An update of nanotopographical surfaces in modulating stem cell fate: a narrative review.

Biomaterials Translational Pub Date : 2022-03-28 eCollection Date: 2022-01-01 DOI:10.12336/biomatertransl.2022.01.006
Shuqin Cao, Quan Yuan
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引用次数: 2

Abstract

Stem cells have been one of the ideal sources for tissue regeneration owing to their capability of self-renewal and differentiation. In vivo, the extracellular microenvironment plays a vital role in modulating stem cell fate. When developing biomaterials for regenerative medicine, incorporating biochemical and biophysical cues to mimic extracellular matrix can enhance stem cell lineage differentiation. More specifically, modulating the stem cell fate can be achieved by controlling the nanotopographic features on synthetic surfaces. Optimization of nanotopographical features leads to desirable stem cell functions, which can maximize the effectiveness of regenerative treatment. In this review, nanotopographical surfaces, including static patterned surface, dynamic patterned surface, and roughness are summarized, and their fabrication, as well as the impact on stem cell behaviour, are discussed. Later, the recent progress of applying nanotopographical featured biomaterials for altering different types of stem cells is presented, which directs the design and fabrication of functional biomaterial. Last, the perspective in fundamental research and for clinical application in this field is discussed.

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纳米形貌表面在调节干细胞命运的更新:叙述回顾。
干细胞具有自我更新和分化的能力,已成为组织再生的理想来源之一。在体内,细胞外微环境在调节干细胞命运中起着至关重要的作用。在开发用于再生医学的生物材料时,结合生物化学和生物物理线索来模拟细胞外基质可以增强干细胞谱系分化。更具体地说,可以通过控制合成表面的纳米形貌特征来调节干细胞的命运。纳米形貌特征的优化导致理想的干细胞功能,这可以最大限度地提高再生治疗的有效性。在这篇综述中,纳米形貌表面,包括静态图像化表面,动态图像化表面和粗糙度进行了总结,并讨论了它们的制造,以及对干细胞行为的影响。随后,介绍了纳米形貌特征生物材料在不同类型干细胞改造中的应用进展,这对功能性生物材料的设计和制造具有指导意义。最后,对该领域的基础研究和临床应用前景进行了展望。
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