Lab on a Chip最新文献

Well-defined assembly of plasmonic metal nanoparticles by dielectrophoresis for highly sensitive SERS-active substrates. 等离子体金属纳米颗粒在高敏感sers活性衬底上的良好定义组装。

IF 6.1 2区工程技术 Q1 BIOCHEMICAL RESEARCH METHODS

Lab on a Chip

Pub Date : 2025-05-16 DOI: 10.1039/d5lc00238a

Yun Su Yeo,Jaejun Park,Sunghoon Yoo,Dong Hwan Nam,Hayoung Kim,Tae Jae Lee,Gyu Leem,Jae-Sung Kwon,Seunghyun Lee

In this study, dielectrophoresis (DEP) was performed to develop highly sensitive surface- enhanced Raman scattering (SERS)-active substrates for molecular sensing. Substrates with a circular hole pattern were used, and plasmonic particles were trapped and immobilized along the edges of the pattern using dielectrophoretic forces. The arranged particles created hotspots, resulting in an enhanced SERS signal that was detectable even at concentrations as low as 10-10 M. This uniform arrangement provided a consistent signal over a large area. In addition, it was experimentally verified that the behavior of the particles varied with pattern diameter. This phenomenon was further supported by theoretical analysis. The proposed DEP-based SERS substrates are expected to be useful in various applications due to their excellent reproducibility and reliability.

在这项研究中，采用介质电泳（DEP）来开发高灵敏度的表面增强拉曼散射（SERS）活性底物用于分子传感。采用具有圆孔图案的衬底，利用介电泳力沿图案边缘捕获和固定等离子体粒子。排列的粒子产生热点，导致增强的SERS信号，即使浓度低至10-10 m也可以检测到。这种均匀的排列在很大范围内提供了一致的信号。此外，实验还证实了粒子的行为随图案直径的变化而变化。这一现象得到了理论分析的进一步支持。所提出的基于dep的SERS衬底由于其出色的再现性和可靠性，预计将在各种应用中有用。

引用次数: 0

Cancer-on-a-chip for precision cancer medicine. 芯片上的癌症精准治疗。

IF 6.1 2区工程技术 Q1 BIOCHEMICAL RESEARCH METHODS

Lab on a Chip

Pub Date : 2025-05-16 DOI: 10.1039/d4lc01043d

Lunan Liu, Huishu Wang, Ruiqi Chen, Yujing Song, William Wei, David Baek, Mahan Gillin, Katsuo Kurabayashi, Weiqiang Chen

Many cancer therapies fail in clinical trials despite showing potent efficacy in preclinical studies. One of the key reasons is the adopted preclinical models cannot recapitulate the complex tumor microenvironment (TME) and reflect the heterogeneity and patient specificity in human cancer. Cancer-on-a-chip (CoC) microphysiological systems can closely mimic the complex anatomical features and microenvironment interactions in an actual tumor, enabling more accurate disease modeling and therapy testing. This review article concisely summarizes and highlights the state-of-the-art progresses in CoC development for modeling critical TME compartments including the tumor vasculature, stromal and immune niche, as well as its applications in therapying screening. Current dilemma in cancer therapy development demonstrates that future preclinical models should reflect patient specific pathophysiology and heterogeneity with high accuracy and enable high-throughput screening for anticancer drug discovery and development. Therefore, CoC should be evolved as well. We explore future directions and discuss the pathway to develop the next generation of CoC models for precision cancer medicine, such as patient-derived chip, organoids-on-a-chip, and multi-organs-on-a-chip with high fidelity. We also discuss how the integration of sensors and microenvironmental control modules can provide a more comprehensive investigation of disease mechanisms and therapies. Next, we outline the roadmap of future standardization and translation of CoC technology toward real-world applications in pharmaceutical development and clinical settings for precision cancer medicine and the practical challenges and ethical concerns. Finally, we overview how applying advanced artificial intelligence tools and computational models could exploit CoC-derived data and augment the analytical ability of CoC.

