Genome-scale metabolic models in translational medicine: the current status and potential of machine learning in improving the effectiveness of the models

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Beste Turanli, Gizem Gulfidan, Ozge Onluturk Aydogan, Ceyda Kula, Gurudeeban Selvaraj and Kazim Yalcin Arga
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Abstract

The genome-scale metabolic model (GEM) has emerged as one of the leading modeling approaches for systems-level metabolic studies and has been widely explored for a broad range of organisms and applications. Owing to the development of genome sequencing technologies and available biochemical data, it is possible to reconstruct GEMs for model and non-model microorganisms as well as for multicellular organisms such as humans and animal models. GEMs will evolve in parallel with the availability of biological data, new mathematical modeling techniques and the development of automated GEM reconstruction tools. The use of high-quality, context-specific GEMs, a subset of the original GEM in which inactive reactions are removed while maintaining metabolic functions in the extracted model, for model organisms along with machine learning (ML) techniques could increase their applications and effectiveness in translational research in the near future. Here, we briefly review the current state of GEMs, discuss the potential contributions of ML approaches for more efficient and frequent application of these models in translational research, and explore the extension of GEMs to integrative cellular models.

Abstract Image

转化医学中的基因组尺度代谢模型:机器学习在提高模型有效性方面的现状和潜力
基因组尺度代谢模型(GEM)已成为系统级代谢研究的主要建模方法之一,并已在广泛的生物体和应用领域得到了广泛探索。由于基因组测序技术和现有生化数据的发展,可以为模式和非模式微生物以及多细胞生物(如人类和动物模型)重建 GEM。随着生物数据、新数学建模技术和自动 GEM 重建工具的发展,GEM 也将同步发展。高质量、特定背景的 GEM 是原始 GEM 的一个子集,其中去除了不活跃的反应,但保留了提取模型中的代谢功能,在模型生物中使用这些 GEM 和机器学习(ML)技术,可以在不久的将来提高它们在转化研究中的应用和有效性。在此,我们简要回顾了 GEM 的现状,讨论了 ML 方法在转化研究中更有效、更频繁地应用这些模型的潜在贡献,以及将 GEM 扩展到综合细胞模型的可能性。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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