High-Performance Acoustofluidic Platform for Hematocrit Determination and Particle Separation Using Lateral Plate Transducer Modes

IF 2.2 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Sensors Letters Pub Date : 2025-08-15 DOI:10.1109/LSENS.2025.3599672

Andreas Fuchsluger;Tina Mitteramskogler;Rafael Ecker;Annalisa De Pastina;Bernhard Jakoby

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引用次数: 0

Abstract

Acoustofluidics enables contact-free manipulation of particles in fluids using acoustic forces, making it ideal for handling biological samples without labeling or surface modification. While bulk acoustic wave (BAW) devices typically rely on transducer thickness modes, this work demonstrates high-performance particle manipulation using lateral width modes. Our silicon-glass-based microfluidic device, coupled to a piezoelectric transducer in an antisymmetric lateral mode, achieves acoustic energy densities up to

$\text{3000 J/m}^{\text{3}}$

—comparable to leading thickness-mode systems. This work demonstrates the two key applications, first, direct hematocrit determination by focusing red blood cells in whole blood, enabling optical analysis without centrifugation, and second, flow-through separation of particles and cells at rates up to

$\text{9 mL/min}$

. The efficient particle focusing and separation performance confirm that lateral transducer modes are a powerful alternative in acoustofluidics. This approach broadens the design space for lab-on-chip systems targeting label-free diagnostics and sample preparation.

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利用侧板换能器模式进行红细胞压积测定和颗粒分离的高性能声流控平台

acoustofluicics能够使用声学力对流体中的颗粒进行无接触操作，使其成为处理生物样品而无需标记或表面修饰的理想选择。体声波（BAW）设备通常依赖于换能器厚度模式，而这项工作展示了使用横向宽度模式的高性能粒子操纵。我们基于硅玻璃的微流体装置，以反对称横向模式耦合到压电换能器，可实现高达3000 J/m的声能密度，可与领先的厚度模式系统相媲美。这项工作证明了两个关键的应用，首先，通过聚焦全血中的红细胞直接测定红细胞压积，无需离心即可进行光学分析，其次，以高达9ml /min的速率进行颗粒和细胞的流动分离。有效的粒子聚焦和分离性能证实了侧向换能器模式是声流体学中一种强有力的替代方案。这种方法拓宽了针对无标签诊断和样品制备的芯片实验室系统的设计空间。

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来源期刊

IEEE Sensors Letters Engineering-Electrical and Electronic Engineering

CiteScore

3.50

自引率

7.10%

发文量

194