通过生物工程对称性破缺实现有机体的极化

IF 2 Q3 NEUROSCIENCES
Jae Ryun Ryu , Kahee Ko , Woong Sun
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引用次数: 0

摘要

打破对称导致轴的形成和空间模式化,对于在器官组织中更准确地再现人类发育过程至关重要。虽然这些过程可通过多能干细胞的自组织能力自发发生,但它们往往会导致有机体内细胞类型的结构和组成发生变化。为解决这一局限性,越来越多的生物工程技术利用几何、拓扑和硬度因素来加强控制和一致性。在此,我们回顾了微图案、微流体、生物材料等自发方式和工程工具如何促进对称性打破过程,从而在胚泡、胚乳、神经元和神经有机体中形成胚层图案以及前后轴和背腹轴。此外,还讨论了通过融合过程由多个脑区组成的脑集合体。从模式化工具的角度概述类器官极化,可为提高类器官系统的生理相关性提供有价值的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Polarization of organoids by bioengineered symmetry breaking

Symmetry breaking leading to axis formation and spatial patterning is crucial for achieving more accurate recapitulation of human development in organoids. While these processes can occur spontaneously by self-organizing capabilities of pluripotent stem cells, they can often result in variation in structure and composition of cell types within organoids. To address this limitation, bioengineering techniques that utilize geometric, topological and stiffness factors are increasingly employed to enhance control and consistency. Here, we review how spontaneous manners and engineering tools such as micropattern, microfluidics, biomaterials, etc. can facilitate the process of symmetry breaking leading to germ layer patterning and the formation of anteroposterior and dorsoventral axes in blastoids, gastruloids, neuruloids and neural organoids. Furthermore, brain assembloids, which are composed of multiple brain regions through fusion processes are discussed. The overview of organoid polarization in terms of patterning tools can offer valuable insights for enhancing the physiological relevance of organoid system.

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来源期刊
IBRO Neuroscience Reports
IBRO Neuroscience Reports Neuroscience-Neuroscience (all)
CiteScore
2.80
自引率
0.00%
发文量
99
审稿时长
14 weeks
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