从非常大的生物网络中识别因果基因和通路的并行图理论方法

Proceedings of the Second International Conference on Internet of things, Data and Cloud Computing Pub Date : 2017-03-22 DOI:10.1145/3018896.3056793

Jeethu V. Devasia, P. Chandran, G. Shreya, A. R., Abijith R.

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引用次数: 1

摘要

对于大多数应用程序来说，从生物网络中计算有意义的信息所花费的时间非常高，因此这些网络很难处理。这项工作的重点是提高处理生物网络的速度，特别是更快地遍历基因组，这些基因组已经被映射到一个网络中，用于检测因果基因和相关途径。致病基因及其途径的推断在计算生物学中起着至关重要的作用，因为它在理解导致疾病状态的主要致病基因及其相互作用以及提出新的药物靶点方面具有实用性。在这项工作中，使用Hadoop的分布式存储系统来存储分子相互作用网络。利用Hadoop MapReduce的图并行处理技术，结合图理论方法，提高了结果的准确性和基准数据的执行时间。

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On parallelizing graph theoretical approaches for identifying causal genes and pathways from very large biological networks

The time taken to compute meaningful information from biological networks is very high for most of the applications and therefore these networks are very hard to process. This work focuses on improving the speed of processing biological networks, in particular, faster traversal of genomes which have been mapped into a network for the detection of causal genes and associated pathways. Inference of disease causing genes and their pathways has achieved a crucial role in computational biology because of its practicality in understanding the major causal genes and their interactions that lead to a disease state, and suggesting new drug targets. In this work, Hadoop's distributed storage system has been used to store the molecular interaction network. Graph parallel processing techniques of Hadoop MapReduce, in conjunction with graph theoretical approaches have been utilized to improve the accuracy of results and execution time on benchmark data.

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Proceedings of the Second International Conference on Internet of things, Data and Cloud Computing

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