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将先进的微电子技术与信号处理和传感接口相结合,以产生预期传感器设备为目标,已成为具有巨大潜力的快速发展领域。目标传感器是独立的集成设备,它使用与物理导入元件直接接触的物质识别元件提供定量分析信息。声波的使用是最合适的直接转导机制之一,声波的产生有多种途径,其中压电效应在声波的产生和接收中应用最为广泛。压电传感器是一种声学传感器,它能够对生物事件进行实时选择和无标签检测。石英晶体微天平(QCM)是基于石英晶体的压电效应而制成的表面敏感型分析技术,是非常灵敏的质量检测仪器,测量精度可达纳克级,并且具有广泛的应用领域,如监测和表征(生物)膜沉积,检测特定抗原,研究生物分子结合动力学,细胞黏附和DNA检测。本研究综述了QCM在细胞、环境监测、纤维素酶水解、电化学等领域的应用,以期为动态监测及微量检测等方面的研究提供技术借鉴。
Application and development of quartz crystal microbalance (QCM)
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摘要: 石英晶体微天平(QCM)是基于石英晶体的压电效应而制成的表面敏感型分析技术,是高灵敏的在线表界面过程分析工具,具有纳克级的灵敏度,可以原位、实时反映石英晶片表面的质量变化。QCM的实时监测、表征(生物)膜沉积、检测特定抗原和研究细胞黏附等特点在化学、物理、生物等领域有着广泛的应用。本研究介绍了QCM的技术原理以及综述了近年来QCM在细胞、环境监测、纤维素酶水解、电化学等方面的应用,展望了QCM技术可能应用的新方向。参40
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关键词:
- 石英晶体微天平(QCM) /
- 细胞 /
- 环境监测 /
- 纤维素酶水解 /
- 电化学
Abstract: As a surface sensitive analysis technique based on the piezoelectric effect of quartz crystal, quartz crystal microbalance (QCM) is a highly sensitive on-line interface process analysis tool featured with the sensitivity of Nanogram level and a in-situ and real-time reflection of the surface quality change of the crystal wafer. The strengths of QCM in real-time monitoring, characterization of (biological) membrane deposition, detection of specific antigens and research on cell adhesion have been widely explored in the fields of chemistry, physics and biology. This paper, with an introduction of the technical principles of QCM and an overview of its applications in cells, environmental monitoring, enzymatic hydrolysis, electrochemistry and other fields in recent years, is aimed to prospect the research direction of QCM in the future. [Ch, 40 ref.] -
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https://zlxb.zafu.edu.cn/article/doi/10.11833/j.issn.2095-0756.20190570
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