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aux_regression = ~.trt
were
incorrectly omitting the treatment effects on the auxiliary parameter(s)
in some cases (#43).marginal_effects()
for survival outcomes
with a single target population previously gave an error.aux_regression
had been specified were giving an error
(#44). aux_regression
and aux_by
have no
effect for exponential models since there are no auxiliary (shape)
parameters and are ignored, now with a warning.c()
.predict()
outside of a
plot()
call no longer gives an error (#40).marginal_effects()
function produces
marginal treatment effects, as a wrapper around absolute predictions
from predict()
. For example, for an analysis with a binary
outcome marginal odds ratios, risk ratios, or risk differences may be
produced. For survival outcomes, marginal effects may be based on the
full range of predictions produced by predict()
, such as
marginal differences in restricted mean survival times, or time-varying
marginal hazard ratios.predict()
or
marginal_effects()
from ML-NMR models that may take longer
to run. These can be controlled with the new progress
argument.trt_ref
argument to
predict()
has been renamed to baseline_ref
;
using trt_ref
is now soft-deprecated. Renaming this
argument baseline_ref
follows the naming convention for the
other arguments (baseline_type
,
baseline_level
) that specify the details of a provided
baseline
distribution. This also makes way for the new
marginal_effects()
functionality.predict()
for AgD meta-regression
models with new data and baseline_type = "response"
to fail
with an error.plot.nma_data()
with weight_edges = TRUE
was
incorrect when a study had multiple arms of the same treatment. This now
correctly counts the number of studies making a comparison, rather than
the number of arms.set_ipd()
now has a Surv
argument for
specifying survival outcomes using survival::Surv()
, and a
new function set_agd_surv()
sets up aggregate data in the
form of event/censoring times (e.g. from digitized Kaplan-Meier curves)
and overall covariate summaries.aux_by
argument to nma()
.aux_regression
argument to nma()
, allowing
non-proportionality to be modelled by treatment and/or covariate effects
on the shapes or spline coefficients.predict()
method produces estimates of survival
probabilities, hazards, cumulative hazards, mean survival times,
restricted mean survival times, quantiles of the survival time
distribution, and median survival times. All of these predictions can be
plotted using the plot()
method.geom_km()
function assists in plotting Kaplan-Meier
curves from a network object, for example to overlay these on estimated
survival curves. The transform
argument can be used to
produce log-log plots for assessing the proportional hazards assumption,
along with cumulative hazards or log survival curves.ndmm_ipd
, ndmm_agd
, and
ndmm_agd_covs
.n_int
and half with n_int/2
integration points. Any Rhat or effective sample size warnings can then
be ascribed to either: non-convergence of the MCMC chains, requiring
increased number of iterations iter
in nma()
,
or; insufficient accuracy of numerical integration, requiring increased
number of integration points n_int
in
add_integration()
. Descriptive warning messages indicate
which is the case.int_check
argument
to nma()
, which is enabled (TRUE
) by
default.int_thin = 0
, and is now disabled by default. The
previous default was int_thin = max(n_int %/% 10, 1)
.n_int
in
add_integration()
has been lowered to 64. This is still a
conservative choice, and will be sufficient in many cases; the previous
default of 1000 was excessive.n_int
and disabling saving cumulative
integration points.dic()
now includes an option to use the pV
penalty instead of pD.baseline
and aux
arguments to
predict()
can now be specified as the name of a study in
the network, to use the parameter estimates from that study for
prediction.predict()
will now produce aggregate-level
predictions over a sample of individuals in newdata
for
ML-NMR models (previously newdata
had to include
integration points).plot.mcmc_array()
method, as a
shortcut for plot(summary(x), ...)
.plot.nma_data()
, using a custom
layout
that is not a string (e.g. a data frame of layout
coordinates) now works as expected when nudge > 0
.as.tibble.stan_nma()
and
as_tibble.stan_nma()
methods, to complement the existing
as.data.frame.stan_nma()
.weight_nodes = TRUE
, using the new
nudge
argument to plot.nma_data()
(#15).as_tibble()
or as.data.frame()
on an nma_summary
object
(such as relative effects or predictions) now includes columns for the
corresponding treatment (.trt
) or contrast
(.trta
and .trtb
), and a
.category
column may be included for multinomial models.
