一种新的估计振荡生化系统参数的代价函数。

Seyedbehzad Nabavi, Cranos M Williams
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引用次数: 2

摘要

振荡通路是生物化学系统中最重要的一类,其例子包括昼夜节律和细胞周期维持。这些高度互联的生化网络的数学建模需要满足许多目标,如调查,预测和控制这些系统的动态。确定动力学速率参数对于充分模拟这些和其他生物过程至关重要。然而,这些动力学参数通常不能从测量中得到,它们中的大多数必须通过参数拟合技术来估计。估计振荡系统动力学参数的问题之一是用于估计这些参数的最小二乘(LS)代价函数表面的不规则性,这是由测量的周期性引起的。这些不规则性导致了大量的局部最小值,从而限制了一些最健壮的全局优化算法的性能。我们提出了一个参数估计框架来解决这些问题,该框架将时间信息与嵌入在用于估计这些参数的测量中的周期性信息集成在一起。利用这些周期性信息构建具有更好表面特性的成本函数,从而减少局部极小值,提高全局优化算法的性能。我们对三个振荡生化系统进行了验证,与传统的LS成本函数相比,我们提出的成本函数可以提高估计准确动力学参数的能力。我们将此成本函数与改进的噪声去除方法相结合,该方法利用嵌入在测量中的周期性特征来有效地降低噪声。实验结果有力地证明了这种去噪方法比以往常用的小波硬阈值去噪方法的有效性。提出的优化框架将产生更精确的动力学参数,最终导致更精确、可预测和可控的生化模型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A novel cost function to estimate parameters of oscillatory biochemical systems.

A novel cost function to estimate parameters of oscillatory biochemical systems.

A novel cost function to estimate parameters of oscillatory biochemical systems.

A novel cost function to estimate parameters of oscillatory biochemical systems.

Oscillatory pathways are among the most important classes of biochemical systems with examples ranging from circadian rhythms and cell cycle maintenance. Mathematical modeling of these highly interconnected biochemical networks is needed to meet numerous objectives such as investigating, predicting and controlling the dynamics of these systems. Identifying the kinetic rate parameters is essential for fully modeling these and other biological processes. These kinetic parameters, however, are not usually available from measurements and most of them have to be estimated by parameter fitting techniques. One of the issues with estimating kinetic parameters in oscillatory systems is the irregularities in the least square (LS) cost function surface used to estimate these parameters, which is caused by the periodicity of the measurements. These irregularities result in numerous local minima, which limit the performance of even some of the most robust global optimization algorithms. We proposed a parameter estimation framework to address these issues that integrates temporal information with periodic information embedded in the measurements used to estimate these parameters. This periodic information is used to build a proposed cost function with better surface properties leading to fewer local minima and better performance of global optimization algorithms. We verified for three oscillatory biochemical systems that our proposed cost function results in an increased ability to estimate accurate kinetic parameters as compared to the traditional LS cost function. We combine this cost function with an improved noise removal approach that leverages periodic characteristics embedded in the measurements to effectively reduce noise. The results provide strong evidence on the efficacy of this noise removal approach over the previous commonly used wavelet hard-thresholding noise removal methods. This proposed optimization framework results in more accurate kinetic parameters that will eventually lead to biochemical models that are more precise, predictable, and controllable.

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