Engineering Nanoclusters of Cell Adhesive Ligands on Biomaterial Surfaces: Superior Cell Proliferation and Myotube Formation for Skeletal Muscle Tissue Regeneration.

IF 10 2区 医学 Q1 ENGINEERING, BIOMEDICAL Advanced Healthcare Materials Pub Date : 2024-10-28 DOI:10.1002/adhm.202402991
Shirin Nour, Sadegh Shabani, Kristy Swiderski, Gordon S Lynch, Andrea J O'Connor, Greg Qiao, Daniel E Heath
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Abstract

Engineering biointerfaces with nanoscale clustering of integrin-binding cell adhesive peptides is critical for promoting receptor redistribution into signaling complexes. Skeletal muscle cells are exquisitely sensitive to integrin-mediated signaling, yet biomaterials supporting myogenesis through control of the density and nanodistribution of ligands have not been developed. Here, materials are developed with tailorable cell adhesive ligands distribution at the interface by independently controlling their global and local density to enhance myogenesis, by promoting myoblast growth and myotube formation. To this end, RGD-functionalized low-fouling polymer surfaces with global ligand densities (G) from 0-7 µg peptide/mg polymer and average local ligand densities (L) from 1-6.3 ligands/cluster, are generated and characterized. Cell studies demonstrate improvements in cell adhesion, spreading, growth, and myotube formation up to a density of 7 µg peptide/mg polymer with 4 ligands/cluster. Optimizing ligand density and distribution also promotes early myofiber maturation, identified by increased MF20 marker protein expression and sarcomere-forming myotubes. At higher ligand densities, these cell properties are decreased, indicating that ligand multivalency is a critical parameter for tailoring cell-material interactions, to a certain threshold. The findings provide new insights for designing next-generation biomaterials and hold promise for improved engineering of skeletal muscle.

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生物材料表面的细胞粘附配体纳米团簇工程:用于骨骼肌组织再生的卓越细胞增殖和肌管形成。
设计具有纳米级整合素结合细胞粘附肽集群的生物界面,对于促进受体重新分布到信号复合物中至关重要。骨骼肌细胞对整合素介导的信号极为敏感,但通过控制配体的密度和纳米分布来支持肌肉生成的生物材料尚未开发出来。在这里,通过独立控制配体的整体和局部密度,开发出了可在界面上定制细胞粘附配体分布的材料,从而通过促进肌母细胞生长和肌管形成来增强肌生成。为此,我们生成并表征了 RGD 功能化的低污损聚合物表面,其整体配体密度 (G) 为 0-7 µg 肽/mg 聚合物,平均局部配体密度 (L) 为 1-6.3 个配体/簇。细胞研究表明,在 7 微克多肽/毫克聚合物和 4 个配体/簇的密度范围内,细胞粘附、扩散、生长和肌管形成都得到了改善。配体密度和分布的优化还能促进肌纤维的早期成熟,这体现在 MF20 标记蛋白表达的增加和肌节形成的肌管上。配体密度越高,这些细胞特性就越弱,这表明配体的多价性在一定程度上是定制细胞与材料相互作用的关键参数。这些发现为设计下一代生物材料提供了新的见解,并为改进骨骼肌工程学带来了希望。
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来源期刊
Advanced Healthcare Materials
Advanced Healthcare Materials 工程技术-生物材料
CiteScore
14.40
自引率
3.00%
发文量
600
审稿时长
1.8 months
期刊介绍: Advanced Healthcare Materials, a distinguished member of the esteemed Advanced portfolio, has been dedicated to disseminating cutting-edge research on materials, devices, and technologies for enhancing human well-being for over ten years. As a comprehensive journal, it encompasses a wide range of disciplines such as biomaterials, biointerfaces, nanomedicine and nanotechnology, tissue engineering, and regenerative medicine.
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