Differentiation potential of periodontal Col1+ cells under orthodontic force

Mechanobiology in Medicine Pub Date : 2023-10-29 DOI:10.1016/j.mbm.2023.100026

Xinyu Wang , Xiangru Huang , Xin Gao , Hongyuan Xu , Anting Jin , Xijun Wang , Siyuan Sun , Yuanqi Liu , Yanfei Zhu , Jingyi Liu , Tingwei Lu , Qinggang Dai , Lingyong Jiang

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Abstract

Mechanical force often has clear effects on tissue niche remodeling. However, the changes in stem cells and their roles in clinical treatment remain unclear. Orthodontic tooth movement (OTM), the primary approach to treating dental-maxillofacial malformations, involves reconstruction of periodontal tissue. Herein, lineage tracing revealed that Col1⁺ cells are distributed in the periodontal ligament and are sensitive to mechanical forces during OTM. Immunofluorescence analysis confirms that Col1⁺ cells can differentiate into osteoblasts and fibroblasts under orthodontic force. Moreover, Col1⁺ cells may be involved in angiogenesis. These findings suggest that Col1⁺ cells play a crucial role in the mechanical remodeling of periodontal tissue during OTM and may serve as a valuable tool for studying the mechanism of OTM.

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正畸力作用下牙周Col1+细胞的分化潜能

机械力通常对组织生态位重塑有明显的影响。然而，干细胞的变化及其在临床治疗中的作用仍不清楚。牙齿矫正运动(OTM)是治疗牙颌面畸形的主要方法，涉及牙周组织的重建。在此，谱系追踪显示Col1+细胞分布在牙周韧带中，并且在OTM期间对机械力敏感。免疫荧光分析证实，在正畸力作用下，Col1+细胞可分化为成骨细胞和成纤维细胞。此外，Col1+细胞可能参与血管生成。这些结果表明Col1+细胞在牙周组织的机械重塑中起着重要作用，可能为研究牙周组织的机制提供有价值的工具。

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Mechanobiology in Medicine

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