In many biological systems, chemical reactions or changes in a physical
state are assumed to occur instantaneously. For describing the dynamics of those
systems, Markov models that require exponentially distributed inter-event times have
been used widely. However, some biophysical processes such as gene transcription
and translation are known to have a signi�cant gap between the initiation and
the completion of the processes, which renders the usual assumption of exponential
distribution untenable. In this paper, we consider relaxing this assumption by
incorporating age-dependent random time delays (distributed according to a given
probability distribution) into the system dynamics. We do so by constructing a
measure-valued Markov process on a more abstract state space, which allows us to
keep track of the "ages" of molecules participating in a chemical reaction.
We study the large-volume limit of such age-structured systems. We show that,
when appropriately scaled, the stochastic system can be approximated by a system of
Partial Di�erential Equations (PDEs) in the large-volume limit, as opposed to Ordinary
Di�erential Equations (ODEs) in the classical theory. We show how the limiting PDE
system can be used for the purpose of further model reductions and for devising e�cient
simulation algorithms. In order to describe the ideas, we use a simple transcription
process as a running example. We, however, note that the methods developed in this
paper apply to a wide class of biophysical systems. |
