Fit a kinetic model to data with one or more state variables

Usage

mkinfit(mkinmod, observed,  parms.ini = "auto", state.ini = "auto", fixed_parms = NULL, fixed_initials = names(mkinmod$diffs)[-1],  solution_type = c("auto", "analytical", "eigen", "deSolve"), method.ode = "lsoda", use_compiled = "auto", method.modFit = c("Port", "Marq", "SANN", "Nelder-Mead", "BFGS", "CG", "L-BFGS-B"), maxit.modFit = "auto", control.modFit = list(), transform_rates = TRUE, transform_fractions = TRUE, plot = FALSE, quiet = FALSE, err = NULL, weight = "none",  scaleVar = FALSE,  atol = 1e-8, rtol = 1e-10, n.outtimes = 100,  reweight.method = NULL, reweight.tol = 1e-8, reweight.max.iter = 10, trace_parms = FALSE, ...)

Arguments

mkinmod

A list of class mkinmod, containing the kinetic model to be fitted to the data, or one of the shorthand names ("SFO", "FOMC", "DFOP", "HS", "SFORB"). If a shorthand name is given, a parent only degradation model is generated for the variable with the highest value in observed.

observed

The observed data. It has to be in the long format as described in modFit, i.e. the first column called "name" must contain the name of the observed variable for each data point. The second column must contain the times of observation, named "time". The third column must be named "value" and contain the observed values. Optionally, a further column can contain weights for each data point. If it is not named "err", its name must be passed as a further argument named err which is then passed on to modFit.

parms.ini

A named vector of initial values for the parameters, including parameters to be optimised and potentially also fixed parameters as indicated by fixed_parms. If set to "auto", initial values for rate constants are set to default values. Using parameter names that are not in the model gives an error. It is possible to only specify a subset of the parameters that the model needs. You can use the parameter lists "bparms.ode" from a previously fitted model, which contains the differential equation parameters from this model. This works nicely if the models are nested. An example is given below.

state.ini

A named vector of initial values for the state variables of the model. In case the observed variables are represented by more than one model variable, the names will differ from the names of the observed variables (see map component of mkinmod). The default is to set the initial value of the first model variable to the mean of the time zero values for the variable with the maximum observed value, and all others to 0. If this variable has no time zero observations, its initial value is set to 100.

fixed_parms

The names of parameters that should not be optimised but rather kept at the values specified in parms.ini.

fixed_initials

The names of model variables for which the initial state at time 0 should be excluded from the optimisation. Defaults to all state variables except for the first one.

solution_type

If set to "eigen", the solution of the system of differential equations is based on the spectral decomposition of the coefficient matrix in cases that this is possible. If set to "deSolve", a numerical ode solver from package deSolve is used. If set to "analytical", an analytical solution of the model is used. This is only implemented for simple degradation experiments with only one state variable, i.e. with no metabolites. The default is "auto", which uses "analytical" if possible, otherwise "eigen" if the model can be expressed using eigenvalues and eigenvectors, and finally "deSolve" for the remaining models (time dependence of degradation rates and metabolites). This argument is passed on to the helper function mkinpredict.

method.ode

The solution method passed via mkinpredict to ode in case the solution type is "deSolve". The default "lsoda" is performant, but sometimes fails to converge.

use_compiled

If set to FALSE, no compiled version of the mkinmod model is used, in the calls to mkinpredict even if a compiled verion is present.

method.modFit

The optimisation method passed to modFit. In order to optimally deal with problems where local minima occur, the "Port" algorithm is now used per default as it is less prone to get trapped in local minima and depends less on starting values for parameters than the Levenberg Marquardt variant selected by "Marq". However, "Port" needs more iterations. The former default "Marq" is the Levenberg Marquardt algorithm nls.lm from the package minpack.lm and usually needs the least number of iterations. The "Pseudo" algorithm is not included because it needs finite parameter bounds which are currently not supported. The "Newton" algorithm is not included because its number of iterations can not be controlled by control.modFit and it does not appear to provide advantages over the other algorithms.

maxit.modFit

Maximum number of iterations in the optimisation. If not "auto", this will be passed to the method called by modFit, overriding what may be specified in the next argument control.modFit.

control.modFit

Additional arguments passed to the optimisation method used by modFit.

transform_rates

Boolean specifying if kinetic rate constants should be transformed in the model specification used in the fitting for better compliance with the assumption of normal distribution of the estimator. If TRUE, also alpha and beta parameters of the FOMC model are log-transformed, as well as k1 and k2 rate constants for the DFOP and HS models and the break point tb of the HS model. If FALSE, zero is used as a lower bound for the rates in the optimisation.