许多癌症疗法在临床前研究中显示出强有力的疗效，但在临床试验中却失败了。其中一个关键原因是所采用的临床前模型不能概括复杂的肿瘤微环境（TME），不能反映人类癌症的异质性和患者特异性。肿瘤芯片微生理系统可以模拟实际肿瘤的复杂解剖特征和微环境相互作用，从而实现更准确的疾病建模和治疗测试。本文简要总结并重点介绍了CoC在肿瘤血管、基质和免疫生态位等关键TME区室建模方面的最新进展，以及CoC在治疗筛选中的应用。当前癌症治疗发展的困境表明，未来的临床前模型应该能够高精度地反映患者特异性病理生理和异质性，并能够为抗癌药物的发现和开发提供高通量筛选。因此，CoC也应该得到发展。我们探索了未来的发展方向，并讨论了开发下一代精确癌症医学的CoC模型的途径，如患者衍生芯片、类器官芯片和高保真的多器官芯片。我们还讨论了传感器和微环境控制模块的集成如何为疾病机制和治疗提供更全面的研究。接下来，我们概述了CoC技术在药物开发和精确癌症医学临床环境中的未来标准化和转化的路线图，以及实际挑战和伦理问题。最后，我们概述了如何应用先进的人工智能工具和计算模型来利用CoC衍生数据并增强CoC的分析能力。

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引用次数: 0

A SAW-driven modular acoustofluidic tweezer. saw驱动的模块化声流镊。

IF 6.1 2区工程技术 Q1 BIOCHEMICAL RESEARCH METHODS

Lab on a Chip

Pub Date : 2025-05-15 DOI: 10.1039/d4lc00924j

Dachuan Sang, Suyu Ding, Qinran Wei, Fengmeng Teng, Haixiang Zheng, Yu Zhang, Dong Zhang, Xiasheng Guo

In surface acoustic wave (SAW)-driven acoustofluidic tweezers (AFTs), most setups are integrated on a piezoelectric substrate for a single purpose, limiting the reusability and versatility of devices fabricated using complex MEMS technologies. Meanwhile, prevalent devices exhibit anisotropy in SAW excitation and propagation, as well as optical birefringence and limited transmittance. This work presents a SAW-driven modular acoustofluidic tweezer consisting of up to four replaceable interdigital transducer (IDT) modules and a function module assembled on a common base. Since the IDT modules are separated, each can be fabricated using the piezoelectric substrate best suited to the requirements. For example, SAWs generated from different directions can simultaneously propagate along the X-axis of 128° Y-cut LiNbO₃, enabling highly efficient excitations. The generated SAWs couple into the function module with excellent optical properties and convert into Lamb waves, which then leak into the microfluidic domain and act on the fluid/particles. All modules are connected via standardized interfaces, eliminating potential instabilities caused by wired connections. The reliability of the setup is demonstrated via particle/cell patterning, separation, and concentration experiments, during which the replaceability and reusability of different modules, and the other advantages of the setup, e.g., simple assembly, ease of operation, and application flexibility, are proven.

在表面声波（SAW）驱动的声流镊（aft）中，大多数装置都集成在压电衬底上，用于单一目的，限制了使用复杂MEMS技术制造的器件的可重复使用性和多功能性。同时，常见器件在声表面波激发和传播方面表现出各向异性、光学双折射和有限透射率。这项工作提出了一个saw驱动的模块化声流体镊子，由多达四个可更换的数字转换器（IDT）模块和一个功能模块组装在一个共同的基础上。由于IDT模块是分开的，每个模块都可以使用最适合要求的压电基板制造。例如，从不同方向产生的saw可以同时沿着128°y切割LiNbO3的x轴传播，从而实现高效激发。生成的saw耦合到具有优异光学特性的功能模块中，并转换为兰姆波，然后泄漏到微流体域中并作用于流体/颗粒。所有模块都通过标准化接口连接，消除了有线连接带来的潜在不稳定性。通过颗粒/细胞图案、分离和浓度实验证明了该装置的可靠性，在此过程中，不同模块的可替换性和可重用性，以及该装置的其他优点，例如简单组装、易于操作和应用灵活性，都得到了证明。

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引用次数: 0

From Lab-on-a-Chip to Lab-on-a-Chip-in-the-Lab: a perspective of clinical laboratory medicine for the microtechnologist. 从芯片实验室到实验室芯片实验室：微技术专家的临床检验医学视角。

