用于纳升细胞悬浮液宽带介电特性分析的微通道生物传感器,频率高达 110 千兆赫

Biosensors Pub Date : 2024-06-30 DOI:10.3390/bios14070327
Wen Sun, Jianhua Wang, Jin Chen, Xiwei Huang, Xin Rao, Jiangtao Su, Yuqiao Huang, Boyu Zhang, Lingling Sun
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引用次数: 0

摘要

细胞介电特性测量因其无标记、无创伤的特性,在细胞检测和诊断中具有巨大的应用潜力。在这项研究中,我们开发了一种生物传感器,利用微波和毫米波共面波导与微通道相结合,测量液体样品的介电常数,特别是纳升尺度的细胞悬浮液。这种生物传感器可在 1 GHz 至 110 GHz 的频域内测量散射参数。然后,利用特定算法将获得的散射参数转换为介电常数。微通道内的细胞捕获结构可确保细胞悬浮液在测量区域内保持稳定。通过与 Keysight 的商用探头进行比较,证实了这种生物传感器的可行性。我们使用生物传感器测量了三种不同细胞悬浮液(HepG2、A549 和 MCF-7)的介电常数。我们还计算了在多次测量中捕获的每种细胞类型的细胞数量,并比较了介电常数的相应变化。结果表明,HepG2 细胞的介电常数实部比其他两种细胞低 0.2-0.8。A549 和 MCF-7 之间的差异相对较小,仅为 0.2-0.4。在测量过程中,细胞数量变化引起的介电频谱波动小于不同细胞类型之间的差异。因此,该传感器适用于测量细胞悬浮液,可用于识别生物细胞悬浮液的无标记、非侵入式研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Biosensor with Microchannel for Broadband Dielectric Characterization of Nanoliter Cell Suspensions up to 110 GHz
Cell dielectric property measurement holds significant potential for application in cell detection and diagnosis due to its label-free and noninvasive nature. In this study, we developed a biosensor designed to measure the permittivity of liquid samples, particularly cell suspensions at the nanoliter scale, utilizing microwave and millimeter wave coplanar waveguides in conjunction with a microchannel. This biosensor facilitates the measurement of scattering parameters within a frequency domain ranging from 1 GHz to 110 GHz. The obtained scattering parameters are then converted into dielectric constants using specific algorithms. A cell capture structure within the microchannel ensures that cell suspensions remain stable within the measurement zone. The feasibility of this biosensor was confirmed by comparison with a commercial Keysight probe. We measured the dielectric constants of three different cell suspensions (HepG2, A549, MCF-7) using our biosensor. We also counted the number of cells captured in multiple measurements for each cell type and compared the corresponding changes in permittivity. The results indicated that the real part of the permittivity of HepG2 cells is 0.2–0.8 lower than that of the other two cell types. The difference between A549 and MCF-7 was relatively minor, only 0.2–0.4. The fluctuations in the dielectric spectrum caused by changes in cell numbers during measurements were smaller than the differences observed between different cell types. Thus, the sensor is suitable for measuring cell suspensions and can be utilized for label-free, noninvasive studies in identifying biological cell suspensions.
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