transform_fractions

Boolean specifying if formation fractions constants should be transformed in the model specification used in the fitting for better compliance with the assumption of normal distribution of the estimator. The default (TRUE) is to do transformations. If TRUE, the g parameter of the DFOP and HS models are also transformed, as they can also be seen as compositional data. The transformation used for these transformations is the ilr transformation.

plot

Should the observed values and the numerical solutions be plotted at each stage of the optimisation?

quiet

Suppress printing out the current model cost after each improvement?

err

either NULL, or the name of the column with the error estimates, used to weigh the residuals (see details of modCost); if NULL, then the residuals are not weighed.

weight

only if err=NULL: how to weight the residuals, one of "none", "std", "mean", see details of modCost.

scaleVar

Will be passed to modCost. Default is not to scale Variables according to the number of observations.

atol

Absolute error tolerance, passed to ode. Default is 1e-8, lower than in lsoda.

rtol

Absolute error tolerance, passed to ode. Default is 1e-10, much lower than in lsoda.

n.outtimes

The length of the dataseries that is produced by the model prediction function mkinpredict. This impacts the accuracy of the numerical solver if that is used (see solution_type argument. The default value is 100.

reweight.method

The method used for iteratively reweighting residuals, also known as iteratively reweighted least squares (IRLS). Default is NULL, the other method implemented is called "obs", meaning that each observed variable is assumed to have its own variance, this is estimated from the fit and used for weighting the residuals in each iteration until convergence of this estimate up to reweight.tol or up to the maximum number of iterations specified by reweight.max.iter.

reweight.tol

Tolerance for convergence criterion for the variance components in IRLS fits.

reweight.max.iter

Maximum iterations in IRLS fits.

trace_parms

Should a trace of the parameter values be listed?

...

Further arguments that will be passed to modFit.

Examples

# Use shorthand notation for parent only degradation
fit <- mkinfit("FOMC", FOCUS_2006_C, quiet = TRUE)
summary(fit)

mkin version:    0.9.41 
R version:       3.2.2 
Date of fit:     Mon Nov  9 09:06:03 2015 
Date of summary: Mon Nov  9 09:06:03 2015 

Equations:
d_parent = - (alpha/beta) * 1/((time/beta) + 1) * parent

Model predictions using solution type analytical 

Fitted with method Port using 64 model solutions performed in 0.18 s

Weighting: none

Starting values for parameters to be optimised:
         value   type
parent_0  85.1  state
alpha      1.0 deparm
beta      10.0 deparm

Starting values for the transformed parameters actually optimised:
              value lower upper
parent_0  85.100000  -Inf   Inf
log_alpha  0.000000  -Inf   Inf
log_beta   2.302585  -Inf   Inf

Fixed parameter values:
None

Optimised, transformed parameters with symmetric confidence intervals:
          Estimate Std. Error    Lower   Upper
parent_0  85.87000     2.2460 80.38000 91.3700
log_alpha  0.05192     0.1605 -0.34080  0.4446
log_beta   0.65100     0.2801 -0.03452  1.3360

Parameter correlation:
          parent_0 log_alpha log_beta
parent_0    1.0000   -0.2033  -0.3624
log_alpha  -0.2033    1.0000   0.9547
log_beta   -0.3624    0.9547   1.0000

Residual standard error: 2.275 on 6 degrees of freedom

Backtransformed parameters:
Confidence intervals for internally transformed parameters are asymmetric.
t-test (unrealistically) based on the assumption of normal distribution
for estimators of untransformed parameters.
         Estimate t value    Pr(>t)   Lower  Upper
parent_0   85.870  38.230 1.069e-08 80.3800 91.370
alpha       1.053   6.231 3.953e-04  0.7112  1.560
beta        1.917   3.570 5.895e-03  0.9661  3.806

Chi2 error levels in percent:
         err.min n.optim df
All data   6.657       3  6
parent     6.657       3  6

Estimated disappearance times:
        DT50  DT90 DT50back
parent 1.785 15.15     4.56

Data:
 time variable observed predicted residual
    0   parent     85.1    85.875  -0.7749
    1   parent     57.9    55.191   2.7091
    3   parent     29.9    31.845  -1.9452
    7   parent     14.6    17.012  -2.4124
   14   parent      9.7     9.241   0.4590
   28   parent      6.6     4.754   1.8460
   63   parent      4.0     2.102   1.8977
   91   parent      3.9     1.441   2.4590
  119   parent      0.6     1.092  -0.4919