IF 6.1 2区工程技术 Q1 BIOCHEMICAL RESEARCH METHODS

Lab on a Chip

Pub Date : 2025-05-15 DOI: 10.1039/d4lc00614c

Kirby Fibben,Evelyn Kendall Williams,John D Roback,Wilbur A Lam,David N Alter

An overview of the evolving role of microfluidics within clinical laboratories and diagnostic settings. It explores how microfluidic technologies, initially envisioned to replace traditional lab practices, are instead integrating into established workflows. This integration is driven by advancements in miniaturization and automation, enhancing efficiency and expanding testing capabilities. Regulatory frameworks such as CLIA and FDA oversight shape the landscape for microfluidic adoption, emphasizing the need for rigorous validation and compliance. The total testing process (TTP) framework underscores the critical phases-pre-analytical, analytical, and post-analytical-where microfluidics must conform with to ensure accuracy and reliability in diagnostic outcomes. Automation emerges as pivotal by streamlining workflows and reducing errors, particularly in sample handling and result interpretation. Challenges persist including the complex categorization of tests and the push for tighter regulation of laboratory developed tests (LDTs). The challenges necessitate collaboration between researchers, clinicians, and regulatory bodies. This review highlights how automation and integration of microfluidic technologies in point-of-care settings are reshaping clinical diagnostics, offering rapid, personalized testing options while maintaining high standards of patient care. Despite advancements, mitigating diagnostic errors remains paramount, requiring continuous refinement of technologies and adherence to established clinical protocols. Ultimately, the successful integration of microfluidics into clinical laboratories hinges on balancing innovation with regulatory compliance, ensuring seamless usability and consistent diagnostic accuracy within existing healthcare infrastructures.

微流体在临床实验室和诊断环境中不断发展的作用概述。它探讨了如何微流体技术，最初设想取代传统的实验室实践，而不是整合到既定的工作流程。这种集成是由小型化和自动化、提高效率和扩展测试能力的进步所驱动的。监管框架，如CLIA和FDA监督塑造了微流体采用的景观，强调需要严格的验证和合规性。总测试过程（TTP）框架强调了关键阶段-分析前，分析和分析后-微流体必须符合，以确保诊断结果的准确性和可靠性。通过简化工作流程和减少错误，特别是在样本处理和结果解释方面，自动化成为关键。挑战依然存在，包括对测试进行复杂的分类，以及推动对实验室开发的测试进行更严格的监管。这些挑战需要研究人员、临床医生和监管机构之间的合作。这篇综述强调了自动化和微流控技术在护理点环境中的集成如何重塑临床诊断，提供快速、个性化的测试选择，同时保持高标准的患者护理。尽管取得了进步，但减少诊断错误仍然是最重要的，这需要不断改进技术并遵守既定的临床协议。最终，将微流体成功集成到临床实验室取决于平衡创新与法规遵从性，确保现有医疗保健基础设施的无缝可用性和一致的诊断准确性。

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引用次数: 0

Compartmentalized perfusion for temporal control of the chemical microenvironment of iPSC-derived cardiac cells. 分区灌注对ipsc源性心肌细胞化学微环境的时间控制。

IF 6.1 2区工程技术 Q1 BIOCHEMICAL RESEARCH METHODS

Lab on a Chip

Pub Date : 2025-05-15 DOI: 10.1039/d5lc00072f

Kaisa Tornberg,Wolfram Grötsch,Niina Ritari,Saara Haikka,Lassi Sukki,Katriina Aalto-Setälä,Mari Pekkanen-Mattila,Pasi Kallio

Organ-on-chip structures are predicted to have a significant influence in drug research. In these structures, perfusion can provide cells a more controllable environment to receive signaling molecules. In many current organ-on-chip applications, perfusion is used for shear stress stimulus for the cells, but it can also provide a more precise way of controlling the chemical microenvironment around the cells. In this paper, we propose an open-top organ-on-chip structure with compartment-specific perfusion to introduce stimulating molecules to cells with only minimal extra unspecific stimulus. Using numerical simulations, we show that shear stress sensed by the cells within the structure is low. We further validated the flow profile experimentally. We showed that the hiPSC-CMs accommodate to the flow environment where the shear stress is kept below 0.035 mPa. We also show that the beating rate of hiPSC-CMs increases due to the stimulation provided by chemical stimulant molecules introduced through the flow.

