From cells-on-a-chip to organs-on-a-chip: scaffolding materials for 3D cell culture in microfluidics

Terrell John A.; Jones Curtis G.; Kabandana Giraso Keza Monia; Chen Chengpeng

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From cells-on-a-chip to organs-on-a-chip: scaffolding materials for 3D cell culture in microfluidics

机译：从芯片上的电池到芯片上的芯片：微流体中用于3D细胞培养的脚手架材料

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It is an emerging research area to integrate scaffolding materials in microfluidic devices for 3D cell culture (organs-on-a-chip). The technology of organs-on-a-chip holds the potential to obviate the gaps between pre-clinical and clinical studies. As accumulating evidence shows the importance of extracellular matrix inin vitrocell culture, significant efforts have been made to integrate 3D ECM/scaffolding materials in microfluidics. There are two families of materials that are commonly used for this purpose: hydrogels and electrospun fibers. In this review, we briefly discuss the properties of the materials, and focus on the various technologies to obtain the materials (e.g.extraction of collagen from animal tissues) and to include the materials in microfluidic devices. Challenges and potential solutions of the current materials and technologies were also thoroughly discussed. At the end, we provide a perspective on future efforts to make these technologies more translational to broadly benefit pharmaceutical and pathophysiological research.

机译：它是一种新兴的研究区，用于将脚手架材料整合在微流体装置中的3D细胞培养物（芯片碎片）。器官芯片技术占据了临床前和临床研究之间的差距的可能性。由于累积证据表明，vitrocell培养细胞外基质的重要性，已经进行了大量努力，以在微流体中整合3D ECM /脚手架材料。有两个常用的材料常用于此目的：水凝胶和电纺纤维。在本文中，我们简要讨论了材料的性质，并专注于各种技术，以获得材料（例如来自动物组织的胶原蛋白的胶原蛋白）并包括微流体装置中的材料。还彻底讨论了目前材料和技术的挑战和潜在解决方案。最后，我们提供了未来努力的视角，使这些技术更加平移，以广泛利用药物和病理生理学研究。

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《Journal of Materials Chemistry, B. materials for biology and medicine》 |2020年第31期|共19页
作者
Terrell John A.; Jones Curtis G.; Kabandana Giraso Keza Monia; Chen Chengpeng;
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Univ Maryland Baltimore Cty Dept Chem &

Biochem Baltimore MD 21250 USA;

Univ Maryland Baltimore Cty Dept Chem &

Biochem Baltimore MD 21250 USA;

Univ Maryland Baltimore Cty Dept Chem &

Biochem Baltimore MD 21250 USA;

Univ Maryland Baltimore Cty Dept Chem &

Biochem Baltimore MD 21250 USA;

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正文语种 eng
中图分类分析化学;
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1. From cells-on-a-chip to organs-on-a-chip: scaffolding materials for 3D cell culture in microfluidics [J] . Terrell John A., Jones Curtis G., Kabandana Giraso Keza Monia, Journal of Materials Chemistry, B. materials for biology and medicine . 2020,第31期

机译：从芯片上的电池到芯片上的芯片：微流体中用于3D细胞培养的脚手架材料
2. Exploring the dark side of MTT viability assay of cells cultured onto electrospun PLGA-based composite nanofibrous scaffolding materials [J] . Qi R., Shen M., Cao X., The Analyst: The Analytical Journal of the Royal Society of Chemistry: A Monthly International Publication Dealing with All Branches of Analytical Chemistry . 2011,第14期

机译：探索在静电纺丝基于PLGA的复合纳米纤维支架材料上培养的细胞的MTT活力测定的阴暗面
3. 3D Culture Histology Cryosectioned Well Insert Technology Preserves the Structural Relationship between Cells and Biomaterials for Time-Lapse Analysis of 3D Cultures [J] . Charbonneau Andre M., Al-Samadi Ahmed, Salo Tuula, Biotechnology Journal: Healthcare,Nutrition,Technology . 2019,第11期

机译：3D培养组织学丧漏井插入技术可保持细胞和生物材料之间的结构关系，用于3D培养的时间延时分析
4. Confocal Fluorescence Detection for 3D Cultured Mammalian Cells in a Microfluidic Cell Culture System [C] . Jong-ryul Choi, Jong Hwan Sung, Michael L. Shuler, Imaging, manipulation, and analysis of biomolecules, cells, and tissues VIII . 2010

机译：在微流细胞培养系统中共聚焦荧光检测3D培养的哺乳动物细胞
5. Microfluidic Generation and Manipulation of Hydrogel Microcapsules for Biomimetic 3D Tissue Culture and Cell Cryopreservation. [D] . Huang, Haishui. 2016

机译：用于仿生3D组织培养和细胞冷冻保存的水凝胶微胶囊的微流体生成和操纵。
6. 3D‐Printed Microfluidics: Formation of Polarized Functional Artificial Cells from Compartmentalized Droplet Networks and Nanomaterials Using One‐Step Dual‐Material 3D‐Printed Microfluidics (Adv. Sci. 1/2020) [O] . Jin Li, Divesh Kamal Baxani, William David Jamieson, 2020

机译：3D打印的微流体：使用一步双材料的3D打印的微流体由分隔的液滴网络和纳米材料形成极化的功能性人造细胞（Adv。Sci。1/2020）
7. A zeptomolar microfluidic immunoassay MS imaging from a microfluidic device BSI to study free-solution binding without labeling Effect of the Debye screening length on NW-FET sensors SILAC with top-down MS for protein quantitation and characterization FRET and force spectroscopy-together at last Nominations for Gold Medal Award Cellular imaging is just a click away CARS monitors lipid storage Microfluidic hydrogel scaffold for 3D cell culture Getting to E = mc2 [O] . 2007

机译：ZeptOmolar Microfluidic免疫测定 MS Imaging来自Microfluidic设备 BSI在没有标签的情况下学习自由溶液绑定 DEYBE筛选长度对NW-FET传感器的影响SILAC具有自上而下MS的蛋白质定量和表征最后的褶皱和力量光谱 - 在一起金牌奖提名蜂窝成像只需点击一下即可汽车监测脂质储存微流体水凝胶支架3D细胞培养进入e = mc2

From cells-on-a-chip to organs-on-a-chip: scaffolding materials for 3D cell culture in microfluidics

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