用于微创血糖监测的反应性水凝胶微针系统

Q1 Engineering
Yan Wang , Haiyang Liu , Xuxia Yang , Zhekun Shi , Jingwen Li , Longjian Xue , Sheng Liu , Yifeng Lei
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引用次数: 9

摘要

糖尿病患者血糖监测对糖尿病管理至关重要。微创BG监测是提高患者依从性的迫切需要。在此,我们基于反应性水凝胶系统,开发了一种用于微创血糖监测的智能微针贴片系统。该贴片由透明的光固化树脂基片和由ph响应和葡萄糖响应水凝胶制成的微针组成。反应性水凝胶由光交联甲基丙烯酸明胶水凝胶(GelMA)、ph响应纳米凝胶(nano(CMC-pHEA))和葡萄糖氧化酶(GOx)组成。复合水凝胶在生理范围内对葡萄糖水平具有快速响应和高敏感性,这主要是由于CMC-pHEA组分的电离和质子平衡。该微针具有足够的机械强度,能以最小的侵入性穿透小鼠皮肤,并实现了间质液(ISF)中葡萄糖的原位提取和原位葡萄糖反应。研究了微针贴片系统在模拟皮肤凝胶和糖尿病小鼠体内的快速血糖监测。微针对葡萄糖浓度的反应迅速而灵敏,通过微针高度和膨胀率的变化可以定量读出葡萄糖水平。此外,小鼠体内的读数与血糖仪测量的BG水平一致。该智能微针系统具有替代采血的潜力,能够最大限度地减少患者在BG检测过程中的不适,因此具有微创、快速、可靠的BG监测潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A responsive hydrogel-based microneedle system for minimally invasive glucose monitoring

A responsive hydrogel-based microneedle system for minimally invasive glucose monitoring

Blood glucose (BG) monitoring in patients with diabetes is critical for diabetes management. Minimally invasive BG monitoring is urgently required to increase the patient compliance. Herein, based on a responsive hydrogel system, we developed a smart microneedle patch system for minimally invasive glucose monitoring. The patch consisted of a transparent substrate of photocurable resin and microneedles made of a pH-responsive and glucose-responsive hydrogel. The responsive hydrogel was composed of a photocrosslinkable hydrogel of gelatin methacrylate (GelMA) together with a pH-responsive nanogel (nano(CMC-pHEA)) and glucose oxidase (GOx). The composite hydrogel showed fast response and high sensitivity to glucose levels in physiological range, mainly due to the ionization of CMC-pHEA component and proton balance. The microneedles showed sufficient mechanical strength to penetrate the skin of mice with minimal invasion, and achieved in situ extraction of glucose in interstitial fluid (ISF) and in situ glucose-responsive reaction. We demonstrated the rapid glucose monitoring by microneedle patch system in skin-mimicking gels in vitro and in diabetic mice in vivo. The microneedles quickly and sensitively responded to glucose concentrations, allowed quantitative readouts of glucose levels through the changes of microneedle heights and swelling ratios. Moreover, the readouts in mice in vivo were consistent with BG levels measured by glucometer. This smart microneedle system has potentials to replace blood sampling, and minimize patient discomfort during BG testing, therefore has potentials in minimally invasive, rapid and reliable BG monitoring.

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来源期刊
Smart Materials in Medicine
Smart Materials in Medicine Engineering-Biomedical Engineering
CiteScore
14.00
自引率
0.00%
发文量
41
审稿时长
48 days
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