一种自动纳升液滴选择和收集装置。

IF 2.5 4区 医学 Q3 BIOCHEMICAL RESEARCH METHODS SLAS Technology Pub Date : 2024-02-01 DOI:10.1016/j.slast.2023.11.002
Joaquín E. Urrutia Gómez , Razan El Khaled El Faraj , Moritz Braun , Pavel A. Levkin , Anna A. Popova
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摘要

微滴阵列(DMA)已成为高通量生物和化学应用的工具,实现了实验过程的小型化和并行化。由于DMA能够容纳数百纳升液滴,因此可以对细胞和生物分子等样品进行简单的筛选和分析。然而,处理纳升体积带来了挑战,因为手工回收纳升体积是不可行的,传统的实验室设备不适合处理如此小的体积和小阵列格式。为了应对这一挑战,我们开发了自动纳升液滴选择装置(ANDeS),这是一个自动收集和转移DMA纳升样品的机器人系统。ANDeS可以使用熔融二氧化硅毛细管从DMA的平坦表面自动收集50至350 nL的体积,移动精度为±30µm。该系统可以自动收集并将DMA芯片上的液滴转移到其他平台,如微滴板、锥形管或其他DMA。此外,为了确保高通量和多液滴收集,优化并演示了在单个毛细管内吸收多个液滴的方法,通过气隙分离以避免毛细管内样品的混合。这项研究显示了ANDeS在实验室应用中的潜力,将其用于收集和转移纳升液滴中含有的生物样品,以供后续分析。实验结果表明,通过允许从DMA中自动检索纳升样品,ANDeS能够增加DMA平台的多功能性,这在单个液滴水平上是不可能的。因此,它扩大了各种分析技术,可用于分析单个液滴的含量和使用DMA进行的实验。因此,ANDeS开启了在细胞筛选、组学分析和组合化学等领域扩大小型化分析发展的机会。
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ANDeS: An automated nanoliter droplet selection and collection device

The Droplet Microarray (DMA) has emerged as a tool for high-throughput biological and chemical applications by enabling miniaturization and parallelization of experimental processes. Due to its ability to hold hundreds of nanoliter droplets, the DMA enables simple screening and analysis of samples such as cells and biomolecules. However, handling of nanoliter volumes poses a challenge, as manual recovery of nanoliter volumes is not feasible, and traditional laboratory equipment is not suited to work with such low volumes, and small array formats. To tackle this challenge, we developed the Automated Nanoliter Droplet Selection device (ANDeS), a robotic system for automated collection and transfer of nanoliter samples from DMA.

ANDeS can automatically collect volumes from 50 to 350 nL from the flat surface of DMA with a movement accuracy of ±30 µm using fused silica capillaries. The system can automatically collect and transfer the droplets from DMA chip into other platforms, such as microtiter plates, conical tubes or another DMA. In addition, to ensure high throughput and multiple droplet collection, the uptake of multiple droplets within a single capillary, separated by air gaps to avoid mixing of the samples within the capillary, was optimized and demonstrated.

This study shows the potential of ANDeS in laboratory applications by using it for the collection and transfer of biological samples, contained in nanoliter droplets, for subsequent analysis. The experimental results demonstrate the ability of ANDeS to increase the versatility of the DMA platform by allowing for automated retrieval of nanoliter samples from DMA, which was not possible manually on the level of individual droplets. Therefore, it widens the variety of analytical techniques that can be used for the analysis of content of individual droplets and experiments performed using DMA. Thus, ANDeS opens up opportunities to expand the development of miniaturized assays in such fields as cell screening, omics analysis and combinatorial chemistry.

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来源期刊
SLAS Technology
SLAS Technology Computer Science-Computer Science Applications
CiteScore
6.30
自引率
7.40%
发文量
47
审稿时长
106 days
期刊介绍: SLAS Technology emphasizes scientific and technical advances that enable and improve life sciences research and development; drug-delivery; diagnostics; biomedical and molecular imaging; and personalized and precision medicine. This includes high-throughput and other laboratory automation technologies; micro/nanotechnologies; analytical, separation and quantitative techniques; synthetic chemistry and biology; informatics (data analysis, statistics, bio, genomic and chemoinformatics); and more.
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