nlmixr uses a unified interface for specifying and running models. Let’s start with a very simple PK example, using the single-dose theophylline dataset generously provided by Dr. Robert A. Upton of the University of California, San Francisco:
## Load libraries
library(nlmixr2)
str(theo_sd)
#> 'data.frame': 144 obs. of 7 variables:
#> $ ID : int 1 1 1 1 1 1 1 1 1 1 ...
#> $ TIME: num 0 0 0.25 0.57 1.12 2.02 3.82 5.1 7.03 9.05 ...
#> $ DV : num 0 0.74 2.84 6.57 10.5 9.66 8.58 8.36 7.47 6.89 ...
#> $ AMT : num 320 0 0 0 0 ...
#> $ EVID: int 101 0 0 0 0 0 0 0 0 0 ...
#> $ CMT : int 1 2 2 2 2 2 2 2 2 2 ...
#> $ WT : num 79.6 79.6 79.6 79.6 79.6 79.6 79.6 79.6 79.6 79.6 ...
We can try fitting a simple one-compartment PK model to this small dataset. We write the model as follows:
function() {
one.cmt <-ini({
## You may label each parameter with a comment
0.45 # Ka
tka <- log(c(0, 2.7, 100)) # Log Cl
tcl <-## This works with interactive models
## You may also label the preceding line with label("label text")
3.45; label("log V")
tv <-## the label("Label name") works with all models
~ 0.6
eta.ka ~ 0.3
eta.cl ~ 0.1
eta.v 0.7
add.sd <-
})model({
exp(tka + eta.ka)
ka <- exp(tcl + eta.cl)
cl <- exp(tv + eta.v)
v <-linCmt() ~ add(add.sd)
})
}
nlmixr(one.cmt) f <-
We can now run the model…
nlmixr(one.cmt, theo_sd, est="focei",
fit <-control=list(print=0))
#> calculating covariance matrix
#> [====|====|====|====|====|====|====|====|====|====] 0:00:00
#> done
print(fit)
#> ── nlmixr FOCEi (outer: nlminb) ──
#>
#> OBJF AIC BIC Log-likelihood Condition Number
#> FOCEi 116.8035 373.4033 393.5829 -179.7016 68.42019
#>
#> ── Time (sec $time): ──
#>
#> setup optimize covariance table compress other
#> elapsed 0.011502 0.12172 0.12172 0.025 0.007 0.834058
#>
#> ── Population Parameters ($parFixed or $parFixedDf): ──
#>
#> Parameter Est. SE %RSE Back-transformed(95%CI) BSV(CV%) Shrink(SD)%
#> tka Ka 0.464 0.195 42.1 1.59 (1.08, 2.33) 70.4 1.81%
#> tcl Log Cl 1.01 0.0751 7.42 2.75 (2.37, 3.19) 26.8 3.87%
#> tv log V 3.46 0.0437 1.26 31.8 (29.2, 34.6) 13.9 10.3%
#> add.sd 0.695 0.695
#>
#> Covariance Type ($covMethod): r,s
#> No correlations in between subject variability (BSV) matrix
#> Full BSV covariance ($omega) or correlation ($omegaR; diagonals=SDs)
#> Distribution stats (mean/skewness/kurtosis/p-value) available in $shrink
#> Minimization message ($message):
#> relative convergence (4)
#>
#> ── Fit Data (object is a modified tibble): ──
#> # A tibble: 132 × 20
#> ID TIME DV PRED RES WRES IPRED IRES IWRES CPRED CRES
#> <fct> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl>
#> 1 1 0 0.74 1.79e-15 0.740 1.07 0 0.74 1.07 -5.61e-16 0.740
#> 2 1 0.25 2.84 3.26e+ 0 -0.423 -0.225 3.85 -1.01 -1.45 3.22e+ 0 -0.379
#> 3 1 0.57 6.57 5.83e+ 0 0.740 0.297 6.78 -0.215 -0.309 5.77e+ 0 0.795
#> # … with 129 more rows, and 9 more variables: CWRES <dbl>, eta.ka <dbl>,
#> # eta.cl <dbl>, eta.v <dbl>, ka <dbl>, cl <dbl>, v <dbl>, tad <dbl>,
