基于不同纳米孔结构的无标记纳米孔阻抗生物传感器的优化

Biosensors Pub Date : 2024-09-04 DOI:10.3390/bios14090426
Ali Fardoost, Hassan Raji, Mehdi Javanmard
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引用次数: 0

摘要

与传统的基于阻抗的生物传感器相比,基于纳米孔的阻抗无标记生物传感器在检测癌症生物标记物和大分子的灵敏度、简便性和准确性方面具有显著优势。虽然纳米孔阵列以前曾被用于生物标记物检测,但其制造过程中的光刻步骤存在明显的局限性,导致效率降低。一直以来,这些纳米孔的直径都是 2 微米。为了解决这个问题,我们提出了纳米孔的替代几何形状,它们具有更大的表面积,同时保持相似的周长,从而提高了生物传感器的制造效率。我们研究了三种几何形状:管状、螺旋状和四叶形。使用锁相放大器每隔 10 分钟对样品进行一次阻抗测量。研究使用浓度为 100 nM 的白细胞介素-6(IL-6)抗体和抗原/蛋白质作为目标大分子。结果表明,管状纳米孔检测 IL-6 蛋白的灵敏度最高,阻抗变化率为 9.55%。相比之下,螺旋形、四叶形和圆形的阻抗变化分别为 0.91%、0.95% 和 1.62%。因此,在未来的研究中,管形纳米孔结构有望替代传统的纳米孔阵列,从而提高生物传感器制造的效率和灵敏度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Optimization of Nanowell-Based Label-Free Impedance Biosensor Based on Different Nanowell Structures
Nanowell-based impedance-based label-free biosensors have demonstrated significant advantages in sensitivity, simplicity, and accuracy for detecting cancer biomarkers and macromolecules compared to conventional impedance-based biosensors. Although nanowell arrays have previously been employed for biomarker detection, a notable limitation exists in the photolithography step of their fabrication process, leading to a reduced efficiency rate. Historically, the diameter of these nanowells has been 2 μm. To address this issue, we propose alternative geometries for nanowells that feature larger surface areas while maintaining a similar circumference, thereby enhancing the fabrication efficiency of the biosensors. We investigated three geometries: tube, spiral, and quatrefoil. Impedance measurements of the samples were conducted at 10 min intervals using a lock-in amplifier. The study utilized interleukin-6 (IL-6) antibodies and antigens/proteins at a concentration of 100 nM as the target macromolecules. The results indicated that tube-shaped nanowells exhibited the highest sensitivity for detecting IL-6 protein, with an impedance change of 9.55%. In contrast, the spiral, quatrefoil, and circle geometries showed impedance changes of 0.91%, 0.95%, and 1.62%, respectively. Therefore, the tube-shaped nanowell structure presents a promising alternative to conventional nanowell arrays for future studies, potentially enhancing the efficiency and sensitivity of biosensor fabrication.
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