Highly porous polycaprolactone microspheres for skeletal repair promote a mature bone cell phenotype in vitro.

Thomas E Paterson, Robert Owen, Colin Sherborne, Hossein Bahmaee, Amy L Harding, Nicola H Green, Gwendolen C Reilly, Frederik Claeyssens
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Abstract

Improving our ability to treat skeletal defects is a critical medical challenge that necessitates the development of new biomaterials. One promising approach involves the use of degradable polymer microparticles with an interconnected internal porosity. Here, we employed a double emulsion to generate such round microparticles (also known as microspheres) from a polycaprolactone-based polymerised high internal phase emulsion (polyHIPE). These microspheres effectively supported the growth of mesenchymal progenitors over a 30-day period, and when maintained in osteogenic media, cells deposited a bone-like extracellular matrix, as determined by histological staining for calcium and collagen. Interestingly, cells with an osteocyte-like morphology were observed within the core of the microspheres indicating the role of a physical environment comparable to native bone for this phenotype to occur. At later timepoints, these cultures had significantly increased mRNA expression of the osteocyte-specific markers dentin matrix phosphoprotein-1 (Dmp-1) and sclerostin, with sclerostin also observed at the protein level. Cells pre-cultured on porous microspheres exhibited enhanced survival rates compared to those pre-cultured on non-porous counterparts when injected. Cells precultured on both porous and non-porous microspheres promoted angiogenesis in a chorioallantoic membrane (CAM) assay. In summary, the polycaprolactone polyHIPE microspheres developed in this study exhibit significant promise as an alternative to traditional synthetic bone graft substitutes, offering a conducive environment for cell growth and differentiation, with the potential for better clinical outcomes in bone repair and regeneration.

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用于骨骼修复的高多孔聚己内酯微球可在体外促进成熟骨细胞表型。
提高我们治疗骨骼缺陷的能力是一项严峻的医学挑战,因此有必要开发新的生物材料。一种很有前景的方法是使用具有内部孔隙相互连接的可降解聚合物微颗粒。在这里,我们采用双乳液法从聚己内酯基聚合高内相乳液(polyHIPE)中生成了这种圆形微颗粒(也称为微球)。这些微球能在 30 天内有效支持间充质祖细胞的生长,当在成骨培养基中培养时,细胞会沉积出类似骨的细胞外基质,这是由组织学上的钙和胶原染色确定的。有趣的是,在微球的核心部分观察到了具有骨细胞样形态的细胞,这表明要形成这种表型,需要与原生骨相似的物理环境。在稍后的时间点上,这些培养物的骨细胞特异性标志物牙本质基质磷蛋白-1(Dmp-1)和硬骨素的 mRNA 表达明显增加,硬骨素在蛋白质水平上也被观察到。与注射在无孔微球上预先培养的细胞相比,注射在多孔微球上预先培养的细胞存活率更高。在绒毛膜(CAM)试验中,多孔和无孔微球上预培养的细胞都能促进血管生成。总之,本研究开发的聚己内酯 polyHIPE 微球有望替代传统的合成骨移植替代物,为细胞生长和分化提供有利环境,在骨修复和再生方面有望取得更好的临床效果。
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来源期刊
Journal of materials chemistry. B
Journal of materials chemistry. B 化学科学, 工程与材料, 生命科学, 分析化学, 高分子组装与超分子结构, 高分子科学, 免疫生物学, 免疫学, 生化分析及生物传感, 组织工程学, 生物力学与组织工程学, 资源循环科学, 冶金与矿业, 生物医用高分子材料, 有机高分子材料, 金属材料的制备科学与跨学科应用基础, 金属材料, 样品前处理方法与技术, 有机分子功能材料化学, 有机化学
CiteScore
12.00
自引率
0.00%
发文量
0
审稿时长
1 months
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