Von Foerster equation
The McKendrick–von Foerster equation is a linear first-order partial differential equation encountered in several areas of mathematical biology – for example, demography[1] and cell proliferation modeling; it is applied when age structure is an important feature in the mathematical model.[2] It was first presented by Anderson Gray McKendrick in 1926 as a deterministic limit of lattice models applied to epidemiology,[3] and subsequently independently in 1959 by biophysics professor Heinz von Foerster for describing cell cycles.
Mathematical formula
[edit]The mathematical formula can be derived from first principles. It reads:
where the population density is a function of age and time , and is the death function. When , we have:[2]
It relates that a population ages, and that fact is the only one that influences change in population density; the negative sign shows that time flows in just one direction, that there is no birth and the population is going to die out.
Derivation
[edit]Suppose that for a change in time and change in age , the population density is:That is, during a time period the population density decreases by a percentage . Taking a Taylor series expansion to order gives us that:We know that , since the change of age with time is 1. Therefore, after collecting terms, we must have that:
Analytical solution
[edit]The von Foerster equation is a continuity equation; it can be solved using the method of characteristics.[2] Another way is by similarity solution; and a third is a numerical approach such as finite differences.
To get the solution, the following boundary conditions should be added:
which states that the initial births should be conserved (see Sharpe–Lotka–McKendrick’s equation for otherwise), and that:
which states that the initial population must be given; then it will evolve according to the partial differential equation.
Similar equations
[edit]In Sebastian Aniţa, Viorel Arnăutu, Vincenzo Capasso. An Introduction to Optimal Control Problems in Life Sciences and Economics (Birkhäuser. 2011), this equation appears as a special case of the Sharpe–Lotka–McKendrick’s equation; in the latter there is inflow, and the math is based on directional derivative. The McKendrick’s equation appears extensively in the context of cell biology as a good approach to model the eukaryotic cell cycle.[4]
See also
[edit]- Finite difference method
- Partial differential equation
- Renewal theory
- Continuity equation
- Volterra integral equation
References
[edit]- ^ Keyfitz, B. L.; Keyfitz, N. (1997-09-01). "The McKendrick partial differential equation and its uses in epidemiology and population study". Mathematical and Computer Modelling. 26 (6): 1–9. doi:10.1016/S0895-7177(97)00165-9. ISSN 0895-7177. S2CID 15550610.
- ^ a b c Murray, J.D. (2002). Mathematical Biology I: An Introduction. Interdisciplinary Applied Mathematics. Vol. 17 (3rd ed.). Springer. ISBN 0-387-95223-3.
- ^ McKendrick, A. G. (1926). "Applications of Mathematics to Medical Problems". Proceedings of the Edinburgh Mathematical Society. 44: 98–130. doi:10.1017/S0013091500034428. ISSN 1464-3839.
- ^ Gavagnin, Enrico (14 October 2018). "The invasion speed of cell migration models with realistic cell cycle time distributions". Journal of Theoretical Biology. 79 (1): 91–99. arXiv:1806.03140. Bibcode:2019JThBi.481...91G. doi:10.1016/j.jtbi.2018.09.010. PMID 30219568. S2CID 47015362.