预计器官芯片结构将对药物研究产生重大影响。在这些结构中，灌注可以为细胞提供一个更可控的环境来接收信号分子。在目前的许多器官芯片应用中，灌注用于细胞的剪切应力刺激，但它也可以提供一种更精确的方法来控制细胞周围的化学微环境。在本文中，我们提出了一种具有室特异性灌注的开放式器官芯片结构，仅以最小的额外非特异性刺激将刺激分子引入细胞。通过数值模拟，我们发现结构内部的细胞所感受到的剪切应力很低。我们进一步通过实验验证了流动剖面。结果表明，hiPSC-CMs能够适应剪切应力低于0.035 mPa的流动环境。我们还表明，hiPSC-CMs的跳动速率增加是由于通过流动引入的化学刺激分子提供的刺激。

引用次数: 0

CO2 hydrate nucleation study: novel high-pressure microfluidic devices. CO2水合物成核研究：新型高压微流控装置。

IF 6.1 2区工程技术 Q1 BIOCHEMICAL RESEARCH METHODS

Lab on a Chip

Pub Date : 2025-05-15 DOI: 10.1039/d4lc01102c

Peyman Dehghani,Anne Sinquin,Nicolas Gland,Eric Lécolier,Livio Ruffine,Anh Minh Tang

This study presents the development and application of a novel high-pressure microfluidic system for investigating CO2 hydrate nucleation and growth, with applications for carbon capture and storage (CCS) technologies. Two distinct microchip geometries-a capillary channel chip (serpentine-shaped) and an advanced droplet trap chip- were respectively designed and evaluated. These microchips enable the generation, trapping, and observation of CO2 droplets or bubbles within aqueous systems under static and dynamic conditions. The capillary channel chip allows droplet storage in a single serpentine channel, whereas the droplet trap chip offers superior immobilization and control, preventing droplet/bubble displacement during CO2 hydrate formation. High-resolution optical imaging, coupled with precise pressure and temperature regulation and control, facilitated real-time visualization of CO2 hydrate crystallization at CO2-water interfaces under varying temperature and pressure conditions. Experimental results reveal the influence of geometry, flow dynamics, and hydrodynamics on hydrate morphology and growth. The high-pressure microfluidic setup provides an adaptable and scalable approach for studying hydrate behavior, offering valuable insights for investigating CO2 storage in geological formations.

本研究介绍了一种新型高压微流体系统的开发和应用，用于研究二氧化碳水合物的成核和生长，以及碳捕获和储存（CCS）技术的应用。两种不同的微芯片几何形状-毛细管通道芯片（蛇形）和先进的液滴陷阱芯片-分别设计和评估。这些微芯片能够在静态和动态条件下产生、捕获和观察水系统中的CO2液滴或气泡。毛细管通道芯片允许液滴存储在单个蛇形通道中，而液滴陷阱芯片提供卓越的固定和控制，防止在CO2水合物形成过程中液滴/气泡位移。高分辨率光学成像，加上精确的压力和温度调节和控制，促进了不同温度和压力条件下CO2-水界面CO2水合物结晶的实时可视化。实验结果揭示了几何、流动力学和流体力学对水合物形态和生长的影响。高压微流体装置为研究水合物行为提供了一种适应性强、可扩展的方法，为研究地质构造中的二氧化碳储存提供了有价值的见解。

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引用次数: 0

Dual-mode droplet rolling strategy: mimicking Earth's rotation and revolution for dual-cycle synergy in the efficient capture and controlled release of trace targets. 双模液滴滚动策略：模拟地球自转和公转双循环协同有效捕获和控制释放痕量目标。

IF 6.1 2区工程技术 Q1 BIOCHEMICAL RESEARCH METHODS

Lab on a Chip

Pub Date : 2025-05-15 DOI: 10.1039/d5lc00110b

Qian Wang,Kexin Liu,Kunming Xing,Yuyan Li,Yumin Liu,Guangyao Tan,Yingnan Sun,Shusheng Zhang