# One parent compound, one metabolite, both single first order.
# Use mkinsub for convenience in model formulation. Pathway to sink included per default.
SFO_SFO <- mkinmod(
  parent = mkinsub("SFO", "m1"),
  m1 = mkinsub("SFO"))

Successfully compiled differential equation model from auto-generated C code.
# Fit the model to the FOCUS example dataset D using defaults
print(system.time(fit <- mkinfit(SFO_SFO, FOCUS_2006_D, 
                           solution_type = "eigen", quiet = TRUE)))

   user  system elapsed 
  1.180   1.196   0.889 

coef(fit)

         parent_0 log_k_parent_sink   log_k_parent_m1     log_k_m1_sink 
         99.59848          -3.03822          -2.98030          -5.24750 

endpoints(fit)

$ff
parent_sink   parent_m1     m1_sink 
   0.485524    0.514476    1.000000 

$SFORB
logical(0)

$distimes
             DT50      DT90
parent   7.022929  23.32967
m1     131.760712 437.69961


## Not run: 
# # deSolve is slower when no C compiler (gcc) was available during model generation
# print(system.time(fit.deSolve <- mkinfit(SFO_SFO, FOCUS_2006_D, 
#                            solution_type = "deSolve")))
# coef(fit.deSolve)
# endpoints(fit.deSolve)
# ## End(Not run)

# Use stepwise fitting, using optimised parameters from parent only fit, FOMC
## Not run: 
# FOMC_SFO <- mkinmod(
#   parent = mkinsub("FOMC", "m1"),
#   m1 = mkinsub("SFO"))
# # Fit the model to the FOCUS example dataset D using defaults
# fit.FOMC_SFO <- mkinfit(FOMC_SFO, FOCUS_2006_D)
# # Use starting parameters from parent only FOMC fit
# fit.FOMC = mkinfit("FOMC", FOCUS_2006_D, plot=TRUE)
# fit.FOMC_SFO <- mkinfit(FOMC_SFO, FOCUS_2006_D, 
#   parms.ini = fit.FOMC$bparms.ode, plot=TRUE)
# 
# # Use stepwise fitting, using optimised parameters from parent only fit, SFORB
# SFORB_SFO <- mkinmod(
#   parent = list(type = "SFORB", to = "m1", sink = TRUE),
#   m1 = list(type = "SFO"))
# # Fit the model to the FOCUS example dataset D using defaults
# fit.SFORB_SFO <- mkinfit(SFORB_SFO, FOCUS_2006_D)
# fit.SFORB_SFO.deSolve <- mkinfit(SFORB_SFO, FOCUS_2006_D, solution_type = "deSolve")
# # Use starting parameters from parent only SFORB fit (not really needed in this case)
# fit.SFORB = mkinfit("SFORB", FOCUS_2006_D)
# fit.SFORB_SFO <- mkinfit(SFORB_SFO, FOCUS_2006_D, parms.ini = fit.SFORB$bparms.ode)
# ## End(Not run)

## Not run: 
# # Weighted fits, including IRLS
# SFO_SFO.ff <- mkinmod(parent = mkinsub("SFO", "m1"),
#                       m1 = mkinsub("SFO"), use_of_ff = "max")
# f.noweight <- mkinfit(SFO_SFO.ff, FOCUS_2006_D)
# summary(f.noweight)
# f.irls <- mkinfit(SFO_SFO.ff, FOCUS_2006_D, reweight.method = "obs")
# summary(f.irls)
# f.w.mean <- mkinfit(SFO_SFO.ff, FOCUS_2006_D, weight = "mean")
# summary(f.w.mean)
# f.w.mean.irls <- mkinfit(SFO_SFO.ff, FOCUS_2006_D, weight = "mean",
#                          reweight.method = "obs")
# summary(f.w.mean.irls)
# ## End(Not run)

## Not run: 
# # Manual weighting
# dw <- FOCUS_2006_D
# errors <- c(parent = 2, m1 = 1)
# dw$err.man <- errors[FOCUS_2006_D$name]
# f.w.man <- mkinfit(SFO_SFO.ff, dw, err = "err.man")
# summary(f.w.man)
# f.w.man.irls <- mkinfit(SFO_SFO.ff, dw, err = "err.man",
#                        reweight.method = "obs")
# summary(f.w.man.irls)
# ## End(Not run)

See also

Author