%0 Journal Article %1 Hasenauer2010 %A Hasenauer, J. %A Waldherr, S. %A Radde, N. %A Doszczak, M. %A Scheurich, P. %A Allgöwer, F. %D 2010 %I Elsevier %J Procedia Computer Science %K 2010 izi scheuric %N 1 %P 1655--1663 %R 10.1016/j.procs.2010.04.185 %T A maximum likelihood estimator for parameter distributions in heterogeneous cell populations %U https://www.sciencedirect.com/science/article/pii/S1877050910001869 %V 1 %X In many biologically relevant situations, cells of a clonal population show a heterogeneous response upon a common stimulus. The computational analysis of such situations requires the study of cell-cell variability and modeling of heterogeneous cell populations. In this work, we consider populations where the behavior of every single cell can be described by a system of ordinary differential equations. Heterogeneity among individual cells is modeled via differences in parameter values and initial conditions. Both are subject to a distribution function which is part of the cell population model. We present a novel approach to estimate the distribution of parameters and initial conditions from single cell measurements, e.g. flow cytometry and cytometric fluorescence microscopy. Therefore, a maximum likelihood estimator for the distribution is derived. The resulting optimization problem is reformulated via a parameterization of the distribution of parameters and initial conditions to allow the use of convex optimization techniques. To evaluate the proposed method, artificial data from a model of TNF signal transduction are considered. It is shown that the proposed method yields a good estimate of the parameter distributions in case of a limited amount of noise corrupted data.

@article{Hasenauer2010, abstract = {In many biologically relevant situations, cells of a clonal population show a heterogeneous response upon a common stimulus. The computational analysis of such situations requires the study of cell-cell variability and modeling of heterogeneous cell populations. In this work, we consider populations where the behavior of every single cell can be described by a system of ordinary differential equations. Heterogeneity among individual cells is modeled via differences in parameter values and initial conditions. Both are subject to a distribution function which is part of the cell population model. We present a novel approach to estimate the distribution of parameters and initial conditions from single cell measurements, e.g. flow cytometry and cytometric fluorescence microscopy. Therefore, a maximum likelihood estimator for the distribution is derived. The resulting optimization problem is reformulated via a parameterization of the distribution of parameters and initial conditions to allow the use of convex optimization techniques. To evaluate the proposed method, artificial data from a model of TNF signal transduction are considered. It is shown that the proposed method yields a good estimate of the parameter distributions in case of a limited amount of noise corrupted data.}, added-at = {2023-06-29T13:07:55.000+0200}, author = {Hasenauer, J. and Waldherr, S. and Radde, N. and Doszczak, M. and Scheurich, P. and Allg{\"{o}}wer, F.}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2929891be37587cef9d11b84cd2bd51c5/fabian}, doi = {10.1016/j.procs.2010.04.185}, interhash = {6775d1e569176a6ea0a701c4f9563edb}, intrahash = {929891be37587cef9d11b84cd2bd51c5}, issn = {18770509}, journal = {Procedia Computer Science}, keywords = {2010 izi scheuric}, month = may, number = 1, pages = {1655--1663}, publisher = {Elsevier}, timestamp = {2023-06-29T13:07:55.000+0200}, title = {{A maximum likelihood estimator for parameter distributions in heterogeneous cell populations}}, url = {https://www.sciencedirect.com/science/article/pii/S1877050910001869}, volume = 1, year = 2010 }