可灌注的载细胞微图案水凝胶,用于向组织传递时空血管样信号

Walter B. Varhue , Aditya Rane , Ramon Castellanos-Sanchez , Shayn M. Peirce , George Christ , Nathan S. Swami
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引用次数: 0

摘要

在承载细胞的水凝胶三维培养物中整合生理尺度的脉管系统,以传递时空质量运输、化学和机械线索,是构建能够概括体内线索的体外组织模型的踏脚石。为了解决这一挑战,我们提出了一种通用的方法,用可渗透的通道或管腔核心来微图案相邻的水凝胶壳,一方面可以方便地与流体控制系统集成,另一方面可以方便地与细胞负载的生物材料界面集成。这种微流控压印光刻方法利用键对齐过程的高耐受性和可逆性,在微流控装置内平刻定位多层压印,用于单壳或多壳的水凝胶腔结构的顺序填充和图图化。通过结构的流体界面,能够提供生理学上相关的机械信号,以再现水凝胶外壳上的周期性拉伸和管腔内皮细胞上的剪切应力。我们设想将该平台应用于重现微血管的生物功能和拓扑结构,以及提供运输和机械线索的能力,这是3D培养构建体外组织模型所需要的。
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Perfusable cell-laden micropatterned hydrogels for delivery of spatiotemporal vascular-like cues to tissues

The integration of vasculature at physiological scales within 3D cultures of cell-laden hydrogels for the delivery of spatiotemporal mass transport, chemical and mechanical cues, is a stepping-stone towards building in vitro tissue models that recapitulate in vivo cues. To address this challenge, we present a versatile method to micropattern adjoining hydrogel shells with a perfusable channel or lumen core, for enabling facile integration with fluidic control systems, on one hand, and to cell-laden biomaterial interfaces, on the other hand. This microfluidic imprint lithography methodology utilizes the high tolerance and reversible nature of the bond alignment process to lithographically position multiple layers of imprints within a microfluidic device for sequential filling and patterning of hydrogel lumen structures with single or multiple shells. Through fluidic interfacing of the structures, the ability to deliver physiologically relevant mechanical cues for recapitulating cyclical stretch on the hydrogel shell and shear stress on endothelial cells in the lumen are validated. We envision application of this platform for recapitulation of the bio-functionality and topology of micro-vasculatures, alongside the ability to deliver transport and mechanical cues, as needed for 3D culture to construct in vitro tissue models.

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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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审稿时长
125 days
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