Unlocking Bio-Instructive Polymers: A Novel Multi-Well Screening Platform Based on Secretome Sampling

Shirin Fateh, Reem Alromaihi, Amir Ghaemmaghami, Morgan Alexander
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Abstract

Biomaterials are designed to interact with biological systems to replace, support, enhance, or monitor their function. However, there are challenges associated with traditional biomaterials’ development due to the lack of underlying theory governing cell response to materials’ chemistry. This leads to the time-consuming process of testing different materials plus the adverse reactions in the body such as cytotoxicity and foreign body response. High-throughput screening (HTS) offers a solution to these challenges by enabling rapid and simultaneous testing of a large number of materials to determine their bio-interactions and biocompatibility. Secreted proteins regulate many physiological functions and determine the success of implanted biomaterials through directing cell behaviour. However, the majority of biomaterials’ HTS platforms are suitable for microscopic analyses of cell behaviour and not for investigating non-adherent cells or measuring cell secretions. Here, we describe a multi-well platform adaptable to robotic printing of polymers and suitable for secretome profiling of both adherent and non-adherent cells. We detail the platform's development steps, encompassing the preparation of individual cell culture chambers, polymer printing, and the culture environment, as well as examples to demonstrate surface chemical characterisation and biological assessments of secreted mediators. Such platforms will no doubt facilitate the discovery of novel biomaterials and broaden their scope by adapting wider arrays of cell types and incorporating assessments of both secretome and cell-bound interactions. Key features • Detailed protocols for preparation of substrate for contact printing of acrylate-based polymers including O2 plasma etching, functionalisation process, and Poly(2-hydroxyethyl methacrylate) (pHEMA) dip coating. • Preparations of 7 mm × 7 mm polymers employing pin printing system. • Provision of confined area for each polymer using ProPlate® multi-well chambers. • Compatibility of this platform was validated using adherent cells [primary human monocyte–derived macrophages (MDMs)) and non-adherent cells (primary human monocyte–derived dendritic cells (moDCs)]. • Examples of the adaptability of the platform for secretome analysis including five different cytokines using enzyme-linked immunosorbent assay (ELISA, DuoSet®). Graphical overview
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揭开生物诱导聚合物的神秘面纱:基于分泌组取样的新型多孔筛选平台
生物材料旨在与生物系统相互作用,以替代、支持、增强或监测其功能。然而,由于缺乏细胞对材料化学反应的基本理论,传统生物材料的开发面临着挑战。这导致不同材料的测试过程非常耗时,而且还会在体内产生不良反应,如细胞毒性和异物反应。高通量筛选(HTS)可以快速、同步地测试大量材料,以确定其生物相互作用和生物相容性,从而为这些挑战提供了解决方案。分泌蛋白可调节许多生理功能,并通过引导细胞行为决定植入生物材料的成败。然而,大多数生物材料的 HTS 平台都适用于细胞行为的显微分析,而不适用于研究非粘附细胞或测量细胞分泌物。在此,我们将介绍一种适用于机器人打印聚合物的多孔平台,该平台适用于粘附细胞和非粘附细胞的分泌组分析。我们详细介绍了该平台的开发步骤,包括单个细胞培养室的制备、聚合物打印和培养环境,并举例说明了表面化学特征描述和分泌介质的生物学评估。毫无疑问,这种平台将促进新型生物材料的发现,并通过适应更广泛的细胞类型阵列以及纳入分泌组和细胞结合相互作用的评估,拓宽生物材料的应用范围。主要特点 - 制备丙烯酸酯基聚合物接触打印基底的详细方案,包括 O2 等离子刻蚀、功能化过程和聚(2-羟乙基甲基丙烯酸酯)(pHEMA)浸渍涂层。- 使用针式印刷系统制备 7 毫米 × 7 毫米的聚合物。- 使用 ProPlate® 多孔室为每种聚合物提供封闭区域。- 使用粘附细胞(原代人类单核细胞衍生巨噬细胞 (MDM))和非粘附细胞(原代人类单核细胞衍生树突状细胞 (moDC))验证了该平台的兼容性。- 使用酶联免疫吸附测定法(ELISA,DuoSet®)分析五种不同细胞因子的分泌组的平台适应性示例。图表概览
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