3D-Printed Microfluidic-Based Cell Culture System With Analysis to Investigate Macrophage Activation.

IF 3 3区生物学 Q2 BIOCHEMICAL RESEARCH METHODS

ELECTROPHORESIS Pub Date : 2025-02-18 DOI:10.1002/elps.8109

Major A Selemani, Giraso Keza Monia Kabandana, Chengpeng Chen, R Scott Martin

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Abstract

In this paper, we describe the development of 3D-printed microfluidic cell culture devices that can be coupled with a circulation system to study the dynamics of both intracellular and extracellular (release) processes. Key to this approach is the ability to quantitate key analytes on a minutes timescale with either on-line (in this study, quantitating nitric oxide production using an amperometric flow cell) or off-line (in this work, quantitating intracellular itaconate production with LC/MS) analytical measurements. To demonstrate the usefulness of this approach, we chose to study macrophage polarization as a function of the extracellular matrix (silk) fiber size, a major area of research in tissue engineering. It was found that the use of larger fibers (1280 nm vs. smaller 512 nm fibers) led to increases in the production of both nitric oxide and itaconate. These findings set the foundation for future research for the creation of finely tuned microfluidic 3D cell culture approaches in areas where flow and the extracellular matrix play a significant role in barrier transport and where integrated analysis of key markers is needed.

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基于3d打印微流体的细胞培养系统及其分析研究巨噬细胞活化。

在本文中，我们描述了3d打印微流体细胞培养装置的发展，该装置可以与循环系统相结合，以研究细胞内和细胞外（释放）过程的动力学。该方法的关键是能够在几分钟的时间尺度上通过在线（在本研究中，使用安培流池定量一氧化氮的产生）或离线（在本研究中，使用LC/MS定量细胞内衣康酸的产生）分析测量来定量关键分析物。为了证明这种方法的实用性，我们选择研究巨噬细胞极化作为细胞外基质（丝）纤维大小的函数，这是组织工程研究的一个主要领域。研究发现，使用更大的纤维（1280纳米比512纳米更小的纤维）导致一氧化氮和衣康酸的产量增加。这些发现为未来在流动和细胞外基质在屏障运输中发挥重要作用以及需要对关键标记进行综合分析的领域中创建微调微流体3D细胞培养方法的研究奠定了基础。

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

ELECTROPHORESIS 生物-分析化学

CiteScore

6.30

自引率

13.80%

发文量

244

审稿时长

1.9 months

期刊介绍： ELECTROPHORESIS is an international journal that publishes original manuscripts on all aspects of electrophoresis, and liquid phase separations (e.g., HPLC, micro- and nano-LC, UHPLC, micro- and nano-fluidics, liquid-phase micro-extractions, etc.). Topics include new or improved analytical and preparative methods, sample preparation, development of theory, and innovative applications of electrophoretic and liquid phase separations methods in the study of nucleic acids, proteins, carbohydrates natural products, pharmaceuticals, food analysis, environmental species and other compounds of importance to the life sciences. Papers in the areas of microfluidics and proteomics, which are not limited to electrophoresis-based methods, will also be accepted for publication. Contributions focused on hyphenated and omics techniques are also of interest. Proteomics is within the scope, if related to its fundamentals and new technical approaches. Proteomics applications are only considered in particular cases. Papers describing the application of standard electrophoretic methods will not be considered. Papers on nanoanalysis intended for publication in ELECTROPHORESIS should focus on one or more of the following topics: • Nanoscale electrokinetics and phenomena related to electric double layer and/or confinement in nano-sized geometry • Single cell and subcellular analysis • Nanosensors and ultrasensitive detection aspects (e.g., involving quantum dots, "nanoelectrodes" or nanospray MS) • Nanoscale/nanopore DNA sequencing (next generation sequencing) • Micro- and nanoscale sample preparation • Nanoparticles and cells analyses by dielectrophoresis • Separation-based analysis using nanoparticles, nanotubes and nanowires.