生物工程三维细胞培养模型的低温保存方法

IF 3.9 3区 医学 Q2 ENGINEERING, BIOMEDICAL
Alba Herrero-Gómez, Marcelo Azagra, Irene Marco-Rius
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引用次数: 1

摘要

低温保存活组织、细胞系和原代细胞的技术自20世纪50年代首次展示以来,对临床医生和研究人员来说已经非常成熟,并广泛用于储存和运输应用。然而,目前对于生物工程的三维(3D)细胞模型,包括患者样本,仍然缺乏可行的冷冻保存和解冻方法。作为解决这一差距的第一步,我们展示了一种基于3D羧甲基纤维素支架和精确冷冻和解冻条件的球体冷冻保存和存活的可行方案。该方案使用肝细胞进行了测试,支架为细胞提供了3D结构,使细胞能够自我排列成球体,并在冷冻期间支持细胞,以获得最佳的解冻后生存能力。与传统的颗粒模型相比,解冻后的细胞活力得到改善,在传统的颗粒模型中,细胞在重力作用下沉淀形成假组织,然后冷冻。这项技术可能会推动低温生物学和其他需要在设施之间(例如在医疗实践、研究和测试设施之间)高度完整地运输预组装3D模型(来自细胞系和将来来自患者的细胞)的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A cryopreservation method for bioengineered 3D cell culture models
Technologies to cryogenically preserve (a.k.a. cryopreserve) living tissue, cell lines and primary cells have matured greatly for both clinicians and researchers since their first demonstration in the 1950s and are widely used in storage and transport applications. Currently, however, there remains an absence of viable cryopreservation and thawing methods for bioengineered, three-dimensional (3D) cell models, including patients’ samples. As a first step towards addressing this gap, we demonstrate a viable protocol for spheroid cryopreservation and survival based on a 3D carboxymethyl cellulose scaffold and precise conditions for freezing and thawing. The protocol is tested using hepatocytes, for which the scaffold provides both the 3D structure for cells to self-arrange into spheroids and to support cells during freezing for optimal post-thaw viability. Cell viability after thawing is improved compared to conventional pellet models where cells settle under gravity to form a pseudo-tissue before freezing. The technique may advance cryobiology and other applications that demand high-integrity transport of pre-assembled 3D models (from cell lines and in future cells from patients) between facilities, for example between medical practice, research and testing facilities.
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来源期刊
Biomedical materials
Biomedical materials 工程技术-材料科学:生物材料
CiteScore
6.70
自引率
7.50%
发文量
294
审稿时长
3 months
期刊介绍: The goal of the journal is to publish original research findings and critical reviews that contribute to our knowledge about the composition, properties, and performance of materials for all applications relevant to human healthcare. Typical areas of interest include (but are not limited to): -Synthesis/characterization of biomedical materials- Nature-inspired synthesis/biomineralization of biomedical materials- In vitro/in vivo performance of biomedical materials- Biofabrication technologies/applications: 3D bioprinting, bioink development, bioassembly & biopatterning- Microfluidic systems (including disease models): fabrication, testing & translational applications- Tissue engineering/regenerative medicine- Interaction of molecules/cells with materials- Effects of biomaterials on stem cell behaviour- Growth factors/genes/cells incorporated into biomedical materials- Biophysical cues/biocompatibility pathways in biomedical materials performance- Clinical applications of biomedical materials for cell therapies in disease (cancer etc)- Nanomedicine, nanotoxicology and nanopathology- Pharmacokinetic considerations in drug delivery systems- Risks of contrast media in imaging systems- Biosafety aspects of gene delivery agents- Preclinical and clinical performance of implantable biomedical materials- Translational and regulatory matters
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