Assemblable 3D biomimetic microenvironment for hMSC osteogenic differentiation.

Luis A Martins, Nadia García-Parra, Joaquín Ródenas-Rochina, Lourdes Cordón, Amparo Sempere, Clarisse Ribeiro, Senentxu Lanceros-Méndez, José Luis Gómez-Ribelles
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Abstract

Adequate simulation mimicking a tissue's native environment is one of the elemental premises in tissue engineering. Although various attempts have been made to induce human mesenchymal stem cells (hMSC) into an osteogenic pathway, they are still far from widespread clinical application. Most strategies focus primarily on providing a specific type of cue, inadequately replicating the complexity of the bone microenvironment. An alternative multifunctional platform for hMSC osteogenic differentiation has been produced. It is based on poly(vinylidene fluoride) (PVDF) and cobalt ferrites magnetoelectric microspheres, functionalized with collagen and gelatin, and packed in a 3D arrangement. This platform is capable of performing mechanical stimulation of piezoelectric PVDF, mimicking the bones electromechanical biophysical cues. Surface functionalization with extracellular matrix biomolecules and osteogenic medium complete this all-round approach. hMSC were cultured in osteogenic inducing conditions and tested for proliferation, surface biomarkers, and gene expression to evaluate their osteogenic commitment.

用于 hMSC 成骨分化的可组装三维仿生微环境
适当模拟组织的原生环境是组织工程学的基本前提之一。尽管人们已做出各种尝试,诱导人类间充质干细胞(hMSC)进入成骨途径,但它们离广泛的临床应用还很遥远。大多数策略主要集中于提供特定类型的线索,远不能复制骨微环境的复杂性。通过应用由聚偏二氟乙烯(PVDF)和钴铁氧体组成、胶原蛋白和明胶功能化并以三维排列方式包装的磁电微球,我们开发出了一种用于 hMSC 成骨分化的多功能平台。该平台能对压电 PVDF 进行机械刺激,模拟骨骼的生物物理机电线索。hMSC 在成骨诱导条件下培养,以诱导其进入这一途径,并检测其增殖、表面生物标志物和基因表达,以评估其成骨承诺。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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