Scalable preparation of macroporous collagen microgels by air bubble-induced breakup and ice templating†

IF 3.4 3区 化学 Q2 CHEMISTRY, MULTIDISCIPLINARY Reaction Chemistry & Engineering Pub Date : 2024-07-02 DOI:10.1039/D3RE00595J
Sushant Singh, Wing Yan Chu, Rojin Ostadsharif Memar, Andrew De Carlo, Teodor Veres and Axel Günther
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Abstract

Collagen I, the most abundant protein of the extracellular matrix, has found widespread use in three-dimensional cell culture, and increasingly also in bioprinting and biofabrication applications. However, several limitations remain, such as the capacity to locally recapitulate the multiscale organization of collagen in native tissues. Bioprinting cellular collagen structures with high feature fidelity so far either requires a more rapidly gelling biopolymer to be added or an acellular collagen structure to be defined before the delivery of cells. Here, we report the flow synthesis of macroporous collagen microgels (MCMs) that serve as building blocks for granular bioinks. Obtained bioinks offer excellent printability, provide an avenue to faithfully recapitulate the multiscale collagen organization of native tissues, and overcome the aforementioned limitations. Viscous collagen solutions with concentrations as high as 10 mg ml−1 are consistently converted into droplets using a parallelized microfluidic device via air bubble induced droplet breakup into a continuous oil phase. MCMs are obtained by inducing gelation, oil removal, and washing, and incorporating internal pores of tunable size via ice templating at freezing rates between 0.1 and 10 °C min−1. Independent control over the MCM diameter (175–250 μm) and porosity (58–76%) allows the extracellular matrix structure to be tailored to different tissue engineering applications. The wall structures within MCMs share similarities with the highly compacted and recapitulated collagen porosity in native tissues. This approach in the future can be used to 3D print more complicated biomimetic structures that require cell positioning during printing.

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通过气泡诱导破裂和冰模板可扩展地制备大孔胶原蛋白微凝胶
胶原蛋白 I 是细胞外基质中最丰富的蛋白质,已广泛应用于三维细胞培养,并越来越多地应用于生物打印和生物制造。然而,这种技术仍存在一些局限性,例如无法在局部再现原生组织中胶原蛋白的多尺度组织结构。迄今为止,生物打印细胞胶原蛋白结构的高特征保真度需要添加更快胶化的生物聚合物,或者在输送细胞之前已经确定无细胞胶原蛋白结构。在此,我们报告了大孔胶原蛋白微凝胶(MCMs)的流动合成过程,这种微凝胶可作为颗粒状生物墨水的构件。浓度高达 10 mg ml-1 的粘性胶原蛋白溶液可通过气泡诱导连续油相中的液滴破裂,使用准化微流体设备持续转化为液滴。通过凝胶化、除油、洗涤以及在 0.1 至 10 °C min-1 的冷冻速率下通过冰模板加入尺寸可调的内部孔隙,从而获得 MCM。通过独立控制 MCM 的直径(175-250 微米)和孔隙率(58-76%),可以为不同的组织工程应用定制细胞外基质结构,使 MCM 的内壁与原生组织中的胶原纤维一样紧密。获得的颗粒状生物芯片可以输送细胞,具有极佳的可印刷性,并为忠实再现原生组织的多尺度胶原组织提供了途径。所介绍的方法在未来可实现复杂细胞结构的挤压三维生物打印。
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来源期刊
Reaction Chemistry & Engineering
Reaction Chemistry & Engineering Chemistry-Chemistry (miscellaneous)
CiteScore
6.60
自引率
7.70%
发文量
227
期刊介绍: Reaction Chemistry & Engineering is a new journal reporting cutting edge research into all aspects of making molecules for the benefit of fundamental research, applied processes and wider society. From fundamental, molecular-level chemistry to large scale chemical production, Reaction Chemistry & Engineering brings together communities of chemists and chemical engineers working to ensure the crucial role of reaction chemistry in today’s world.
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