Current microchips functionalized with antibodies or aptamers primarily enhance the capture and detection efficiency of single targets in microfluidics by refining microchannel designs or developing functional enhancement materials. However, strategies to extend the interaction path for efficiency optimization remain underexplored, as they may cause elevated hydraulic pressure and fluid shear forces within the microchannels, and the potential for path extension is inherently limited. This study introduces a novel dual-mode droplet rolling strategy, mimicking Earth's rotation and revolution, which employs a closed-loop patterned superwetting chip to achieve efficient capture of trace biological targets in gravity-driven droplets. Specifically, the external cyclic motion in the "revolution" mode greatly extends the interaction path between the droplet-contained targets and the active interface. Meanwhile, the internal cyclic vortex flow in the "rotation" mode markedly increases the contact frequency between droplet-contained targets and the active substrate. Consequently, the dual-cycle synergistic amplification significantly enhances the effective contact opportunities between the targets and the functionalized closed-loop track, thereby markedly improving target capture efficiency. As a proof of concept, we demonstrate the specific and efficient capture of both micron-sized polystyrene microspheres (6 μm and 15 μm) and nanoscale AuNPs (50 nm) through multilayer modification of the superslippery track, highlighting the platform's versatility for targets of varying sizes. We achieved 91.3% capture efficiency for circulating tumor cells (MCF-7 cells, ∼20 μm), underscoring the chip's high efficiency in specific target capture. Furthermore, we showcase the strategy's applicability throughout the entire workflow, encompassing efficient capture, controlled release, immediate recovery, and downstream cultivation using pathogenic bacteria (E. coli, ∼1 μm). This strategy holds significant promise for detecting tumor markers and pathogens in body fluid samples, offering an innovative approach to capture-based diagnostics.

目前用抗体或适配体功能化的微芯片主要通过改进微通道设计或开发功能增强材料来提高微流体中单个目标的捕获和检测效率。然而，为了优化效率而扩展相互作用路径的策略仍未得到充分探索，因为它们可能会导致微通道内的液压压力和流体剪切力升高，并且路径扩展的潜力本身就有限。本文介绍了一种模拟地球自转和公转的新型双模液滴滚动策略，该策略采用闭环模式超湿芯片，实现了对重力驱动液滴中痕量生物靶点的高效捕获。具体而言，“旋转”模式下的外循环运动极大地扩展了含液滴目标与活动界面之间的相互作用路径。同时，“旋转”模式下的内部循环涡流动显著增加了含液滴目标与活性基板之间的接触频率。因此，双循环协同放大显著提高了目标与功能化闭环轨迹的有效接触机会，从而显著提高了目标捕获效率。作为概念验证，我们通过对超光滑轨道进行多层修饰，展示了微米级聚苯乙烯微球（6 μm和15 μm）和纳米级AuNPs （50 nm）的特定和有效捕获，突出了该平台对不同尺寸目标的通用性。我们对循环肿瘤细胞（MCF-7细胞，~ 20 μm）的捕获效率达到了91.3%，强调了芯片在特定靶标捕获方面的高效率。此外，我们展示了该策略在整个工作流程中的适用性，包括高效捕获、控制释放、立即恢复和使用致病菌（大肠杆菌，~ 1 μm）进行下游培养。这一策略对检测体液样本中的肿瘤标志物和病原体具有重要意义，为基于捕获的诊断提供了一种创新方法。

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引用次数: 0

Deciphering the unique inertial focusing behavior of sperm cells. 破译精子细胞独特的惯性聚焦行为。

