Many processes in science and engineering can be described by dynamical systems based on nonlinear ordinary differential equations (ODEs). Often ODE parameters are unknown and not directly measurable. Since nonlinear ODEs typically have no closed form solution, standard iterative inference procedures require a computationally expensive numerical integration of the ODEs every time the parameters are adapted, which in practice restricts statistical inference to very small systems. To overcome this computational bottleneck, approximate methods based on gradient matching have recently gained much attention.
In this package, we develop an easy-to-use application in Shiny to
perform parameter inference on ODEs using gradient matching. The
application, called shinyKGode, is built upon the KGode package, which
implements the kernel ridge regression and the gradient matching
algorithm proposed in Niu et
al. (2016) and the warping algorithm proposed in Niu
et al. (2017) for parameter inference in differential equations.
Advanced features such as ODE regularisation and warping can also be
easily used for inference in the shinyKGode
application.
shinyKGode has built-in support for the following three
models described in Niu
et al. (2017): - Lotka-Volterra,
which describes the dynamics of ecological systems with predator-prey
interactions. - FitzHugh–Nagumo),
which is a two-dimensional dynamical system used for modelling spike
generation in axons. - The Biopathway model described in y
Vyshemirsky and Girolami (2008), which is a model for the
interactions of five protein isoforms.
On top of that, shinyKGode also accepts user-defined
models in SBML v2 format. This allows user-defined models specified in
the SBML format to be
loaded into the application.
For loading of SBML, shinyKGode relies on a modified version of SBMLR
(with some bugfixes), so a limited range of SBML level v2 model files
that can be parsed by SBMLR
is supported and can be loaded into the application. Notably, this means
only SBML v2 specifications is supported and not v3 yet.
Models exported from Copasi can be loaded into the application after
some adjustments. These Copasi-generated SBML files often contain user-defined
functions, which are also not supported by the SBMLR parser that
shinyKGode uses. In this case, we suggest removing
user-defined functions from the SBML file (generated by Copasi) and
encoding their kinetic laws directly in the reaction sections of the
SBML file.
Below are the links to some example SBML files that you can load into
shinyKGode. - The
Lotka-Volterra model - The
FitzHugh–Nagumo model
The example SBML files above can be used as the starting point to encoding your own models. Note that SBML files are text-based markup languages, which can be edited in either text editors or specialised SBML editors.
The latest version of the shinyKGode package can be
installed from this github repository using devtools:
library(devtools)
install_github('joewandy/shinyKGode')While the stable R package can be installed from CRAN via
install.packages('shinyKGode').
Once installed, the application can be run by:
library(shinyKGode)
startShinyKGode()The following video demonstrates the benefits of using ODE
regularisation when inferring parameters using gradient matching in the
shinyKGode package.