MZPAQ: a FASTQ data compression tool.

Q2 Decision Sciences

Source Code for Biology and Medicine Pub Date : 2019-06-03 eCollection Date: 2019-01-01 DOI:10.1186/s13029-019-0073-5

Achraf El Allali, Mariam Arshad

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引用次数: 5

Abstract

Background: Due to the technological progress in Next Generation Sequencing (NGS), the amount of genomic data that is produced daily has seen a tremendous increase. This increase has shifted the bottleneck of genomic projects from sequencing to computation and specifically storing, managing and analyzing the large amount of NGS data. Compression tools can reduce the physical storage used to save large amount of genomic data as well as the bandwidth used to transfer this data. Recently, DNA sequence compression has gained much attention among researchers.

Results: In this paper, we study different techniques and algorithms used to compress genomic data. Most of these techniques take advantage of some properties that are unique to DNA sequences in order to improve the compression rate, and usually perform better than general-purpose compressors. By exploring the performance of available algorithms, we produce a powerful compression tool for NGS data called MZPAQ. Results show that MZPAQ outperforms state-of-the-art tools on all benchmark datasets obtained from a recent survey in terms of compression ratio. MZPAQ offers the best compression ratios regardless of the sequencing platform or the size of the data.

Conclusions: Currently, MZPAQ's strength is its higher compression ratio as well as its compatibility with all major sequencing platforms. MZPAQ is more suitable when the size of compressed data is crucial, such as long-term storage and data transfer. More efforts will be made in the future to target other aspects such as compression speed and memory utilization.

Abstract Image

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MZPAQ: FASTQ数据压缩工具。

背景:由于下一代测序(NGS)技术的进步，每天产生的基因组数据量急剧增加。这一增长将基因组项目的瓶颈从测序转移到计算，特别是存储、管理和分析大量的NGS数据。压缩工具可以减少用于保存大量基因组数据的物理存储以及用于传输这些数据的带宽。近年来，DNA序列压缩技术受到了研究人员的广泛关注。结果:在本文中，我们研究了用于压缩基因组数据的不同技术和算法。这些技术中的大多数都利用DNA序列特有的一些特性来提高压缩率，并且通常比通用压缩器表现得更好。通过探索现有算法的性能，我们开发了一个强大的NGS数据压缩工具MZPAQ。结果表明，MZPAQ在最近的一项调查中获得的所有基准数据集的压缩比方面都优于最先进的工具。无论测序平台或数据大小如何，MZPAQ都提供最佳压缩比。结论:目前MZPAQ的优势在于其较高的压缩比以及与各大测序平台的兼容性。MZPAQ更适用于对压缩数据的大小要求非常严格的场合，如长期存储和数据传输等。将来还会在其他方面做出更多的努力，比如压缩速度和内存利用率。

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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来源期刊

Source Code for Biology and Medicine Decision Sciences-Information Systems and Management

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期刊介绍： Source Code for Biology and Medicine is a peer-reviewed open access, online journal that publishes articles on source code employed over a wide range of applications in biology and medicine. The journal"s aim is to publish source code for distribution and use in the public domain in order to advance biological and medical research. Through this dissemination, it may be possible to shorten the time required for solving certain computational problems for which there is limited source code availability or resources.