randomised controlled trials.
A three-level random effects meta-analysis model (Van den Noortgate
et al., 2013) is utilised if argument cluster is used and at
least one cluster provides more than one estimate. Internally,
rma.mv is called to conduct the analysis and
weights.rma.mv with argument type =
"rowsum" is used to calculate random effects weights.
Default settings are utilised for several arguments (assignments
using gs function). These defaults can be changed for
the current R session using the settings.meta
function.
Furthermore, R function update.meta can be used to
rerun a meta-analysis with different settings.
The following transformations of means are implemented to
calculate an overall mean:
Raw, i.e. untransformed, means (sm = "MRAW", default)
Log transformed means (sm = "MLN")
Calculations are conducted on the log scale if sm =
"MLN". Accordingly, list elements TE, TE.common, and
TE.random contain the logarithm of means. In printouts and
plots these values are back transformed if argument
backtransf = TRUE (default).
Approximate means from sample sizes, medians and other statistics
Missing means can be derived from
sample size, median, interquartile range and range (arguments
n, median, q1, q3, min, and
max),
sample size, median and interquartile range (arguments
n, median, q1, and q3), or
sample size, median and range (arguments n,
median, min, and max).
By default, methods described in Luo et al. (2018) are utilised
(argument method.mean = "Luo"):
equation (15) if sample size, median, interquartile range and
range are available,
equation (11) if sample size, median and interquartile range
are available,
equation (7) if sample size, median and range are available.
Instead the methods described in Wan et al. (2014) are used if
argument method.mean = "Wan":
equation (10) if sample size, median, interquartile range and
range are available,
equation (14) if sample size, median and interquartile range
are available,
equation (2) if sample size, median and range are available.
The following methods are also available to estimate means from
quantiles or ranges if R package estmeansd is installed:
Method for Unknown Non-Normal Distributions (MLN) approach
(Cai et al. (2021), argument method.mean = "Cai"),
Quantile Estimation (QE) method (McGrath et al. (2020),
argument method.mean = "QE-McGrath")),
Box-Cox (BC) method (McGrath et al. (2020),
argument method.mean = "BC-McGrath")).
By default, missing means are replaced successively using
interquartile ranges and ranges (if available), interquartile
ranges (if available) and finally ranges. Argument
approx.mean can be used to overwrite this behaviour for each
individual study and treatment arm:
use means directly (entry "" in argument
approx.mean);
median, interquartile range and range ("iqr.range");
median and interquartile range ("iqr");
median and range ("range").
Approximate standard deviations from sample sizes, medians and other statistics
Missing standard deviations can be derived from
sample size, median, interquartile range and range (arguments
n, median, q1, q3, min, and
max),
sample size, median and interquartile range (arguments
n, median, q1 and q3), or
sample size, median and range (arguments n,
median, min and max).
Wan et al. (2014) describe methods to estimate the standard
deviation from the sample size, median and additional
statistics. Shi et al. (2020) provide an improved estimate of the
standard deviation if the interquartile range and range are
available in addition to the sample size and median. Accordingly,
equation (11) in Shi et al. (2020) is the default (argument
method.sd = "Shi"), if the median, interquartile range and
range are provided. The method by Wan et al. (2014) is used if
argument method.sd = "Wan" and, depending on the sample
size, either equation (12) or (13) is used. If only the
interquartile range or range is available, equations (15) / (16)
and (7) / (9) in Wan et al. (2014) are used, respectively.
The following methods are also available to estimate standard
deviations from quantiles or ranges if R package estmeansd
is installed:
Method for Unknown Non-Normal Distributions (MLN) approach
(Cai et al. (2021), argument method.mean = "Cai"),
Quantile Estimation (QE) method (McGrath et al. (2020),
argument method.mean = "QE-McGrath")),
Box-Cox (BC) method (McGrath et al. (2020),
argument method.mean = "BC-McGrath")).
By default, missing standard deviations are replaced successively
using these method, i.e., interquartile ranges and ranges are used
before interquartile ranges before ranges. Argument
approx.sd can be used to overwrite this default for each
individual study and treatment arms:
sample size, median, interquartile range and range
("iqr.range");
sample size, median and interquartile range ("iqr");
sample size, median and range ("range").
Confidence intervals for individual studies
For untransformed means (argument sm = "MRAW"), the
confidence interval for individual studies can be based on the
standard normal distribution (method.ci = "z", default), or
t-distribution (method.ci = "t").
Subgroup analysis
Argument subgroup can be used to conduct subgroup analysis for
a categorical covariate. The metareg function can be
used instead for more than one categorical covariate or continuous
covariates.