#> # dosenum <dbl>
We can alternatively express the same model by ordinary differential equations (ODEs):
function() {
one.compartment <-ini({
0.45 # Log Ka
tka <- 1 # Log Cl
tcl <- 3.45 # Log V
tv <-~ 0.6
eta.ka ~ 0.3
eta.cl ~ 0.1
eta.v 0.7
add.sd <-
})model({
exp(tka + eta.ka)
ka <- exp(tcl + eta.cl)
cl <- exp(tv + eta.v)
v <-/dt(depot) = -ka * depot
d/dt(center) = ka * depot - cl / v * center
d center / v
cp =~ add(add.sd)
cp
}) }
We can try the Stochastic Approximation EM (SAEM) method to this model:
nlmixr(one.compartment, theo_sd, est="saem",
fit2 <-control=list(print=0))
#> [====|====|====|====|====|====|====|====|====|====] 0:00:00
#>
#> [====|====|====|====|====|====|====|====|====|====] 0:00:00
#>
#> [====|====|====|====|====|====|====|====|====|====] 0:00:00
#>
#> [====|====|====|====|====|====|====|====|====|====] 0:00:00
#>
#> [====|====|====|====|====|====|====|====|====|====] 0:00:00
#>
#> [====|====|====|====|====|====|====|====|====|====] 0:00:00
#>
#> [====|====|====|====|====|====|====|====|====|====] 0:00:00
print(fit2)
#> ── nlmixr SAEM OBJF by FOCEi approximation ──
#>
#> Gaussian/Laplacian Likelihoods: AIC() or $objf etc.
#> FOCEi CWRES & Likelihoods: addCwres()
#>
#> ── Time (sec $time): ──
#>
#> setup covariance saem table compress other
#> elapsed 0.001197 0.007003 2.162 0.017 0.016 0.6608
#>
#> ── Population Parameters ($parFixed or $parFixedDf): ──
#>
#> Parameter Est. SE %RSE Back-transformed(95%CI) BSV(CV%) Shrink(SD)%
#> tka Log Ka 0.454 0.196 43.1 1.57 (1.07, 2.31) 71.5 -0.0203%
#> tcl Log Cl 1.02 0.0853 8.4 2.76 (2.34, 3.26) 27.6 3.46%
#> tv Log V 3.45 0.0454 1.32 31.5 (28.8, 34.4) 13.4 9.89%
#> add.sd 0.693 0.693
#>
#> Covariance Type ($covMethod): linFim
#> No correlations in between subject variability (BSV) matrix
#> Full BSV covariance ($omega) or correlation ($omegaR; diagonals=SDs)
#> Distribution stats (mean/skewness/kurtosis/p-value) available in $shrink
#>
#> ── Fit Data (object is a modified tibble): ──
#> # A tibble: 132 × 19
#> ID TIME DV PRED RES IPRED IRES IWRES eta.ka eta.cl eta.v cp
#> <fct> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl>
#> 1 1 0 0.74 0 0.74 0 0.74 1.07 0.103 -0.491 -0.0820 0
#> 2 1 0.25 2.84 3.27 -0.426 3.87 -1.03 -1.48 0.103 -0.491 -0.0820 3.87
#> 3 1 0.57 6.57 5.85 0.723 6.82 -0.246 -0.356 0.103 -0.491 -0.0820 6.82
#> # … with 129 more rows, and 7 more variables: depot <dbl>, center <dbl>,
#> # ka <dbl>, cl <dbl>, v <dbl>, tad <dbl>, dosenum <dbl>
And if we wanted to, we could even apply the traditional R method nlme method to this model:
nlmixr(one.compartment, theo_sd, list(pnlsTol=0.5), est="nlme")
fitN <-#> [====|====|====|====|====|====|====|====|====|====] 0:00:00
#>
#> [====|====|====|====|====|====|====|====|====|====] 0:00:00
#>
#>
#> **Iteration 1
#> LME step: Loglik: -183.2083, nlminb iterations: 1
#> reStruct parameters:
#> ID1 ID2 ID3
#> 0.2195819 0.9924330 1.6502972
#> Beginning PNLS step: .. completed fit_nlme() step.
