用于计算对数的化学反应网络。

IF 2.6 Q2 BIOCHEMICAL RESEARCH METHODS
Synthetic biology (Oxford, England) Pub Date : 2017-04-28 eCollection Date: 2017-01-01 DOI:10.1093/synbio/ysx002
Chun Tung Chou
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引用次数: 0

摘要

活细胞不断处理来自生活环境的信息。最近的研究表明,一些细胞信号传导机制(如 G 蛋白偶联受体和表皮生长因子)可以解释为计算配体浓度的对数。这表明,对数是细胞中最基本的计算原素。合成生物学界对实现模拟计算的兴趣也与日俱增,计算对数就是其中一个例子。本文旨在研究如何利用化学反应网络(CRN)实现对数计算。CRN 无法精确计算对数。标准方法是使用幂级数或有理函数近似法来近似计算对数。虽然 CRN 可以直接实现这些多项式或有理函数计算,但问题在于,为了能够在较大输入范围内精确计算对数,必须使用高阶近似,从而导致 CRN 具有大量反应。本文提出了一种在 CRN 中精确计算对数的新方法,同时保持 CRN 中较少的反应数。通过调整两个设计参数,本文提出的方法可以创建计算对数精度不同的 CRN。本文介绍了实现计算对数的 CRN 所需的化学反应。本文的主要贡献是提出了一种新方法,只需少量化学反应,就能创建可在宽输入范围内精确计算对数的 CRN。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Chemical reaction networks for computing logarithm.

Chemical reaction networks for computing logarithm.

Chemical reaction networks for computing logarithm.

Chemical reaction networks for computing logarithm.

Living cells constantly process information from their living environment. It has recently been shown that a number of cell signaling mechanisms (e.g. G protein-coupled receptor and epidermal growth factor) can be interpreted as computing the logarithm of the ligand concentration. This suggests that logarithm is a fundamental computation primitive in cells. There is also an increasing interest in the synthetic biology community to implement analog computation and computing the logarithm is one such example. The aim of this article is to study how the computation of logarithm can be realized using chemical reaction networks (CRNs). CRNs cannot compute logarithm exactly. A standard method is to use power series or rational function approximation to compute logarithm approximately. Although CRNs can realize these polynomial or rational function computations in a straightforward manner, the issue is that in order to be able to compute logarithm accurately over a large input range, it is necessary to use high-order approximation that results in CRNs with a large number of reactions. This article proposes a novel method to compute logarithm accurately in CRNs while keeping the number of reactions in CRNs low. The proposed method can create CRNs that can compute logarithm to different levels of accuracy by adjusting two design parameters. In this article, we present the chemical reactions required to realize the CRNs for computing logarithm. The key contribution of this article is a novel method to create CRNs that can compute logarithm accurately over a wide input range using only a small number of chemical reactions.

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