Department of Chemical Engineering, Institute for Applied Life Sciences, UMass-Amherst, Amherst, Massachusetts.
Department of Biomedical Engineering, UMass-Amherst, Amherst, Massachusetts.
Tissue Eng Part C Methods. 2020 Mar;26(3):143-155. doi: 10.1089/ten.TEC.2019.0333. Epub 2020 Mar 6.
Inverted colloidal crystal (ICC) hydrogel scaffolds have emerged as a new class of three-dimensional cell culture matrix that represents a unique opportunity to reproduce lymphoid tissue microenvironments. ICC geometry promotes the formation of stromal cell networks and their interaction with hematopoietic cells, a core cellular process in lymphoid tissues. When subdermally implanted, ICC hydrogel scaffolds direct unique foreign body responses to form a vascularized stromal tissue with prolonged attraction of hematopoietic cells, which together resemble lymphoid tissue microenvironments. While conceptually simple, fabrication of ICC hydrogel scaffold requires multiple steps and laborious handling of delicate materials. Here, we introduce a facile route for ICC hydrogel scaffold fabrication using expanded polystyrene (EPS) beads. EPS beads shrink and fuse in a tunable manner under pressurized thermal conditions, which serves as colloidal crystal templates for ICC scaffold fabrication. Inclusion of collagen in the precursor solution greatly simplified preparation of bioactive hydrogel scaffolds. The resultant EPS-templated bioactive ICC hydrogel scaffolds demonstrate characteristic features required for lymphoid tissue modeling in both and settings. We envision that the presented method will facilitate widespread implementation of ICC hydrogel scaffolds for lymphoid tissue engineering and other emerging applications. Impact statement Inverted colloidal crystal (ICC) hydrogel scaffolds have emerged as a new class of three-dimensional cell culture matrix that represents a unique opportunity for lymphoid tissue modeling and other emerging novel bioengineering applications. While conceptually simple, fabrication of the ICC hydrogel scaffold requires multiple steps and laborious handling of delicate materials with highly toxic chemicals. The presented method for ICC hydrogel scaffold fabrication using expanded polystyrene (EPS) beads is simple, cost-effective, and involves less toxic chemicals than conventional methods, while retaining comparable biological significance. We envision that EPS bead-based hydrogel scaffold fabrication will greatly facilitate the widespread implementation of ICC hydrogel scaffolds and their practical applications.
倒置胶体晶体 (ICC) 水凝胶支架作为一种新型三维细胞培养基质,为再现淋巴组织微环境提供了独特的机会。ICC 几何形状促进了基质细胞网络的形成及其与造血细胞的相互作用,这是淋巴组织中核心的细胞过程。当皮下植入时,ICC 水凝胶支架引导独特的异物反应,形成具有长期造血细胞吸引力的血管化基质组织,共同模拟淋巴组织微环境。虽然概念上很简单,但 ICC 水凝胶支架的制造需要多个步骤和繁琐的精细材料处理。在这里,我们介绍了一种使用膨胀聚苯乙烯 (EPS) 珠制造 ICC 水凝胶支架的简便方法。在加压热条件下,EPS 珠以可调节的方式收缩和融合,可作为 ICC 支架制造的胶体晶体模板。在预聚溶液中加入胶原大大简化了生物活性水凝胶支架的制备。所得的 EPS 模板化生物活性 ICC 水凝胶支架在二维和三维环境中均表现出模拟淋巴组织所需的特征。我们设想,所提出的方法将促进 ICC 水凝胶支架在淋巴组织工程和其他新兴应用中的广泛应用。 影响说明 倒置胶体晶体 (ICC) 水凝胶支架作为一种新型三维细胞培养基质,为淋巴组织建模和其他新兴的生物工程应用提供了独特的机会。虽然概念上很简单,但 ICC 水凝胶支架的制造需要多个步骤和繁琐的精细材料处理,并且使用了剧毒化学品。与传统方法相比,使用膨胀聚苯乙烯 (EPS) 珠制造 ICC 水凝胶支架的方法简单、经济高效,涉及的化学物质毒性较低,但保留了相当的生物学意义。我们设想,基于 EPS 珠的水凝胶支架制造将极大地促进 ICC 水凝胶支架的广泛应用及其实际应用。