#> PNLS step: RSS = 64.95306
#> fixed effects: 0.4464074 1.033353 3.45079
#> iterations: 3
#> Convergence crit. (must all become <= tolerance = 1e-05):
#> fixed reStruct
#> 0.03227684 0.54047252
#>
#> **Iteration 2
#> LME step: Loglik: -180.6328, nlminb iterations: 1
#> reStruct parameters:
#> ID1 ID2 ID3
#> 0.1425419 0.9780287 1.6452264
#> Beginning PNLS step: .. completed fit_nlme() step.
#> PNLS step: RSS = 64.95308
#> fixed effects: 0.4464074 1.033353 3.45079
#> iterations: 1
#> Convergence crit. (must all become <= tolerance = 1e-05):
#> fixed reStruct
#> 0.000000e+00 3.794674e-06
#> [====|====|====|====|====|====|====|====|====|====] 0:00:00
#>
#> [====|====|====|====|====|====|====|====|====|====] 0:00:00
print(fitN)
#> ── nlmixr nlme by maximum likelihood ──
#>
#> OBJF AIC BIC Log-likelihood Condition Number
#> nlme 118.6658 375.2656 395.4452 -180.6328 9.736076
#>
#> ── Time (sec $time): ──
#>
#> setup table compress other
#> elapsed 0.001135 0.017 0.003 1.407865
#>
#> ── Population Parameters ($parFixed or $parFixedDf): ──
#>
#> Parameter Est. SE %RSE Back-transformed(95%CI) BSV(CV%)
#> tka Log Ka 0.4464 0.1442 32.31 1.563 (1.178, 2.073) 66.6
#> tcl Log Cl 1.033 0.08626 8.347 2.81 (2.373, 3.328) 26.7
#> tv Log V 3.451 0.04622 1.34 31.53 (28.79, 34.51) 13.5
#> add.sd 0.6988 0.6988
#> Shrink(SD)%
#> tka -6.31%
#> tcl 7.24%
#> tv 7.82%
#> add.sd
#>
#> Covariance Type ($covMethod): nlme
#> No correlations in between subject variability (BSV) matrix
#> Full BSV covariance ($omega) or correlation ($omegaR; diagonals=SDs)
#> Distribution stats (mean/skewness/kurtosis/p-value) available in $shrink
#>
#> ── Fit Data (object is a modified tibble): ──
#> # A tibble: 132 × 19
#> ID TIME DV PRED RES IPRED IRES IWRES eta.ka eta.cl eta.v cp
#> <fct> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl>
#> 1 1 0 0.74 0 0.74 0 0.74 1.06 0.0740 -0.478 -0.0902 0
#> 2 1 0.25 2.84 3.24 -0.404 3.78 -0.944 -1.35 0.0740 -0.478 -0.0902 3.78
#> 3 1 0.57 6.57 5.81 0.756 6.72 -0.147 -0.210 0.0740 -0.478 -0.0902 6.72
#> # … with 129 more rows, and 7 more variables: depot <dbl>, center <dbl>,
#> # ka <dbl>, cl <dbl>, v <dbl>, tad <dbl>, dosenum <dbl>
This example delivers a complete model fit as the fit
object, including parameter history, a set of fixed effect estimates, and random effects for all included subjects.
The nlmixr modeling dialect, inspired by R and NONMEM, can be used to fit models using all current and future estimation algorithms within nlmixr. Using these widely-used tools as inspiration has the advantage of delivering a model specification syntax that is instantly familiar to the majority of analysts working in pharmacometrics and related fields.
Model specifications for nlmixr are written using functions containing ini
and model
blocks. These functions can be called anything, but must contain these two components. Let’s look at a very simple one-compartment model with no covariates.
function() {
f <-ini({ # Initial conditions/variables
# are specified here
})model({ # The model is specified
# here
}) }
The ini
block specifies initial conditions, including initial estimates and boundaries for those algorithms which support them (currently, the built-in nlme
and saem
methods do not). Nomenclature is similar to that used in NONMEM, Monolix and other similar packages. In the NONMEM world, the ini
block is analogous to $THETA
, $OMEGA
and $SIGMA
blocks.