Exclusion of studies from meta-analysis
Arguments subset and exclude can be used to exclude
studies from the meta-analysis. Studies are removed completely from
the meta-analysis using argument subset, while excluded
studies are shown in printouts and forest plots using argument
exclude (see Examples in metagen).
Meta-analysis results are the same for both arguments.
Presentation of meta-analysis results
Internally, both common effect and random effects models are
calculated regardless of values choosen for arguments
common and random. Accordingly, the estimate
for the random effects model can be extracted from component
TE.random of an object of class "meta" even if
argument random = FALSE. However, all functions in R
package meta will adequately consider the values for
common and random. E.g. functions
print.meta and forest.meta will not
print results for the random effects model if random =
FALSE.
A prediction interval will only be shown if prediction =
TRUE.
Value
An object of class c("metamean", "meta") with corresponding
generic functions (see meta-object).
Note
The function metagen is called internally to
calculate individual and overall treatment estimates and standard
errors.
Author(s)
Guido Schwarzer guido.schwarzer@uniklinik-freiburg.de
References
Cai S, Zhou J, Pan J (2021):
Estimating the sample mean and standard deviation from order
statistics and sample size in meta-analysis.
Statistical Methods in Medical Research,
30, 2701–2719
Luo D, Wan X, Liu J, Tong T (2018):
Optimally estimating the sample mean from the sample size, median,
mid-range, and/or mid-quartile range.
Statistical Methods in Medical Research,
27, 1785–805
McGrath S, Zhao X, Steele R, et al. and the DEPRESsion Screening
Data (DEPRESSD) Collaboration (2020):
Estimating the sample mean and standard deviation from commonly
reported quantiles in meta-analysis.
Statistical Methods in Medical Research,
29, 2520–2537
Shi J, Luo D, Weng H, Zeng X-T, Lin L, Chu H, et al. (2020):
Optimally estimating the sample standard deviation from the
five-number summary.
Research Synthesis Methods.
Van den Noortgate W, López-López JA, Marín-Martínez F, Sánchez-Meca
J (2013):
Three-level meta-analysis of dependent effect sizes.
Behavior Research Methods,
45, 576–94
Wan X, Wang W, Liu J, Tong T (2014):
Estimating the sample mean and standard deviation from the sample
size, median, range and/or interquartile range.
BMC Medical Research Methodology,
14, 135
See Also
meta-package, update.meta,
metamean, metagen
Examples
m1 <- metamean(rep(100, 3), 1:3, rep(1, 3))
m1
m2 <- update(m1, sm = "MLN")
m2
# With test for overall mean equal to 2
#
update(m1, null.effect = 2)
update(m2, null.effect = 2)
# Print results without back-transformation
#
update(m1, backtransf = FALSE)
update(m2, backtransf = FALSE)
update(m1, null.effect = 2, backtransf = FALSE)
update(m2, null.effect = 2, backtransf = FALSE)
meta documentation built on Oct. 31, 2024, 5:07 p.m.
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| metamean | R Documentation |
Meta-analysis of single means
Description
Calculation of an overall mean from studies reporting a single mean using the inverse variance method for pooling; inverse variance weighting is used for pooling.
Usage
metamean(
n,
mean,
sd,
studlab,
data = NULL,
subset = NULL,
exclude = NULL,
cluster = NULL,
rho = 0,
median,
q1,
q3,
min,
max,
method.mean = "Luo",
method.sd = "Shi",
approx.mean,
approx.sd,
sm = gs("smmean"),
method.ci = gs("method.ci.cont"),
level = gs("level"),
common = gs("common"),
random = gs("random") | !is.null(tau.preset),
overall = common | random,
overall.hetstat = if (is.null(gs("overall.hetstat"))) common | random else
gs("overall.hetstat"),
prediction = gs("prediction") | !missing(method.predict),
method.tau = gs("method.tau"),
method.tau.ci = gs("method.tau.ci"),
level.hetstat = gs("level.hetstat"),
tau.preset = NULL,
TE.tau = NULL,
tau.common = gs("tau.common"),
method.I2 = gs("method.I2"),
level.ma = gs("level.ma"),
method.random.ci = gs("method.random.ci"),
adhoc.hakn.ci = gs("adhoc.hakn.ci"),
level.predict = gs("level.predict"),
method.predict = gs("method.predict"),
adhoc.hakn.pi = gs("adhoc.hakn.pi"),
seed.predict = NULL,
null.effect = NA,
method.bias = gs("method.bias"),
backtransf = gs("backtransf"),
text.common = gs("text.common"),
text.random = gs("text.random"),
text.predict = gs("text.predict"),
text.w.common = gs("text.w.common"),
text.w.random = gs("text.w.random"),
title = gs("title"),
complab = gs("complab"),
outclab = "",
label.left = gs("label.left"),
label.right = gs("label.right"),
col.label.left = gs("col.label.left"),
col.label.right = gs("col.label.right"),
subgroup,
subgroup.name = NULL,
print.subgroup.name = gs("print.subgroup.name"),
sep.subgroup = gs("sep.subgroup"),
test.subgroup = gs("test.subgroup"),
prediction.subgroup = gs("prediction.subgroup"),
seed.predict.subgroup = NULL,
byvar,
adhoc.hakn,
keepdata = gs("keepdata"),
warn = gs("warn"),
warn.deprecated = gs("warn.deprecated"),
control = NULL,
...
