Nanoscale strain gauges on flexible polymer substrates

Devin K. Brown, Isha Lodhi, Biya Haile, David R. Myers, Wilbur A. Lam, Oliver Brand
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Abstract

Biological cell force is important for proper cell and tissue function and can be an indicator of disease. Therefore, measuring cell force has potential in disease diagnosis and treatment. However, biological cell force measurement approaches are limited and typically slow due to the analysis of optical images before and after cell application or other methods that have low throughput. This work seeks to overcome this bottleneck by the use of nanoscale strain gauges which can measure cell forces as an electrical signal in real time, as well as being able to be scaled to measure tens of thousands of cells, simultaneously. This paper presents the design, COMSOL simulation, fabrication, as well as electrical and mechanical testing of gold nanometer scale strain gauges embedded in soft polydimethylsiloxane (PDMS) using a sacrificial aluminum layer method. A process flow using an aluminum sacrificial layer is presented, which successfully fabricated gold strain gauges with 100 nm dimensions in soft PDMS polymer and have been used to measure strain applied to the PDMS surface. Compressive strains ranging from 0.4% to 1.7% in the PDMS surface, corresponding to forces of 718 nN to 2.0 μN have been detected with resistance changes of 1%–8%. To the best of our knowledge, these are the smallest metal strain gauges to be made on soft polymers and is a promising new approach for biological cell force measurement.
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柔性聚合物基板上的纳米级应变片
生物细胞力对正常的细胞和组织功能很重要,可以作为疾病的指标。因此,测定细胞力在疾病诊断和治疗中具有潜在的应用价值。然而,由于细胞应用前后的光学图像分析或其他低通量方法,生物细胞力测量方法是有限的,通常速度很慢。这项工作试图通过使用纳米级应变计来克服这一瓶颈,这种应变计可以实时测量细胞力作为电信号,并且能够同时测量数万个细胞。本文介绍了采用牺牲铝层法嵌入软质聚二甲基硅氧烷(PDMS)的金纳米级应变片的设计、COMSOL模拟、制作以及电学和力学测试。提出了一种采用铝牺牲层的工艺流程,成功地在软质PDMS聚合物上制作了100 nm尺寸的金应变片,并用于测量PDMS表面的应变。PDMS表面的压缩应变范围为0.4% ~ 1.7%,对应于718 ~ 2.0 μN的力,电阻变化幅度为1% ~ 8%。据我们所知,这些是在软聚合物上制造的最小的金属应变片,是一种很有前途的生物细胞力测量新方法。
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