function() { # Note that arguments to the function are currently
f <-# ignored by nlmixr
ini({
# Initial conditions for population parameters (sometimes
# called THETA parameters) are defined by either '<-' or '='
1.6 # log Cl (L/hr)
lCl <-
# Note that simple expressions that evaluate to a number are
# OK for defining initial conditions (like in R)
log(90) # log V (L)
lVc =
## Also, note that a comment on a parameter is captured as a parameter label
1 # log Ka (1/hr)
lKa <-
# Bounds may be specified by c(lower, est, upper), like NONMEM:
# Residuals errors are assumed to be population parameters
c(0, 0.2, 1)
prop.err <-
# IIV terms will be discussed in the next example
})
# The model block will be discussed later
model({})
}
As shown in the above example:
c(lower, est, upper)
.c(lower,est)
is equivalent to c(lower,est,Inf)
c(est)
does not specify a lower bound, and is equivalent to specifying the parameter without using R’s c()
function.These parameters can be named using almost any R-compatible name. Please note that:
=
or <-
, not ~
)._
are not supported. Note that R does not allow variable starting with _
to be assigned without quoting them.rx_
or nlmixr_
is not allowed, since rxode2()
and nlmixr use these prefixes internally for certain estimation routines and for calculating residuals.CL
is not the same as Cl
.In mixture models, multivariate normal individual deviations from the normal population and parameters are estimated (in NONMEM these are called “ETA” parameters). Additionally, the variance/covariance matrix of these deviations are is also estimated (in NONMEM this is the “OMEGA” matrix). These also take initial estimates. In nlmixr, these are specified by the ~
operator. This that is typically used in statistics R for “modeled by”, and was chosen to distinguish these estimates from the population and residual error parameters.
Continuing from the prior example, we can annotate the estimates for the between-subject error distribution…
function() {
f <-ini({
1.6 # log Cl (L/hr)
lCl <- log(90) # log V (L)
lVc = 1 # log Ka (1/hr)
lKa <- c(0, 0.2, 1)
prop.err <-
# Initial estimate for ka IIV variance
# Labels work for single parameters
~ 0.1 ## BSV Ka
eta.ka
# For correlated parameters, you specify the names of each
# correlated parameter separated by a addition operator `+`
# and the left handed side specifies the lower triangular
# matrix initial of the covariance matrix.
+ eta.vc ~ c(0.1,
eta.cl 0.005, 0.1)
# Note that labels do not currently work for correlated
# parameters. Also, do not put comments inside the lower
# triangular matrix as this will currently break the model.
})
# The model block will be discussed later
model({})
}
As shown in the above example:
~
.~
.Currently, comments inside the lower triangular matrix are not allowed.
The model
block specifies the model, and is analogous to the $PK
, $PRED
and $ERROR
blocks in NONMEM.
Once the initialization block has been defined, you can define a model in terms of the variables defined in the ini
block. You can also mix rxode2()
blocks into the model if needed.
The current method of defining a nlmixr model is to specify the parameters, and then any required rxode2()
lines. Continuing the annotated example:
function() {
f <-ini({
1.6 # log Cl (L/hr)
lCl <- log(90) # log Vc (L)
lVc <- 0.1 # log Ka (1/hr)
lKA <- c(0, 0.2, 1)
prop.err <-
~ 0.1 # BSV Cl
eta.Cl ~ 0.1 # BSV Vc
eta.Vc ~ 0.1 # BSV Ka
eta.KA
})model({
# Parameters are defined in terms of the previously-defined
# parameter names:
exp(lCl + eta.Cl)
Cl <- exp(lVc + eta.Vc)
Vc = exp(lKA + eta.KA)
KA <-
# Next, the differential equations are defined:
Cl / Vc;
kel <-
/dt(depot) = -KA*depot;
d/dt(centr) = KA*depot-kel*centr;
d
# And the concentration is then calculated
centr / Vc;
cp =# Finally, we specify that the plasma concentration follows
# a proportional error distribution (estimated by the parameter
# prop.err)
~ prop(prop.err)
cp
})
}
A few points to note:
rx_
or nlmixr_
since these are used internally in some estimation routines.~
. Currently you can use either add(parameter)
for additive error, prop(parameter)
for proportional error or add(parameter1) + prop(parameter2)
for combined additive and proportional error. You can also specify norm(parameter)
for additive error, since it follows a normal distribution.saem
, require parameters expressed in terms of Pop.Parameter + Individual.Deviation.Parameter + Covariate*Covariate.Parameter
. The order of these parameters does not matter. This is similar to NONMEM’s mu-referencing, though not as restrictive. This means that for saem
, a parameterization of the form Cl <- Cl*exp(eta.Cl)
is not allowed.ini
block; covariates used in the model are not included in the ini
block. These variables need to be present in the modeling dataset for the model to run.Models can be fitted several ways, including via the [magrittr] forward-pipe operator.
