用于组织发育和维持的多细胞模拟的自适应数值方法。

IF 1.9 4区 数学 Q2 BIOLOGY
James M. Osborne
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引用次数: 0

摘要

近年来,多细胞模型(将细胞表示为相互作用的单个实体)越来越流行。这导致了新方法和模拟工具的激增。本文的第一个目的是回顾多细胞建模工具所使用的数值方法,并展示哪些数值方法适合组织和器官发育及疾病模拟。第二个目的是介绍一种自适应时间步进算法,并展示其效率和准确性。我们的重点是基于力学的非晶格模型,细胞运动由一系列一阶常微分方程定义,这些方程是通过假设过阻尼运动和平衡力推导出来的。通过一系列示例性多细胞模拟,我们发现如果:注意让事件(出生、死亡和重新网格化/重新排列)发生在共同的时间步上;在数值方法的所有子步上施加边界或使用力来实现,那么所有数值方法都能以正确的阶次收敛。我们引入了一种自适应时间步法,并证明 L∞ 误差和运行时间之间的最佳折中方案是使用 Runge-Kutta 4,并增加时间步长和适度自适应。我们发现,与 Osborne 等人(2017 年)的前向欧拉方法相比,明智地选择数值方法可以将模拟速度提高 10-60 倍,而使用自适应时间步长可以进一步提高 4 倍。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
An adaptive numerical method for multi-cellular simulations of tissue development and maintenance

In recent years, multi-cellular models, where cells are represented as individual interacting entities, are becoming ever popular. This has led to a proliferation of novel methods and simulation tools. The first aim of this paper is to review the numerical methods utilised by multi-cellular modelling tools and to demonstrate which numerical methods are appropriate for simulations of tissue and organ development, maintenance, and disease. The second aim is to introduce an adaptive time-stepping algorithm and to demonstrate it’s efficiency and accuracy. We focus on off-lattice, mechanics based, models where cell movement is defined by a series of first order ordinary differential equations, derived by assuming over-damped motion and balancing forces. We see that many numerical methods have been used, ranging from simple Forward Euler approaches through to higher order single-step methods like Runge–Kutta 4 and multi-step methods like Adams–Bashforth 2. Through a series of exemplar multi-cellular simulations, we see that if: care is taken to have events (births deaths and re-meshing/re-arrangements) occur on common time-steps; and boundaries are imposed on all sub-steps of numerical methods or implemented using forces, then all numerical methods can converge with the correct order. We introduce an adaptive time-stepping method and demonstrate that the best compromise between L error and run-time is to use Runge–Kutta 4 with an increased time-step and moderate adaptivity. We see that a judicious choice of numerical method can speed the simulation up by a factor of 10–60 from the Forward Euler methods seen in Osborne et al. (2017), and a further speed up by a factor of 4 can be achieved by using an adaptive time-step.

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来源期刊
CiteScore
4.20
自引率
5.00%
发文量
218
审稿时长
51 days
期刊介绍: The Journal of Theoretical Biology is the leading forum for theoretical perspectives that give insight into biological processes. It covers a very wide range of topics and is of interest to biologists in many areas of research, including: • Brain and Neuroscience • Cancer Growth and Treatment • Cell Biology • Developmental Biology • Ecology • Evolution • Immunology, • Infectious and non-infectious Diseases, • Mathematical, Computational, Biophysical and Statistical Modeling • Microbiology, Molecular Biology, and Biochemistry • Networks and Complex Systems • Physiology • Pharmacodynamics • Animal Behavior and Game Theory Acceptable papers are those that bear significant importance on the biology per se being presented, and not on the mathematical analysis. Papers that include some data or experimental material bearing on theory will be considered, including those that contain comparative study, statistical data analysis, mathematical proof, computer simulations, experiments, field observations, or even philosophical arguments, which are all methods to support or reject theoretical ideas. However, there should be a concerted effort to make papers intelligible to biologists in the chosen field.
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