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基于 MoS 纳米片的水凝胶超级电容器及其在葡萄糖监测中的应用

Hydrogel Capacitors Based on MoS Nanosheets and Applications in Glucose Monitoring.

机构信息

School of Intelligent Science and Control Engineering, Jinling Institute of Technology, Nanjing 211169, China.

College of Material and Chemical Engineering, Minjiang University, No. 200, Xiyuangong Road, Minhou District, Fuzhou 350108, China.

出版信息

Molecules. 2024 Sep 16;29(18):4401. doi: 10.3390/molecules29184401.

DOI:10.3390/molecules29184401
PMID:39339397
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11433974/
Abstract

Non-invasive/minimally invasive continuous monitoring of blood glucose and blood glucose administration have a high impact on chronic disease management in diabetic patients, but the existing technology is yet to achieve the above two purposes at the same time. Therefore, this study proposes a microfluidic microneedle patch based on 3D printing technology and an integrated control system design for blood glucose measurement, and a drug delivery control circuit based on a 555 chip. The proposed method provides an improved preparation of a PVA-PEG-MoS nanosheet hydrogel, making use of its dielectric properties to fabricate a microcapacitor and then embedding it in a microfluidic chip. When MoS nanosheets react with interstitial liquid glucose (and during the calibration process), the permittivity of the hydrogel is changed, resulting in changes in the capacitance of the capacitor. By converting the capacitance change into the square-wave period change in the output of the 555 chip with the control circuit design accordingly, the minimally invasive continuous measurement of blood glucose and the controlled release of hypoglycemic drugs are realized. In this study, the cross-linking structure of MoS nanosheets in hydrogel was examined using infrared spectroscopy and scanning electron microscopy (SEM) methods. Moreover, the critical doping mass fraction of MoS nanosheets was determined to be 2% via the measurement of the dielectric constant. Meanwhile, the circuit design and the relationship between the pulse cycle and glucose concentration is validated. The results show that, compared with capacitors in series, the microcapacitors embedded in microfluidic channels can be connected in parallel to obtain better linearized blood glucose measurement results.

摘要

非侵入性/微创连续监测血糖和血糖给药对糖尿病患者的慢性病管理有重大影响,但现有技术尚未同时实现这两个目的。因此,本研究提出了一种基于 3D 打印技术的微流控微针贴片和集成控制系统设计,用于血糖测量,以及基于 555 芯片的药物输送控制电路。所提出的方法提供了一种改进的 PVA-PEG-MoS 纳米片水凝胶的制备方法,利用其介电性能制造微电容器,并将其嵌入微流控芯片中。当 MoS 纳米片与间质液体葡萄糖反应(以及在校准过程中)时,水凝胶的介电常数会发生变化,从而导致电容器的电容发生变化。通过将电容变化转换为控制电路设计相应的 555 芯片输出的方波周期变化,实现了微创连续血糖测量和控释降血糖药物。在本研究中,使用红外光谱和扫描电子显微镜(SEM)方法检查了水凝胶中 MoS 纳米片的交联结构。此外,通过测量介电常数确定了 MoS 纳米片的临界掺杂质量分数为 2%。同时,验证了电路设计和脉冲周期与葡萄糖浓度之间的关系。结果表明,与串联电容器相比,嵌入微流道中的微电容器可以并联连接,以获得更好的线性血糖测量结果。

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