fit <- nlmixr(one.compartment) %>% saem.fit(data=theo_sd)
fit2 <- nlmixr(one.compartment, data=theo_sd, est="saem")
fit3 <- one.compartment %>% saem.fit(data=theo_sd)
Options to the estimation routines can be specified using nlmeControl for nlme estimation:
fit4 <- nlmixr(one.compartment, theo_sd,est="nlme",control = nlmeControl(pnlsTol = .5))
where options are specified in the nlme
documentation. Options for saem can be specified using saemControl
:
fit5 <- nlmixr(one.compartment,theo_sd,est="saem",control=saemControl(n.burn=250,n.em=350,print=50))
this example specifies 250 burn-in iterations, 350 em iterations and a print progress every 50 runs.
Solved PK systems are also currently supported by nlmixr with the ‘linCmt()’ pseudo-function. An annotated example of a solved system is below:
function(){
f <-ini({
1.6 #log Cl (L/hr)
lCl <- log(90) #log Vc (L)
lVc <- 0.1 #log Ka (1/hr)
lKA <- c(0, 0.2, 1)
prop.err <-~ 0.1 # BSV Cl
eta.Cl ~ 0.1 # BSV Vc
eta.Vc ~ 0.1 # BSV Ka
eta.KA
})model({
exp(lCl + eta.Cl)
Cl <- exp(lVc + eta.Vc)
Vc = exp(lKA + eta.KA)
KA <-## Instead of specifying the ODEs, you can use
## the linCmt() function to use the solved system.
##
## This function determines the type of PK solved system
## to use by the parameters that are defined. In this case
## it knows that this is a one-compartment model with first-order
## absorption.
linCmt() ~ prop(prop.err)
}) }
A few things to keep in mind: * Currently the solved systems support either oral dosing, IV dosing or IV infusion dosing and does not allow mixing the dosing types. * While rxode2()
allows mixing of solved systems and ODEs, this has not been implemented in nlmixr yet. * The solved systems implemented are the one, two and three compartment models with or without first-order absorption. Each of the models support a lag time with a tlag parameter. * In general the linear compartment model figures out the model by the parameter names. nlmixr currently knows about numbered volumes, Vc
/Vp
, Clearances in terms of both Cl
and Q
/CLD
. Additionally nlmixr knows about elimination micro-constants (ie K12
). Mixing of these parameters for these models is currently not supported.
After specifying the model syntax you can check that nlmixr is interpreting it correctly by using the nlmixr function on it. Using the above function we can get:
nlmixr(f)
#> ── rxode2-based solved PK 1-compartment model with first-order absorption ──────
#> ── Initalization: ──
#> Fixed Effects ($theta):
#> lCl lVc lKA prop.err
#> 1.60000 4.49981 0.10000 0.20000
#>
#> Omega ($omega):
#> eta.Cl eta.Vc eta.KA
#> eta.Cl 0.1 0.0 0.0
#> eta.Vc 0.0 0.1 0.0
#> eta.KA 0.0 0.0 0.1
#> ── μ-referencing ($muRefTable): ──
#> theta eta level
#> 1 lCl eta.Cl id
#> 2 lVc eta.Vc id
#> 3 lKA eta.KA id
#>
#> ── Model (Normalized Syntax): ──
#> function() {
#> ini({
#> lCl <- 1.6
#> label("log Cl (L/hr)")
#> lVc <- 4.49980967033027
#> label("log Vc (L)")
#> lKA <- 0.1
#> label("log Ka (1/hr)")
#> prop.err <- c(0, 0.2, 1)
#> eta.Cl ~ 0.1
#> eta.Vc ~ 0.1
#> eta.KA ~ 0.1
#> })
#> model({
#> Cl <- exp(lCl + eta.Cl)
#> Vc = exp(lVc + eta.Vc)
#> KA <- exp(lKA + eta.KA)
#> linCmt() ~ prop(prop.err)
#> })
#> }
In general this gives you information about the model (what type of solved system/rxode2()
), initial estimates as well as the code for the model block.