IF 6.1 2区工程技术 Q1 BIOCHEMICAL RESEARCH METHODS

Lab on a Chip

Pub Date : 2025-05-14 DOI: 10.1039/d5lc00047e

Mohammad Moein Naderi,Hua Gao,Jian Zhou,Ian Papautsky,Zhangli Peng

Inertial focusing has been utilized to advance assisted reproductive technologies (ART) for animal breeding and in vitro fertilization (IVF) by separating sperm cells from biofluids with complex cell backgrounds. While existing studies have aimed to design and optimize sperm separation devices, the fundamental mechanism behind the unique focusing behavior of sperm in spiral channels remains largely unknown: sperm cells focus near the outer wall, whereas most other cells focus near the inner wall. This is primarily due to the lack of a direct modelling scheme for capturing the detailed inertial migration of sperm cells in the spiral channels. In this work, we developed a 3D DNS-PT modeling approach that can predict the inertial focusing of sperm cells with long tails. Unlike previous studies that considered rotating spheres, the novelty of our approach is in extracting the inertial lift force for a triaxial ellipsoid (which represents the asymmetric oval-shaped sperm head) and accounting for the tail effect through appropriate boundary conditions, thus capturing their cumulative impact on sperm focusing behavior. Furthermore, we conducted inertial microfluidics experiments with fluorescent images of spermatozoa to validate the modelling results. We discovered that the effect of the tail, rather than the sperm head shape or orientation, is the primary determinant of the unique inertial focusing position of sperm cells in microchannels. The modelling results provided significant insights into the evolution of particle distribution in the channel cross-section along the flow direction, which was previously unknown due to the limitations of imaging techniques. The predicted particle trajectories enabled detailed analysis and explanation of the distinct migration paths of sperm cells and spherical particles. This work bridges the gap in our understanding of the inertial migration of sperm and other flagellated cells, facilitating the better design and optimization of sorting and separation devices.

惯性聚焦已被用于推进辅助生殖技术（ART），用于动物育种和体外受精（IVF），通过从具有复杂细胞背景的生物流体中分离精子细胞。虽然现有的研究旨在设计和优化精子分离装置，但精子在螺旋通道中独特聚焦行为背后的基本机制在很大程度上仍然未知：精子细胞聚焦在外壁附近，而大多数其他细胞聚焦在内壁附近。这主要是由于缺乏一种直接的建模方案来捕获精子细胞在螺旋通道中的详细惯性迁移。在这项工作中，我们开发了一种3D DNS-PT建模方法，可以预测长尾精子细胞的惯性聚焦。与以往考虑旋转球体的研究不同，该方法的新颖之处在于提取了三轴椭球（代表不对称的卵形精子头部）的惯性升力，并通过适当的边界条件考虑了尾部效应，从而捕获了它们对精子聚焦行为的累积影响。此外，我们用精子的荧光图像进行了惯性微流体实验来验证建模结果。我们发现，尾部的影响，而不是精子头部的形状或方向，是微通道中精子细胞独特的惯性聚焦位置的主要决定因素。模拟结果为颗粒沿流动方向在通道横截面上的分布演变提供了重要的见解，这是由于成像技术的限制而未知的。预测的粒子轨迹可以详细分析和解释精子细胞和球形粒子的不同迁移路径。这项工作填补了我们对精子和其他鞭毛细胞惯性迁移理解的空白，有助于更好地设计和优化分选和分离装置。

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引用次数: 0

Designing enhanced mixing in stagnant microfluidic environments: an artificial cilia approach. 在停滞微流体环境中设计增强混合：人工纤毛方法。

IF 6.1 2区工程技术 Q1 BIOCHEMICAL RESEARCH METHODS

Lab on a Chip

Pub Date : 2025-05-14 DOI: 10.1039/d5lc00186b

Tongsheng Wang,Ishu Aggarwal,Erik Steur,Tess Homan,Patrick R Onck,Jaap M J den Toonder,Ye Wang

Mixing in stagnant microfluidic environments is essential for many applications but is inherently challenging to achieve, due to the difficulty in generating effective flow disturbances at the sub-millimetre scale. Traditional passive micromixers require externally driven flow to work, while active mixers often have restrictive use cases with undesirable side-effects. In this study, we designed a 6 × 6 array of multi-directionally inclined magnetic artificial cilia that can be manufactured using a newly developed micromolding process. The array can generate strong local mixing by creating overlapping vortical flows generated by the cilia's tilted conical motion, as well as efficient global mixing by producing a complex flow pattern composed of a collection of predesigned, criss-crossing net flow vectors. Experimental results show effective mixing in stagnant microfluidic environments within 25 seconds when the cilia are actuated by a rotating global magnetic field at a frequency of 20 Hz. We performed fully coupled simulations to design the 3D motion of the cilia. Simulations of double-cilia systems with prescribed motion provide insights for designing the large array, and a simulation of the full array was performed to analyse the mixing effect in 3D.

