Disassembly of self-assembling peptide hydrogels as a versatile method for cell extraction and manipulation.

Cosimo Ligorio, Magda Martinez-Espuga, Domenico Laurenza, Alex Hartley, Chloe B Rodgers, Anna M Kotowska, David J Scurr, Matthew J Dalby, Paloma Ordóñez-Morán, Alvaro Mata
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Abstract

Self-assembling peptide hydrogels (SAPHs) are increasingly being used as two-dimensional (2D) cell culture substrates and three-dimensional (3D) matrices due to their tunable properties and biomimicry of native tissues. Despite these advantages, SAPHs often represent an end-point in cell culture, as isolating cells from them leads to low yields and disruption of cells, limiting their use and post-culture analyses. Here, we report on a protocol designed to easily and effectively disassemble peptide amphiphile (PA) SAPHs to retrieve 3D encapsulated cells with high viability and minimal disruption. Due to the pivotal role played by salt ions in SAPH gelation, tetrasodium ethylenediaminetetraacetic acid (Na4EDTA) was used as metal chelator to sequester ions participating in PA self-assembly and induce a rapid, efficient, clean, and gentle gel-to-sol transition. We characterise PA disassembly from the nano- to the macro-scale, provide mechanistic and practical insights into the PA disassembly mechanism, and assess the potential use of the process. As proof-of-concept, we isolated different cell types from cell-laden PA hydrogels and demonstrated the possibility to perform downstream biological analyses including cell re-plating, gene analysis, and flow cytometry with high reproducibility and no material interference. Our work offers new opportunities for the use of SAPHs in cell culture and the potential use of cells cultured on SAPHs, in applications such as cell expansion, analysis of in vitro models, cell therapies, and regenerative medicine.

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自组装多肽水凝胶的拆解作为细胞提取和操作的多功能方法。
自组装肽水凝胶(SAPHs)因其可调特性和对原生组织的生物仿真性,正越来越多地被用作二维(2D)细胞培养基质和三维(3D)基质。尽管SAPHs具有这些优点,但它往往是细胞培养的终点,因为从SAPHs中分离细胞会导致产量低和细胞破坏,从而限制了SAPHs的使用和培养后分析。在这里,我们报告了一种设计用于轻松有效地拆解多肽双亲(PA)SAPHs 的方案,从而以高活性和最小破坏回收三维包裹细胞。由于盐离子在 SAPH 凝胶化过程中起着关键作用,因此我们使用乙二胺四乙酸四钠(Na4EDTA)作为金属螯合剂来螯合参与 PA 自组装的离子,并诱导快速、高效、清洁、温和的凝胶到溶胶的转变。我们从纳米到宏观尺度描述了 PA 的分解特征,提供了 PA 分解机制的机理和实用见解,并评估了该过程的潜在用途。作为概念验证,我们从富含细胞的 PA 水凝胶中分离出了不同类型的细胞,并证明了进行下游生物分析的可能性,包括细胞再培养、基因分析和流式细胞术,而且具有很高的可重复性且无材料干扰。我们的工作为 SAPHs 在细胞培养中的应用以及在 SAPHs 上培养的细胞在细胞扩增、体外模型分析、细胞疗法和再生医学等应用中的潜在应用提供了新的机遇。
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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%
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0
审稿时长
1 months
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