液滴微阵列平台的数字双胞胎:用于细胞培养的图案化芯片上多个液滴的蒸发行为

Droplet Pub Date : 2024-01-01 DOI:10.1002/dro2.94
Yanchen Wu, Joaquin E. Urrutia Gomez, Hongmin Zhang, Fei Wang, Pavel A. Levkin, Anna A. Popova, Britta Nestler
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引用次数: 0

摘要

在防冰、涂层和高通量检测等许多技术应用中,精确控制多液滴在图案化表面上的蒸发至关重要。然而,人们对多液滴在定义明确的图案表面上的复杂蒸发过程仍然知之甚少。在此,我们开发了一种数字孪生系统,用于实时监控液滴微阵列(DMA)上的关键过程,这对于细胞培养操作的并行化和自动化至关重要。具体来说,我们通过实验和数值模拟研究了不同条件下多个纳升液滴的蒸发过程。我们证明,蒸发率不仅受环境湿度和温度的影响,还与液滴在图案化表面上的分布密切相关,当液滴分布密集时,蒸发率会显著降低。此外,我们还提出了一种理论方法,可帮助实验检测图案化基底上蒸发液滴的体积和 pH 值变化。这种多用途的实用策略使我们能够实现对 DMA 上液滴集体蒸发的主动操纵,这对细胞培养、热管理、微反应器、生物芯片等广泛应用具有重要意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Digital twin of a droplet microarray platform: Evaporation behavior for multiple droplets on patterned chips for cell culture

Digital twin of a droplet microarray platform: Evaporation behavior for multiple droplets on patterned chips for cell culture

Precise control of the evaporation of multiple droplets on patterned surfaces is crucial in many technological applications, such as anti-icing, coating, and high-throughput assays. Yet, the complex evaporation process of multiple droplets on well-defined patterned surfaces is still poorly understood. Herein, we develop a digital twin system for real-time monitoring of key processes on a droplet microarray (DMA), which is essential for parallelization and automation of the operations for cell culture. Specifically, we investigate the evaporation of multiple nanoliter droplets under different conditions via experiments and numerical simulations. We demonstrate that the evaporation rate is not only affected by the environmental humidity and temperature but is also strongly linked to the droplet distribution on the patterned surfaces, being significantly reduced when the droplets are densely distributed. Furthermore, we propose a theoretical method to aid in the experimental detection of volumes and pH variation of evaporating droplets on patterned substrates. This versatile and practical strategy allows us to achieve active maneuvering of the collective evaporation of droplets on a DMA, which provides essential implications for a wide range of applications including cell culture, heat management, microreactors, biochips, and so on.

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CiteScore
6.60
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