)
Arguments
n |
Number of observations. |
mean |
Estimated mean. |
sd |
Standard deviation. |
studlab |
An optional vector with study labels. |
data |
An optional data frame containing the study information. |
subset |
An optional vector specifying a subset of studies to be used. |
exclude |
An optional vector specifying studies to exclude from meta-analysis, however, to include in printouts and forest plots. |
cluster |
An optional vector specifying which estimates come from the same cluster resulting in the use of a three-level meta-analysis model. |
rho |
Assumed correlation of estimates within a cluster. |
median |
Median (used to estimate the mean and standard deviation). |
q1 |
First quartile (used to estimate the mean and standard deviation). |
q3 |
Third quartile (used to estimate the mean and standard deviation). |
min |
Minimum (used to estimate the mean and standard deviation). |
max |
Maximum (used to estimate the mean and standard deviation). |
method.mean |
A character string indicating which method to use to approximate the mean from the median and other statistics (see Details). |
method.sd |
A character string indicating which method to use to approximate the standard deviation from sample size, median, interquartile range and range (see Details). |
approx.mean |
Approximation method to estimate means (see Details). |
approx.sd |
Approximation method to estimate standard deviations (see Details). |
sm |
A character string indicating which summary measure
( |
method.ci |
A character string indicating which method is used to calculate confidence intervals for individual studies, see Details. |
level |
The level used to calculate confidence intervals for individual studies. |
common |
A logical indicating whether a common effect meta-analysis should be conducted. |
random |
A logical indicating whether a random effects meta-analysis should be conducted. |
overall |
A logical indicating whether overall summaries should be reported. This argument is useful in a meta-analysis with subgroups if overall results should not be reported. |
overall.hetstat |
A logical value indicating whether to print heterogeneity measures for overall treatment comparisons. This argument is useful in a meta-analysis with subgroups if heterogeneity statistics should only be printed on subgroup level. |
prediction |
A logical indicating whether a prediction interval should be printed. |
method.tau |
A character string indicating which method is
used to estimate the between-study variance |
method.tau.ci |
A character string indicating which method is
used to estimate the confidence interval of |
level.hetstat |
The level used to calculate confidence intervals for heterogeneity statistics. |
tau.preset |
Prespecified value for the square root of the
between-study variance |
TE.tau |
Overall treatment effect used to estimate the between-study variance tau-squared. |
tau.common |
A logical indicating whether tau-squared should be the same across subgroups. |
method.I2 |
A character string indicating which method is
used to estimate the heterogeneity statistic I |
level.ma |
The level used to calculate confidence intervals for meta-analysis estimates. |
method.random.ci |
A character string indicating which method
is used to calculate confidence interval and test statistic for
random effects estimate (see |
adhoc.hakn.ci |
A character string indicating whether an
ad hoc variance correction should be applied in the case
of an arbitrarily small Hartung-Knapp variance estimate (see
|
level.predict |
The level used to calculate prediction interval for a new study. |
method.predict |
A character string indicating which method is
used to calculate a prediction interval (see
|
adhoc.hakn.pi |
A character string indicating whether an
ad hoc variance correction should be applied for
prediction interval (see |
seed.predict |
A numeric value used as seed to calculate
bootstrap prediction interval (see |
null.effect |
A numeric value specifying the effect under the null hypothesis. |
method.bias |
A character string indicating which test is to
be used. Either |
backtransf |
A logical indicating whether results should be
back transformed in printouts and plots for |
text.common |
A character string used in printouts and forest plot to label the pooled common effect estimate. |
text.random |
A character string used in printouts and forest plot to label the pooled random effects estimate. |
text.predict |
A character string used in printouts and forest plot to label the prediction interval. |
text.w.common |
A character string used to label weights of common effect model. |
text.w.random |
A character string used to label weights of random effects model. |
title |
Title of meta-analysis / systematic review. |
complab |
Comparison label. |
outclab |
Outcome label. |
label.left |
Graph label on left side of null effect in forest plot. |
label.right |
Graph label on right side of null effect in forest plot. |
col.label.left |
The colour of the graph label on the left side of the null effect. |
