将β-环糊精纳入胶原支架中以隔离生长因子并调节间充质干细胞活性。
Incorporating β-cyclodextrin into collagen scaffolds to sequester growth factors and modulate mesenchymal stem cell activity.
机构信息
Department of Chemical and Biomolecular Engineering, University of Illinois at Urbana-Champaign, Urbana, IL 61801, United States.
Department of Bioengineering, University of Illinois at Urbana-Champaign, Urbana, IL 61801, United States.
出版信息
Acta Biomater. 2018 Aug;76:116-125. doi: 10.1016/j.actbio.2018.06.033. Epub 2018 Jun 23.
UNLABELLED
The development of biomaterials for a range of tissue engineering applications increasingly requires control over the bioavailability of biomolecular cues such as growth factors in order to promote desired cell responses. While efforts have predominantly concentrated on covalently-bound or freely-diffusible incorporation of biomolecules in porous, three-dimensional biomaterials, opportunities exist to exploit transient interactions to concentrate growth factor activity over desired time frames. Here, we report the incorporation of β-cyclodextrin into a model collagen-GAG scaffold as a means to exploit the passive sequestration and release of growth factors via guest-host interactions to control mesenchymal stem cell differentiation. Collagen-GAG scaffolds that incorporate β-cyclodextrin show improved sequestration as well as extended retention and release of TGF-β1. We further show extended retention and release of TGF-β1 and BMP-2 from β-cyclodextrin modified scaffolds was sufficient to influence the metabolic activity and proliferation of mesenchymal stem cells as well as differential activation of Smad 2/3 and Smad 1/5/8 pathways associated with differential osteo-chondral differentiation. Further, gene expression analysis showed TGF-β1 release from β-cyclodextrin CG scaffolds promoted early chondrogenic-specific differentiation. Ultimately, this work establishes a novel method for the incorporation and display of growth factors within CG scaffolds via supramolecular interactions. Such a design framework offers opportunities to selectively alter the bioavailability of multiple biomolecules within a three-dimensional collagen-GAG scaffold to enhance cell activity for a range of musculoskeletal regenerative medicine applications.
STATEMENT OF SIGNIFICANCE
We describe the incorporation of β-cyclodextrin into a model CG-scaffold under development for musculoskeletal tissue engineering applications. We show β-cyclodextrin modified scaffolds promote the sequestration of soluble TGF-β1 and BMP-2 via guest-host interactions, leading to extended retention and release. Further, β-cyclodextrin modified CG scaffolds promote TGF-β1 or BMP-2 specific Smad signaling pathway activation associated with divergent osseous versus chondrogenic differentiation pathways in mesenchymal stem cells.
未加标签
为了促进所需的细胞反应,各种组织工程应用的生物材料的发展越来越需要控制生物分子信号(如生长因子)的生物利用度。虽然人们主要集中精力将生物分子共价结合或自由扩散纳入多孔的三维生物材料中,但也存在利用瞬态相互作用在所需的时间范围内集中生长因子活性的机会。在这里,我们报告了将β-环糊精纳入模型胶原蛋白-GAG 支架中,以利用客体-主体相互作用来被动隔离和释放生长因子,从而控制间充质干细胞分化。掺入β-环糊精的胶原蛋白-GAG 支架显示出更好的隔离效果以及 TGF-β1 的延长保留和释放。我们进一步表明,β-环糊精修饰的支架中 TGF-β1 和 BMP-2 的延长保留和释放足以影响间充质干细胞的代谢活性和增殖,以及与差异成软骨-成骨分化相关的 Smad 2/3 和 Smad 1/5/8 途径的差异激活。此外,基因表达分析表明,β-环糊精 CG 支架中 TGF-β1 的释放促进了早期软骨特异性分化。最终,这项工作为通过超分子相互作用在 CG 支架中掺入和展示生长因子建立了一种新方法。这种设计框架为在三维胶原蛋白-GAG 支架中选择性改变多种生物分子的生物利用度提供了机会,以增强细胞活性,用于各种肌肉骨骼再生医学应用。
意义声明
我们描述了将β-环糊精纳入正在开发用于肌肉骨骼组织工程应用的模型 CG 支架中。我们表明,β-环糊精修饰的支架通过主体-客体相互作用促进可溶性 TGF-β1 和 BMP-2 的隔离,从而导致延长保留和释放。此外,β-环糊精修饰的 CG 支架促进 TGF-β1 或 BMP-2 特异性 Smad 信号通路激活,与间充质干细胞中不同的成骨与软骨分化途径相关。
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