声悬浮和操纵液滴柱,集成光学检测功能,实现反应并行化

IF 3.6 3区 化学 Q2 CHEMISTRY, ANALYTICAL Analyst Pub Date : 2024-10-18 DOI:10.1039/D4AN01096E
Ruchi Gupta and Nicholas J. Goddard
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引用次数: 0

摘要

并行进行多个化学和生物反应的最常见方法是使用微滴管板,手动或机器人分配反应物和洗涤液。我们设想进行模式转变,将声学悬浮液滴作为微滴管板的孔,通过声学操作以非接触方式进行化学和生物反应。这反过来又要求液滴线可以同时悬浮和操纵,以便对它们并行执行相同的操作(合并、混合和检测)。然而,在这项工作之前,这一点尚未得到证实。由于声驻波的性质,单个焦点具有一个以上的俘获器,可以悬浮焦点处以及该点上下半波长处的液滴柱。利用这种方法,我们将声学悬浮和合并液滴的数量增加到 6 个,而最先进的方法只有 2 个。我们的研究表明,一个液滴柱中的液滴可以与另一个液滴柱中的液滴同时移动和合并,并以可控的方式进行化学和生物反应的重复和/或并行化。为了在实验中展示我们的方法,我们建造了一个声学悬浮器,其上下表面由 16×16 个 40 kHz 相控阵传感器和集成光学检测系统组成,研究了两种声学阱的生成和移动算法,并进行了一次示例酶测定。这项工作在声学悬浮和操纵大量液滴方面迈出了重要的一步,最终将大大减少使用目前最先进的工具--微孔板和机器人来进行并行化学和生物反应。
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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Acoustic levitation and manipulation of columns of droplets with integrated optical detection for parallelisation of reactions†

The most common methodology for performing multiple chemical and biological reactions in parallel is to use microtitre plates with either manual or robotic dispensing of reactants and wash solutions. We envision a paradigm shift where acoustically levitated droplets serve as wells of microtitre plates and are acoustically manipulated to perform chemical and biological reactions in a non-contact fashion. This in turn requires that lines of droplets can be levitated and manipulated simultaneously so that the same operations (merge, mix, and detect) can be performed on them in parallel. However, this has not been demonstrated until this work. Because of the nature of acoustic standing waves, a single focus has more than one trap, and can allow levitation of columns of droplets at the focal point and at half a wavelength above and below that point. Using this approach, we increased the number of acoustically levitated and merged droplets to 6 compared to 2 in the state-of-the-art. We showed that droplets in a column can be moved and merged with droplets in another column simultaneously and in a controlled manner to perform repeats and/or parallelisation of chemical and biological reactions. To demonstrate our approach experimentally, we built an acoustic levitator with top and bottom surfaces made of a 16 × 16 grid of 40 kHz phased array transducers and integrated optical detection system, studied two acoustic trap generation and movement algorithms, and performed an exemplar enzyme assay. This work has made significant steps towards acoustic levitation and manipulation of large numbers of droplets to eventually significantly reduce the use of the current state-of-the-art tools, microtitre plates and robots, for performing parallelised chemical and biological reactions.

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来源期刊
Analyst
Analyst 化学-分析化学
CiteScore
7.80
自引率
4.80%
发文量
636
审稿时长
1.9 months
期刊介绍: The home of premier fundamental discoveries, inventions and applications in the analytical and bioanalytical sciences
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