无乳化剂壳聚糖-京尼平微凝胶促进生长板软骨再生。

Emulsion-free chitosan-genipin microgels for growth plate cartilage regeneration.

机构信息

University of Colorado Anschutz Medical Campus, Aurora, CO, USA.

Colorado School of Mines, Golden, CO, USA.

出版信息

J Biomater Appl. 2021 Aug;36(2):289-296. doi: 10.1177/0885328221999894. Epub 2021 Mar 12.

DOI:10.1177/0885328221999894

PMID:33709832

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8319035/

Abstract

The growth plate is a cartilage tissue near the ends of children's long bones and is responsible for bone growth. Injury to the growth plate can result in the formation of a 'bony bar' which can span the growth plate and result in bone growth abnormalities in children. Biomaterials such as chitosan microgels could be a potential treatment for growth plate injuries due to their chondrogenic properties, which can be enhanced through loading with biologics. They are commonly fabricated via an emulsion method, which involves solvent rinses that are cytotoxic. Here, we present a high throughput, non-cytotoxic, non-emulsion-based method to fabricate chitosan-genipin microgels. Chitosan was crosslinked with genipin to form a hydrogel network, and then pressed through a syringe filter using mesh with various pore sizes to produce a range of microgel particle sizes. The microgels were then loaded with chemokines and growth factors and their release was studied in vitro. To assess the applicability of the microgels for growth plate cartilage regeneration, they were injected into a rat growth plate injury. They led to increased cartilage repair tissue and were fully degraded by 28 days in vivo. This work demonstrates that chitosan microgels can be fabricated without solvent rinses and demonstrates their potential for the treatment of growth plate injuries.

摘要

生长板是儿童长骨末端的软骨组织，负责骨骼生长。生长板损伤会导致“骨条”的形成，这些骨条可能跨越生长板，导致儿童骨骼生长异常。壳聚糖微凝胶等生物材料由于其软骨生成特性，可能成为生长板损伤的潜在治疗方法，通过加载生物制剂可以增强其软骨生成特性。它们通常通过乳液法制备，该方法涉及到对细胞有毒性的溶剂冲洗。在这里，我们提出了一种高通量、非细胞毒性、非乳液的方法来制备壳聚糖-京尼平微凝胶。壳聚糖与京尼平交联形成水凝胶网络，然后使用具有不同孔径的筛网通过注射器过滤器进行挤压，从而产生一系列不同粒径的微凝胶颗粒。然后将微凝胶加载趋化因子和生长因子，并在体外研究其释放情况。为了评估微凝胶在生长板软骨再生中的适用性，将其注射到大鼠生长板损伤部位。结果表明，微凝胶可促进软骨修复组织的形成，并在体内 28 天内完全降解。这项工作表明，壳聚糖微凝胶可以在不使用溶剂冲洗的情况下制备，并展示了它们在生长板损伤治疗中的潜力。

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