Towards spatially-organized organs-on-chip: Photopatterning cell-laden thiol-ene and methacryloyl hydrogels in a microfluidic device

Jennifer E. Ortiz-Cárdenas , Jonathan M. Zatorski , Abhinav Arneja , Alyssa N. Montalbine , Jennifer M. Munson , Chance John Luckey , Rebecca R. Pompano
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引用次数: 11

Abstract

Micropatterning techniques for 3D cell cultures enable the recreation of tissue-level structures, but the combination of patterned hydrogels with organs-on-chip to generate organized 3D cultures under microfluidic perfusion remains challenging. To address this technological gap, we developed a user-friendly in-situ micropatterning protocol that integrates photolithography of crosslinkable, cell-laden hydrogels with a simple microfluidic housing, and tested the impact of crosslinking chemistry on stability and spatial resolution. Working with gelatin functionalized with photo-crosslinkable moieties, we found that inclusion of cells at high densities (≥107/mL) did not impede thiol-norbornene gelation, but decreased the storage moduli of methacryloyl hydrogels. Hydrogel composition and light dose were selected to match the storage moduli of soft tissues. To generate the desired pattern on-chip, the cell-laden precursor solution was flowed into a microfluidic chamber and exposed to 405 nm light through a photomask. The on-chip 3D cultures were self-standing and the designs were interchangeable by simply swapping out the photomask. Thiol-ene hydrogels yielded highly accurate feature sizes from 100 to 900 μm in diameter, whereas methacryloyl hydrogels yielded slightly enlarged features. Furthermore, only thiol-ene hydrogels were mechanically stable under perfusion overnight. Repeated patterning readily generated multi-region cultures, either separately or adjacent, including non-linear boundaries that are challenging to obtain on-chip. As a proof-of-principle, primary human T cells were patterned on-chip with high regional specificity. Viability remained high (>85%) after 12-hr culture with constant perfusion. We envision that this technology will enable researchers to pattern 3D co-cultures to mimic organ-like structures that were previously difficult to obtain.

Abstract Image

迈向空间组织的芯片上器官:微流控装置中载巯基和甲基丙烯凝胶的光图型细胞
用于3D细胞培养的微图图化技术能够重建组织水平的结构,但在微流控灌注下,将图图化水凝胶与器官芯片相结合以产生有组织的3D培养物仍然具有挑战性。为了解决这一技术差距,我们开发了一种用户友好的原位微图纹方案,该方案将可交联的载细胞水凝胶光刻技术与简单的微流体外壳集成在一起,并测试了交联化学对稳定性和空间分辨率的影响。通过和光交联基团功能化的明胶,我们发现高密度(≥107/mL)的细胞包埋不会阻碍巯基-降冰片烯凝胶化,但会降低甲基丙烯基水凝胶的储存模量。选择水凝胶组成和光照剂量来匹配软组织的储存模量。为了在芯片上产生所需的图案,将装载细胞的前驱体溶液流入微流控室,并通过光掩膜暴露在405 nm的光下。芯片上的3D培养是独立的,通过简单地更换光掩膜,设计可以互换。巯基水凝胶的特征尺寸在直径100 ~ 900 μm之间,准确度很高,而甲基丙烯水凝胶的特征尺寸略大。此外,只有巯基水凝胶在夜间灌注下力学稳定。重复的模式很容易产生多区域培养,无论是单独的还是相邻的,包括具有挑战性的芯片上获得的非线性边界。作为原理证明,原代人T细胞在芯片上具有高区域特异性。持续灌注培养12小时后,细胞存活率仍保持较高(85%)。我们设想这项技术将使研究人员能够模拟3D共培养物来模拟以前难以获得的器官样结构。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Organs-on-a-chip
Organs-on-a-chip Analytical Chemistry, Biochemistry, Genetics and Molecular Biology (General), Cell Biology, Pharmacology, Toxicology and Pharmaceutics (General)
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125 days
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