在停滞的微流体环境中混合对于许多应用来说是必不可少的，但由于难以在亚毫米尺度上产生有效的流动干扰，因此实现这一目标本身就具有挑战性。传统的无源微混频器需要外部驱动流才能工作，而有源混频器通常具有限制性用例和不良副作用。在这项研究中，我们设计了一个6 × 6阵列的多方向倾斜磁性人造纤毛，可以使用新开发的微成型工艺制造。该阵列可以通过产生由纤毛倾斜的锥形运动产生的重叠涡流来产生强烈的局部混合，也可以通过产生由预先设计的、交叉的净流矢量集合组成的复杂流型来产生有效的全局混合。实验结果表明，在频率为20 Hz的旋转磁场作用下，纤毛在25秒内可在静止微流体环境中有效混合。我们进行了完全耦合的模拟来设计纤毛的三维运动。对具有规定运动的双纤毛系统的模拟为设计大型阵列提供了参考，并对整个阵列进行了模拟，以分析三维混合效果。

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引用次数: 0

Blood cell separation with magnetic techniques: a critical review. 血细胞磁分离技术：一个重要的回顾。

IF 6.1 2区工程技术 Q1 BIOCHEMICAL RESEARCH METHODS

Lab on a Chip

Pub Date : 2025-05-13 DOI: 10.1039/d5lc00180c

Karla Mercedes Paz González,Linh Nguyen T Tran,Poornima Ramesh Iyer,Xian Wu,Hyeon Choe,Bahareh Rezaei,Shahriar Mostufa,Ebrahim Azizi,Ioannis H Karampelas,Minxiang Zeng,Kai Wu,Jeffrey Chalmers,Jenifer Gómez-Pastora

Blood cell separation is a critical process for many clinical and research applications. Among the various techniques employed for blood cell isolation, magnetic techniques are very attractive due to their multiple benefits, i.e. high efficiency, simplicity, low-cost, and no need for expensive equipment or trained operators. Microfluidic devices integrating magnetophoresis have demonstrated promising results for high-throughput separation, with some achieving separation rates of over 108 cells per hour. However, there are many different approaches that can be used for blood magnetic separations, with the selection depending on the sample properties, target cells and purpose of the isolated fractions. This critical review examines recent advances (2014-2025) in magnetic techniques for separating blood cells. Both labeled and label-free approaches are analyzed, with a focus on their performance and impact on cellular function, highlighting their strengths, limitations, and potential for future development in clinical research applications. Among the labeled approaches, positive selection methods have been shown to achieve high purities for various cell types; nevertheless, these techniques might affect cell functionality after separation. Therefore, negative selection can be used for the separation of cells when cellular functionality needs to be preserved. Moreover, label-free techniques, primarily focused on red blood cells (RBCs) separation, can be used for blood cell isolation by leveraging the cells' intrinsic magnetic properties. These methods showed potential for continuous, high-purity RBCs separation, with some devices achieving over 95% recovery and purity. This work aims to provide valuable guidelines for the appropriate selection of magnetic technologies for blood separations to accomplish the successful implementation of magnetophoresis in clinical practice.

血细胞分离是许多临床和研究应用的关键过程。在用于血细胞分离的各种技术中，磁性技术因其多种优点而非常有吸引力，即高效率、简单、低成本、不需要昂贵的设备或训练有素的操作人员。集成磁泳的微流控装置在高通量分离方面已经显示出有希望的结果，其中一些装置每小时的分离速度超过108个细胞。然而，有许多不同的方法可用于血液磁分离，其选择取决于样品性质、靶细胞和分离组分的目的。本文回顾了磁性分离血细胞技术的最新进展（2014-2025）。分析了标记和无标记的方法，重点是它们的性能和对细胞功能的影响，突出了它们在临床研究应用中的优势、局限性和未来发展潜力。在标记方法中，阳性选择方法已被证明可以实现各种细胞类型的高纯度；然而，这些技术可能会影响分离后的细胞功能。因此，当需要保留细胞功能时，负选择可用于细胞分离。此外，无标记技术，主要集中在红细胞（红细胞）分离，可用于血细胞分离利用细胞的固有磁性。这些方法具有连续、高纯度分离红细胞的潜力，其中一些设备的回收率和纯度超过95%。本研究旨在为血液分离中磁技术的正确选择提供有价值的指导，以实现磁泳术在临床实践中的成功实施。

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引用次数: 0