Solid state fluid transport and sensing based on printed and embedded cellulose-polymer composites: An alternative pathway to paper-based microfluidic devices

IF 2.8 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC Micro and Nano Engineering Pub Date : 2023-06-01 DOI:10.1016/j.mne.2023.100183
Wolfgang Hilber, Bernhard Jakoby
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Abstract

Here we present an alternative technological approach to paper-based microfluidics that, to the best of our knowledge, has not been reported so far. Instead of defining fluid conducting paths by cutting fluidic structures, or by printing hydrophobic substances on paper, we prepare cellulose/polymer composites that can be printed additively on, in principle, arbitrarily shaped substrates and surfaces. In this way, with respect to geometry and properties, well defined fluid conducting structures based on cellulose can be realized, that can additionally be fully embedded in an organic surface coating. Moreover, the composite can, prior to the printing step, be doped with a functional component, which facilitates the realization of printed analytical devices using just a single base material and process technology. In this sense, the proposed technology can be seen as an alternative pathway to paper-based microfluidics, that may be attractive for specific niche-applications such as, for example, bio-chemical assays embedded in the surface of everyday necessities or commodities. Especially lateral flow immunoassays, pandemic-driven needed in large quantities, may embody a future application field of the presented technology.

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基于印刷和嵌入纤维素-聚合物复合材料的固态流体传输和传感:纸基微流体装置的替代途径
在这里,我们提出了一种纸基微流体的替代技术方法,据我们所知,迄今为止尚未有报道。我们制备的纤维素/聚合物复合材料原则上可以添加印刷在任意形状的基底和表面上,而不是通过切割流体结构或在纸上印刷疏水物质来定义流体传导路径。通过这种方式,就几何形状和性能而言,可以实现基于纤维素的定义良好的流体传导结构,其可以另外完全嵌入有机表面涂层中。此外,在印刷步骤之前,复合材料可以掺杂有功能组分,这有助于仅使用单一基材和工艺技术实现印刷的分析装置。从这个意义上说,所提出的技术可以被视为纸基微流体的替代途径,这可能对特定的利基应用具有吸引力,例如嵌入日常必需品或商品表面的生化分析。特别是需要大量的流行病驱动的侧流免疫测定,可能体现了所提出技术的未来应用领域。
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来源期刊
Micro and Nano Engineering
Micro and Nano Engineering Engineering-Electrical and Electronic Engineering
CiteScore
3.30
自引率
0.00%
发文量
67
审稿时长
80 days
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