BioCAE:组织器官生物制造的复杂生物系统新策略

J. Dernowsek, R. Rezende, J.V.L. da Silva
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引用次数: 4

摘要

生物制造作为一个跨学科领域,正在培养新的知识,并整合纳米技术、化学、生物学、物理学、材料科学、控制系统等领域,以完成生物工程功能复杂组织的挑战。集成平台和系统生物学的出现,可以在多尺度水平上理解复杂的生物系统,这将使生物制造生物结构的预测和创造成为可能。这种评估生物过程的系统分析(meta-analysis)或集成平台被命名为BioCAE,它将成为生物制造过程重要步骤的关键。生物计算辅助工程(BioCAE)是一种新的计算方法,用于理解和生物工程复杂组织(生物制造),使用不同方法的组合,如多尺度建模,计算机模拟,数据挖掘和系统生物学。此外,多智能体系统(MAS)由不同的相互作用的计算实体(称为agent)组成,也提供了一种有趣的方式来设计和实现生物系统的模拟,将它们与BioCAE的所有步骤集成在一起。MAS作为计算科学的一部分,已经成为处理和解决复杂问题的一个日益增长的领域。本文提出了一种方法,可以预测不同生物过程的发展和行为,如分子网络,基因相互作用,细胞,组织和器官,因为它的灵活性,除了提供一个新的前景在组织和器官的生物制造。
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BioCAE: A New Strategy of Complex Biological Systems for Biofabrication of Tissues and Organs
Biofabrication as an interdisciplinary area is fostering new knowledge and integration of areas like nanotechnology, chemistry, biology, physics, materials science, control systems, among many others, necessary to accomplish the challenge of bioengineering functional complex tissues. The emergence of integrated platforms and systems biology to understand complex biological systems in multiscale levels will enable the prediction and creation of biofabricated biological structures. This systematic analysis (meta-analysis) or integrated platforms for estimating biological process have been named as BioCAE, which will become the key for important steps of the biofabrication processes. Biological Computational Aided Engineering (BioCAE) is a new computational approach to understanding and bioengineer complex tissues (biofabrication) using a combination of different methods as multiscale modelling, computer simulations, data mining and systems biology. In addition, multi-agent systems (MAS), which are composed of different interacting computing entities called agents, also provide an interesting way to design and implement simulations of biological systems, integrating them with all steps of the BioCAE. MAS as a part of computational science have become a growing area to manipulate and solve complex problems. This paper presents an approach that will allow predicting the development and behavior of different biological processes such as molecular networks, gene interactions, cells, tissues and organs due to its flexibility, beyond to provide a new outlook in the biofabrication of tissues and organs.
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