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水凝胶辅助微流控芯片平台的增材制造用于光动力治疗研究中的细胞工程应用的研究综述。

Overview of research on additive manufacturing of hydrogel-assisted lab-on-chip platforms for cell engineering applications in photodynamic therapy research.

机构信息

Department of Mechanics, Materials and Biomedical Engineering, Faculty of Mechanical Engineering, Wrocław University of Science and Technology, Wrocław, Poland.

Department of Microsystems, Faculty of Electronics, Photonics and Microsystems, Wrocław University of Science and Technology, Wrocław, Poland.

出版信息

Mikrochim Acta. 2024 Sep 18;191(10):608. doi: 10.1007/s00604-024-06683-9.

DOI:10.1007/s00604-024-06683-9
PMID:39292358
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11410904/
Abstract

Lab-on-chips supported by hydrogel matrices are excellent solutions for cell culture; thus, this literature review presents examples of scientific research in this area. Several works are presenting the properties of biocompatible hydrogels that mimic the cellular environment published recently. Hydrogels can also be treated as cell transporters or as a structural component of microfluidic devices. The rapidly growing scientific sector of hydrogel additive manufacturing is also described herein, with attention paid to the appropriate mechanical and biological properties of the inks used to extrude the material, specifically for biomedical purposes. The paper focuses on protocols employed for additive manufacturing, e.g., 3D printing parameters, calibration, ink preparation, crosslinking processes, etc. The authors also mention potential problems concerning manufacturing processes and offer example solutions. As the novel trend for hydrogels enriched with several biocompatible additives has recently risen, the article presents examples of the use of high-quality carbon nanotubes in hydrogel research enhancing biocompatibility, mechanical stability, and cell viability. Moving forward, the article points out the high applicability of the hydrogel-assisted microfluidic platforms used for cancer research, especially for photodynamic therapy (PDT). This innovative treatment strategy can be investigated directly on the chip, which was first proposed by Jędrych E. et al. in 2011. Summarizing, this literature review highlights recent developments in the additive manufacturing of microfluidic devices supported by hydrogels, toward reliable cell culture experiments with a view to PDT research. This paper gathers the current knowledge in these intriguing and fast-growing research paths.

摘要

水凝胶基质支持的芯片实验室是细胞培养的绝佳解决方案;因此,本文综述了该领域的科学研究示例。最近有几项工作展示了具有生物相容性的水凝胶的特性,这些水凝胶模拟了细胞环境。水凝胶也可以用作细胞转运体或微流控设备的结构组件。本文还介绍了水凝胶添加剂制造这一日益发展的科学领域,特别关注用于挤出材料的墨水的适当机械和生物学特性,具体用于生物医学目的。本文重点介绍了用于添加剂制造的协议,例如 3D 打印参数、校准、墨水制备、交联过程等。作者还提到了制造过程中的潜在问题,并提供了示例解决方案。由于最近出现了富含多种生物相容性添加剂的水凝胶的新趋势,本文介绍了在水凝胶研究中使用高质量碳纳米管来提高生物相容性、机械稳定性和细胞活力的示例。展望未来,本文指出了用于癌症研究的水凝胶辅助微流控平台的高适用性,特别是光动力疗法(PDT)。这种创新的治疗策略可以直接在芯片上进行研究,这是由 Jędrych E. 等人于 2011 年首次提出的。总之,本文综述了水凝胶支持的微流控器件的添加剂制造的最新进展,以期进行可靠的细胞培养实验,从而研究 PDT。本文汇集了这些有趣且快速发展的研究路径的当前知识。

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