Separation of mononuclear cells from progenitor products by a novel inertial microfluidic method.

IF 3.3 4区医学 Q3 ENGINEERING, BIOMEDICAL

Biomedical Microdevices Pub Date : 2025-06-28 DOI:10.1007/s10544-025-00756-z

Nilgün Okşak, Sultan Sahin Keskin, Esin Cetin Aktas, Zeynep Dogusan, Levent Trabzon, Dürdane Serap Erdem Kuruca

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引用次数: 0

Abstract

Mononuclear cells (MNCs), a type of leukocyte, require enrichment owing to their rarity for research and clinical applications. The enrichment of MNCs is generally performed via conventional methods (e.g., density gradient centrifugation). However, these methods have downsides, such as being labor intensive, energy and time consuming, and requiring advanced equipment. Therefore, inertial microfluidics has recently drawn widespread attention as a way to overcome these limitations. This work aims to investigate MNC separation using a novel spiral inertial microfluidic system design. After MNCs were enriched by Ficoll stratification, the cells were separated according to their size and deformability properties by passing through the microfluidic system. In the final step, various cell markers were examined for characterization in these cells collected at outlets. In this paper, we determined that MNCs obtained from three different hematological products could be sorted with a recovery rate of 97.5% and a purity level of 84%, whereas red blood cells (RBCs) had a depletion ratio of 80% using Sunflower-designed microfluidic system. The loss of MNCs in this system was much lower than that in density gradient centrifugation. The separation technique studied here has several advantages, such as continuous processing, a high operation flow rate (e.g., 0.7 ml/min), simplifying the operative procedures for automation, and creating no clogging problems. Additionally, this technique can be easily integrated with downstream applications, such as direct analysis of MNCs via a flow cytometer, and can reduce the number of man-hand manipulation processes.

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新型惯性微流体法分离单核细胞与祖细胞产物。

单核细胞（MNCs）是白细胞的一种，由于其在研究和临床应用中的稀有性，需要富集。跨国公司的富集通常通过常规方法进行（例如，密度梯度离心）。然而，这些方法有缺点，如劳动密集，能源和时间消耗，需要先进的设备。因此，惯性微流体作为一种克服这些限制的方法最近引起了广泛的关注。本文旨在研究一种新型螺旋惯性微流控系统的MNC分离。在Ficoll分层富集MNCs后，根据细胞的大小和可变形性通过微流控系统进行分离。在最后一步，在这些网点收集的细胞中检查各种细胞标记物的特征。在本文中，我们确定了从三种不同的血液学产品中获得的MNCs的回收率为97.5%，纯度为84%，而使用葵花设计的微流体系统，红细胞（rbc）的损耗率为80%。与密度梯度离心相比，该体系中MNCs的损失要小得多。本文研究的分离技术具有连续处理、操作流速高（如0.7 ml/min）、简化自动化操作程序和不产生堵塞问题等优点。此外，该技术可以很容易地与下游应用集成，例如通过流式细胞仪直接分析跨国公司，并且可以减少人工操作过程的数量。

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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来源期刊

Biomedical Microdevices 工程技术-工程：生物医学

CiteScore

6.90

自引率

3.60%

发文量

审稿时长

6 months

期刊介绍： Biomedical Microdevices: BioMEMS and Biomedical Nanotechnology is an interdisciplinary periodical devoted to all aspects of research in the medical diagnostic and therapeutic applications of Micro-Electro-Mechanical Systems (BioMEMS) and nanotechnology for medicine and biology. General subjects of interest include the design, characterization, testing, modeling and clinical validation of microfabricated systems, and their integration on-chip and in larger functional units. The specific interests of the Journal include systems for neural stimulation and recording, bioseparation technologies such as nanofilters and electrophoretic equipment, miniaturized analytic and DNA identification systems, biosensors, and micro/nanotechnologies for cell and tissue research, tissue engineering, cell transplantation, and the controlled release of drugs and biological molecules. Contributions reporting on fundamental and applied investigations of the material science, biochemistry, and physics of biomedical microdevices and nanotechnology are encouraged. A non-exhaustive list of fields of interest includes: nanoparticle synthesis, characterization, and validation of therapeutic or imaging efficacy in animal models; biocompatibility; biochemical modification of microfabricated devices, with reference to non-specific protein adsorption, and the active immobilization and patterning of proteins on micro/nanofabricated surfaces; the dynamics of fluids in micro-and-nano-fabricated channels; the electromechanical and structural response of micro/nanofabricated systems; the interactions of microdevices with cells and tissues, including biocompatibility and biodegradation studies; variations in the characteristics of the systems as a function of the micro/nanofabrication parameters.