Efficient cancer therapy using Boolean networks and Max-SAT-based ATPG

2011 IEEE International Workshop on Genomic Signal Processing and Statistics (GENSIPS) Pub Date : 2011-12-01 DOI:10.1109/GENSiPS.2011.6169450

P. Lin, S. Khatri

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引用次数: 10

Abstract

Cancer and other gene related diseases are usually caused by a failure in the signaling pathway between genes and cells. These failures can occur in different areas of the gene regulatory network, but can be abstracted as faults in the regulatory function. For effective cancer treatment, it is imperative to identify faults and select appropriate drugs to treat the fault. In this paper, we present an extensible Max-SAT based automatic test pattern generation (ATPG) algorithm for cancer therapy. This ATPG algorithm is based on Boolean Satisfiability (SAT) and utilizes the stuck-at fault model for representing signalling faults. A weighted partial Max-SAT formulation is used to enable selection of the most effective drug. Several usage cases as presented for fault identification and drug selection. These include the identification of testable faults, optimal drug selection for single/multiple known faults, and optimal drug selection for overall fault coverage. Experimental results on growth factor (GF) signaling pathways demonstrate that our algorithm is flexible, and can yield an exact solution for each feature in much less than 1 second.

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利用布尔网络和基于max - sat的ATPG进行有效的癌症治疗

癌症和其他基因相关疾病通常是由基因和细胞之间的信号通路失效引起的。这些故障可能发生在基因调控网络的不同区域，但可以抽象为调控功能的故障。为了有效地治疗癌症，必须识别故障并选择合适的药物来治疗故障。在本文中，我们提出了一种可扩展的基于Max-SAT的癌症治疗自动测试模式生成(ATPG)算法。该算法以布尔可满足性(SAT)为基础，利用故障卡滞模型来表示信令故障。加权部分Max-SAT配方用于选择最有效的药物。给出了故障识别和药物选择的几个用例。这些包括可测试故障的识别，单个/多个已知故障的最佳药物选择，以及总体故障覆盖的最佳药物选择。生长因子(GF)信号通路的实验结果表明，我们的算法是灵活的，可以在不到1秒的时间内对每个特征产生精确的解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2011 IEEE International Workshop on Genomic Signal Processing and Statistics (GENSIPS)

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