Previously these details were only present as part of the
parameter
columnlog_student_t()
, which can be used for positive-valued
parameters (e.g. heterogeneity variance).set_agd_contrast()
now produces an
informative error message when the covariance matrix implied by the
se
column is not positive definite. Previously this was
only checked by Stan after calling the nma()
function..trtclass
special in regression formulas, now main effects of
.trtclass
are always removed since these are collinear with
.trt
. This allows expansion of interactions with
*
to work properly, e.g. ~variable*.trtclass
,
whereas previously this resulted in an over-parametrised model.get_nodesplits()
when studies have
multiple arms of the same treatment.print.nma_data()
now prints the repeated arms when
studies have multiple arms of the same treatment.NA
in multi()
) (PR #11)consistency = "nodesplit"
in
nma()
. Comparisons to split can be chosen using the
nodesplit
argument, by default all possibly inconsistent
comparisons are chosen using get_nodesplits()
.
Node-splitting results can be summarised with
summary.nma_nodesplit()
and plotted with
plot.nodesplit_summary()
.add_integration()
for ML-NMR models is now adjusted to
the underlying Gaussian copula, so that the output correlations of the
integration points better match the requested input correlations. A new
argument cor_adjust
controls this behaviour, with options
"spearman"
, "pearson"
, or "none"
.
Although these correlations typically have little impact on the results,
for strict reproducibility the old behaviour from version 0.3.0 and
below is available with cor_adjust = "legacy"
.relative_effects()
and predict.stan_nma()
respectively, using the new argument
predictive_distribution = TRUE
.posterior_ranks()
or
posterior_rank_probs()
, when argument
sucra = TRUE
.trt
,
study
, or trt_class
are factors, previously
the order of levels was reset into natural sort order.options("contrasts")
.plot.nma_data()
no longer gives a ggplot
deprecation warning (PR #6).predict.stan_nma()
with a single covariate
when newdata
is a data.frame
(PR #7).predict.stan_nma()
on a
regression model with only contrast data and no newdata
or
baseline
specified now throws a descriptive error
message.baseline_type
and
baseline_level
arguments to
predict.stan_nma()
, which allow baseline distributions to
be specified on the response or linear predictor scale, and at the
individual or aggregate level.baseline
argument to
predict.stan_nma()
can now accept a (named) list of
baseline distributions if newdata
contains multiple
studies.newdata
arguments to
functions like relative_effects()
and
predict.stan_nma()
now give more informative error
messages.--run-donttest
run correctly.relative_effects()
with all_contrasts = TRUE
no longer gives an error for regression models.cor
in
add_integration()
is not required when only one covariate
is present.likelihood
and link
arguments in nma()
).set_*()
functions now accept
dplyr::mutate()
style semantics, allowing inline variable
transformations.multi()
for specifying the outcomes. Accompanied by a new
data set hta_psoriasis
and vignette.flat()
.as.array.stan_nma()
is now much more
efficient, meaning that many post-estimation functions are also now much
more efficient.plot.nma_dic()
is now more efficient,
particularly with large numbers of data points.plot.nma_dic()
with multiple data types has been
reversed for improved clarity (now AgD over the top of IPD).predict()
from ML-NMR / IPD regression models are now calculated in a much more
memory-efficient manner.weight_edges = TRUE
no
longer produce legends with non-integer values for the number of
studies.plot.nma_dic()
no longer gives an error when
attempting to specify .width
argument when producing
“dev-dev” plots.\donttest{}
instead of
\dontrun{}
plot()
method for
nma_data
objects.as.igraph()
, as_tbl_graph()
methods for nma_data
objects.relative_effects()
, posterior ranks with
posterior_ranks()
, and posterior rank probabilities with
posterior_rank_probs()
. These will be study-specific when a
regression model is given.predict()
method for stan_nma
objects.plot.nma_summary()
.sample_size
argument for
set_agd_*()
that:
center = TRUE
) in
nma()
when a regression model is given, replacing the
agd_sample_size
argument of nma()
plot()
method for nma_dic
objects produced by dic()
.link = "cloglog"
for binomial likelihoods.prior_het_type
.plot_prior_posterior()
.pairs()
.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.
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