Viscoelastic Hydrogel Modulates Phenotype of Macrophage-Derived Multinucleated Cells and Macrophage Differentiation in Foreign Body Reactions.

Josephine Y Fang, Zhi Yang, Wei Hu, Ba Xuan Hoang, Bo Han
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Abstract

Biomaterial-induced macrophage-derived multinucleated cells (MNCs) are often observed at or near material implantation sites, yet their subtypes and roles in tissue repair and wound healing remain unclear. This study compares material-induced MNCs to cytokine-induced MNCs using both in vitro and in vivo models. 3D-embedded Raw264.7 cells and rat bone marrow-derived monocytes (BMDMs), with or without cytokines such as IL-4 and RANKL, were characterized for their MNC morphologies and subtypes via in situ immunocytochemistry and flow cytometry. Macrophage polarization and osteoclastic differentiation were assessed through NO production, arginase activity, and tartrate-resistant acid phosphatase levels. 3D matrix-induced MNCs expressed the same phenotypic heterogeneity as the IL-4 and RANK-treated ones. 3D matrix-induced MNCs displayed the same phenotypic heterogeneity as those treated with IL-4 and RANKL. A high viscoelastic matrix (1006.48 ± 92.29 Pa) induced larger populations of proinflammatory and osteoclast-like MNCs, whereas a low viscoelastic matrix (38.61 ± 7.56 Pa) supported active differentiation and gene expression across pro-, anti-inflammatory, and osteoclast-like macrophages. Matrix viscoelasticity also influenced the effects of IL-4 and RANKL on macrophage-derived MNC polarization. In an in vivo subcutaneous implantation model, medium to high viscoelastic matrices exhibited higher populations of CD86+ and RANK+ MNCs, while low viscoelastic matrices showed higher populations of CD206+ MNCs. These findings suggest that matrix viscoelasticity modulates macrophage differentiation and MNC phenotype, with low viscoelastic matrices potentially favoring anti-inflammatory MNCs and macrophage differentiation suitable for subcutaneous implantation.

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粘弹性水凝胶可调节异物反应中巨噬细胞衍生多核细胞的表型和巨噬细胞的分化。
生物材料诱导的巨噬细胞衍生的多核细胞(MNCs)经常在材料植入部位或附近观察到,但它们的亚型及其在组织修复和伤口愈合中的作用仍不清楚。本研究利用体外和体内模型比较了材料诱导的多核细胞和细胞因子诱导的多核细胞。通过原位免疫细胞化学和流式细胞术,对三维包埋的 Raw264.7 细胞和大鼠骨髓源性单核细胞(BMDMs)(无论是否含有 IL-4 和 RANKL 等细胞因子)的 MNC 形态和亚型进行了表征。通过氮氧化物生成、精氨酸酶活性和耐酒石酸磷酸酶水平评估巨噬细胞极化和破骨细胞分化。三维基质诱导的 MNCs 表现出与 IL-4 和 RANK 处理的 MNCs 相同的表型异质性。三维基质诱导的MNC表现出与IL-4和RANKL处理的MNC相同的表型异质性。高粘弹性基质(1006.48 ± 92.29 Pa)能诱导更多的促炎性和破骨细胞样MNCs,而低粘弹性基质(38.61 ± 7.56 Pa)则支持促炎性、抗炎性和破骨细胞样巨噬细胞的活跃分化和基因表达。基质粘弹性还影响了 IL-4 和 RANKL 对巨噬细胞衍生的 MNC 极化的影响。在体内皮下植入模型中,中高粘弹性基质表现出较高的CD86+和RANK+ MNC数量,而低粘弹性基质则表现出较高的CD206+ MNC数量。这些发现表明,基质粘弹性可调节巨噬细胞分化和MNC表型,低粘弹性基质可能有利于抗炎MNC和巨噬细胞分化,适合皮下植入。
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