col.label.right |
The colour of the graph label on the right side of the null effect. |
subgroup |
An optional vector to conduct a meta-analysis with subgroups. |
subgroup.name |
A character string with a name for the subgroup variable. |
print.subgroup.name |
A logical indicating whether the name of the subgroup variable should be printed in front of the group labels. |
sep.subgroup |
A character string defining the separator between name of subgroup variable and subgroup label. |
test.subgroup |
A logical value indicating whether to print results of test for subgroup differences. |
prediction.subgroup |
A logical indicating whether prediction intervals should be printed for subgroups. |
seed.predict.subgroup |
A numeric vector providing seeds to calculate bootstrap prediction intervals within subgroups. Must be of same length as the number of subgroups. |
byvar |
Deprecated argument (replaced by 'subgroup'). |
adhoc.hakn |
Deprecated argument (replaced by 'adhoc.hakn.ci'). |
keepdata |
A logical indicating whether original data (set) should be kept in meta object. |
warn |
A logical indicating whether warnings should be printed (e.g., if studies are excluded from meta-analysis due to zero standard deviations). |
warn.deprecated |
A logical indicating whether warnings should be printed if deprecated arguments are used. |
control |
An optional list to control the iterative process to
estimate the between-study variance |
... |
Additional arguments (to catch deprecated arguments). |
Details
Common effect and random effects meta-analysis of single means to
calculate an overall mean; inverse variance weighting is used for
pooling. Note, you should use R function metacont to
compare means of pairwise comparisons instead of using
metamean for each treatment arm separately which will break
randomisation in randomised controlled trials.
A three-level random effects meta-analysis model (Van den Noortgate
et al., 2013) is utilised if argument cluster is used and at
least one cluster provides more than one estimate. Internally,
rma.mv is called to conduct the analysis and
weights.rma.mv with argument type =
"rowsum" is used to calculate random effects weights.
Default settings are utilised for several arguments (assignments
using gs function). These defaults can be changed for
the current R session using the settings.meta
function.
Furthermore, R function update.meta can be used to
rerun a meta-analysis with different settings.
The following transformations of means are implemented to calculate an overall mean:
Raw, i.e. untransformed, means (
sm = "MRAW", default)Log transformed means (
sm = "MLN")
Calculations are conducted on the log scale if sm =
"MLN". Accordingly, list elements TE, TE.common, and
TE.random contain the logarithm of means. In printouts and
plots these values are back transformed if argument
backtransf = TRUE (default).
Approximate means from sample sizes, medians and other statistics
Missing means can be derived from
sample size, median, interquartile range and range (arguments
n,median,q1,q3,min, andmax),sample size, median and interquartile range (arguments
n,median,q1, andq3), orsample size, median and range (arguments
n,median,min, andmax).
By default, methods described in Luo et al. (2018) are utilised
(argument method.mean = "Luo"):
equation (15) if sample size, median, interquartile range and range are available,
equation (11) if sample size, median and interquartile range are available,
equation (7) if sample size, median and range are available.
Instead the methods described in Wan et al. (2014) are used if
argument method.mean = "Wan":
equation (10) if sample size, median, interquartile range and range are available,
equation (14) if sample size, median and interquartile range are available,
equation (2) if sample size, median and range are available.
The following methods are also available to estimate means from quantiles or ranges if R package estmeansd is installed:
Method for Unknown Non-Normal Distributions (MLN) approach (Cai et al. (2021), argument
method.mean = "Cai"),Quantile Estimation (QE) method (McGrath et al. (2020), argument
method.mean = "QE-McGrath")),Box-Cox (BC) method (McGrath et al. (2020), argument
method.mean = "BC-McGrath")).
By default, missing means are replaced successively using
interquartile ranges and ranges (if available), interquartile
ranges (if available) and finally ranges. Argument
approx.mean can be used to overwrite this behaviour for each
individual study and treatment arm:
use means directly (entry
""in argumentapprox.mean);median, interquartile range and range (
"iqr.range");median and interquartile range (
"iqr");median and range (
"range").
Approximate standard deviations from sample sizes, medians and other statistics
Missing standard deviations can be derived from
sample size, median, interquartile range and range (arguments
n,median,q1,q3,min, andmax),sample size, median and interquartile range (arguments
n,median,q1andq3), orsample size, median and range (arguments
n,median,minandmax).
