Stem cell-based synthetic development: cellular components, embryonic models, and engineering approaches

HAN Yizhao; GUO Jia; SHAO Yue

doi:10.12211/2096-8280.2023-100

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Stem cell-based synthetic development: cellular components, embryonic models, and engineering approaches

Invited Review | 更新时间：2025-03-19

- Stem cell-based synthetic development: cellular components, embryonic models, and engineering approaches
- Synthetic Biology Journal Vol. 5, Issue 4, Pages: 734-753(2024)
- 作者机构：
  
  清华大学航天航空学院工程力学系，生物力学与医学工程研究所，北京 100084
- 作者简介：
- 基金信息：
- DOI：10.12211/2096-8280.2023-100
  CLC： Q819
- Received：01 December 2023，
  
  Revised：2024-03-04，
  
  Published：31 August 2024
- 稿件说明：
移动端阅览
韩宜钊，郭佳，邵玥. 干细胞模拟发育：细胞元件、胚胎模型与工程方法［J］. 合成生物学， 2024， 5（4）： 734-753

HAN Yizhao， GUO Jia， SHAO Yue. Stem cell-based synthetic development： cellular components， embryonic models， and engineering approaches［J］. Synthetic Biology Journal， 2024， 5（4）： 734-753
韩宜钊，郭佳，邵玥. 干细胞模拟发育：细胞元件、胚胎模型与工程方法［J］. 合成生物学， 2024， 5（4）： 734-753 DOI： 10.12211/2096-8280.2023-100.

HAN Yizhao， GUO Jia， SHAO Yue. Stem cell-based synthetic development： cellular components， embryonic models， and engineering approaches［J］. Synthetic Biology Journal， 2024， 5（4）： 734-753 DOI： 10.12211/2096-8280.2023-100.

摘要

近百年来，胚胎发育的理论基础主要源于对模式动物的研究，珍稀哺乳动物的发育研究一直受到种间差异、伦理及技术手段等条件的制约。随着干细胞技术的迅猛发展，研究者们利用干细胞构建体外胚胎模型突破传统发育研究的局限性。目前，胚胎模型是否能够完全模拟真实胚胎的发育过程尚待验证，但这无疑为发育生物学研究带来新的可能性。本文以小鼠和人为主要讨论模型，总结用于构建胚胎模型的干细胞种类，阐释不同干细胞在模拟发育过程中的作用和重要性。文章系统呈现了胚胎在不同发育阶段的关键事件和时空动态过程，全面阐述胚胎模型取得的显著成果，详细探讨如何评估胚胎模型的仿生度，以及生物工程学方法在胚胎模型开发中的关键作用，为胚胎模型的进一步优化和发展提供参考。通过对胚胎模型领域的深入研究，有助于更全面细致地了解胚胎发育过程，并为早期发育研究、疾病研究、药物筛选、生殖医学及毒性评估等领域提供更为精确的理论依据和应用工具，进而为未来生命科学的发展开辟新的途径。

Abstract

Over the past century

the scientific foundation of embryonic development has primarily relied upon meticulous examination of developmental processes in model organisms. However

investigating the development of mammals has presented numerous challenges

including interspecies disparities

ethical considerations

and technical constraints. With the rapid advancement of stem cell technology

researchers have endeavored to overcome these obstacles by harnessing the potential of stem cells to generate sophisticated

vitro

embryo models. The rapid advancement of stem cell technology has revolutionized our approach to study embryonic development. While the ability of current embryo models to fully simulate the authentic developmental process is yet to be verified

they undeniably present new possibilities for developmental biology research. This review primarily focuses on mouse and human

summarizing the types of stem cells used in constructing embryo models and elucidating the roles and importance of different stem cells in simulating developmental processes. This review systematically presents and dissects crucial events and spatiotemporal dynamics in the embryonic development of both mice and humans across various stages. We thoroughly discuss the remarkable milestones achieved by existing embryo models

explore methods for evaluating the biomimicry of these models

and highlight the crucial role of bioengineering methods in embryo model development. The pivotal role of bioengineering in advancing embryonic model development is underscored

emphasizing its indispensable contribution to providing the requisite technical scaffolding for the realization of instruct multicellular induced self-organization with h

igh-level spatiotemporal orders. Additionally

we provide perspectives for the optimization and progressive refinement of embryo models

so as to improve their relevance and applicability. In summary

engineered advances in stem cell-based synthetic development could not only improve our understanding of the inherent complexities of embryos

but also hold the potential for applications in disease research

drug screening

reproductive medicine

toxicological assessments

and other related fields

thereby opening new avenues for both fundamental and translational research.

关键词

Keywords

references

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