Wan et al. (2014) describe methods to estimate the standard
deviation from the sample size, median and additional
statistics. Shi et al. (2020) provide an improved estimate of the
standard deviation if the interquartile range and range are
available in addition to the sample size and median. Accordingly,
equation (11) in Shi et al. (2020) is the default (argument
method.sd = "Shi"), if the median, interquartile range and
range are provided. The method by Wan et al. (2014) is used if
argument method.sd = "Wan" and, depending on the sample
size, either equation (12) or (13) is used. If only the
interquartile range or range is available, equations (15) / (16)
and (7) / (9) in Wan et al. (2014) are used, respectively.
The following methods are also available to estimate standard deviations from quantiles or ranges if R package estmeansd is installed:
Method for Unknown Non-Normal Distributions (MLN) approach (Cai et al. (2021), argument
method.mean = "Cai"),Quantile Estimation (QE) method (McGrath et al. (2020), argument
method.mean = "QE-McGrath")),Box-Cox (BC) method (McGrath et al. (2020), argument
method.mean = "BC-McGrath")).
By default, missing standard deviations are replaced successively
using these method, i.e., interquartile ranges and ranges are used
before interquartile ranges before ranges. Argument
approx.sd can be used to overwrite this default for each
individual study and treatment arms:
sample size, median, interquartile range and range (
"iqr.range");sample size, median and interquartile range (
"iqr");sample size, median and range (
"range").
Confidence intervals for individual studies
For untransformed means (argument sm = "MRAW"), the
confidence interval for individual studies can be based on the
standard normal distribution (
method.ci = "z", default), ort-distribution (
method.ci = "t").
Subgroup analysis
Argument subgroup can be used to conduct subgroup analysis for
a categorical covariate. The metareg function can be
used instead for more than one categorical covariate or continuous
covariates.
Exclusion of studies from meta-analysis
Arguments subset and exclude can be used to exclude
studies from the meta-analysis. Studies are removed completely from
the meta-analysis using argument subset, while excluded
studies are shown in printouts and forest plots using argument
exclude (see Examples in metagen).
Meta-analysis results are the same for both arguments.
Presentation of meta-analysis results
Internally, both common effect and random effects models are
calculated regardless of values choosen for arguments
common and random. Accordingly, the estimate
for the random effects model can be extracted from component
TE.random of an object of class "meta" even if
argument random = FALSE. However, all functions in R
package meta will adequately consider the values for
common and random. E.g. functions
print.meta and forest.meta will not
print results for the random effects model if random =
FALSE.
A prediction interval will only be shown if prediction =
TRUE.
Value
An object of class c("metamean", "meta") with corresponding
generic functions (see meta-object).
Note
The function metagen is called internally to
calculate individual and overall treatment estimates and standard
errors.
Author(s)
Guido Schwarzer guido.schwarzer@uniklinik-freiburg.de
References
Cai S, Zhou J, Pan J (2021): Estimating the sample mean and standard deviation from order statistics and sample size in meta-analysis. Statistical Methods in Medical Research, 30, 2701–2719
Luo D, Wan X, Liu J, Tong T (2018): Optimally estimating the sample mean from the sample size, median, mid-range, and/or mid-quartile range. Statistical Methods in Medical Research, 27, 1785–805
McGrath S, Zhao X, Steele R, et al. and the DEPRESsion Screening Data (DEPRESSD) Collaboration (2020): Estimating the sample mean and standard deviation from commonly reported quantiles in meta-analysis. Statistical Methods in Medical Research, 29, 2520–2537
Shi J, Luo D, Weng H, Zeng X-T, Lin L, Chu H, et al. (2020): Optimally estimating the sample standard deviation from the five-number summary. Research Synthesis Methods.
Van den Noortgate W, López-López JA, Marín-Martínez F, Sánchez-Meca J (2013): Three-level meta-analysis of dependent effect sizes. Behavior Research Methods, 45, 576–94
Wan X, Wang W, Liu J, Tong T (2014): Estimating the sample mean and standard deviation from the sample size, median, range and/or interquartile range. BMC Medical Research Methodology, 14, 135
See Also
meta-package, update.meta,
metamean, metagen
Examples
m1 <- metamean(rep(100, 3), 1:3, rep(1, 3))
m1
m2 <- update(m1, sm = "MLN")
m2
# With test for overall mean equal to 2
#
update(m1, null.effect = 2)
update(m2, null.effect = 2)
# Print results without back-transformation
#
update(m1, backtransf = FALSE)
update(m2, backtransf = FALSE)
update(m1, null.effect = 2, backtransf = FALSE)
update(m2, null.effect = 2, backtransf = FALSE)
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