Glucose Sensor Printed on Algae-Based Substrates for Eco-Conscious Point-of-Care Devices

IF 2.2 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Sensors Letters Pub Date : 2024-11-25 DOI:10.1109/LSENS.2024.3505959

Emily Bezerra Alexandre;Tutku Beduk;Sabine Lengger;Mani Teja Vijjapu;Sandro Carrara;Jürgen Kosel

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Abstract

The rise of single-use electronics for fast health screening has prompted a reevaluation of traditional materials and manufacturing techniques to address the growing issue of electronic waste (e-waste). Inexpensive self-monitoring devices provide valuable insights into the body's essential metabolic functions. They can measure outrange values in key diseases, e.g., hyper- or hypoglycemia in diabetes. Currently, the prevalent use of nondegradable substrates and toxic metals in glycemia tests significantly contributes to plastic waste and e-waste. In this work, we propose an affordable and environmentally friendly glucose monitoring device printed on a bio-based and biocompatible substrate made of agar derived from red algae. The electrodes for the enzymatic electrochemical detection of glucose are composed of a carbon-based material, while the biorecognition element comprises of the enzyme glucose oxidase coupled with an electron mediator. The device demonstrated the electrochemical detection of physiological levels of glucose in the linear detection range of 1–15 mM, sufficient for accurately monitoring glucose level in patients’ blood. In addition, this glucose sensor exhibits a low interference from other electroactive species usually present in human tissues, including blood. This all-carbon electrode sensor manufactured on our bio-sourced substrate aids the development of the next generation, metal-free, eco-friendly devices for healthcare monitoring.

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葡萄糖传感器印刷在藻类为基础的生态意识点护理设备

用于快速健康检查的一次性电子产品的兴起促使人们重新评估传统材料和制造技术，以解决日益严重的电子废物问题。廉价的自我监测设备提供了对人体基本代谢功能的宝贵见解。它们可以测量关键疾病的异常值，例如糖尿病中的高血糖或低血糖。目前，在血糖测试中普遍使用不可降解的底物和有毒金属，这大大增加了塑料废物和电子废物。在这项工作中，我们提出了一种价格合理且环保的葡萄糖监测装置，该装置印刷在由红藻衍生的琼脂制成的生物基和生物相容性基质上。用于葡萄糖酶促电化学检测的电极由碳基材料组成，而生物识别元件由酶葡萄糖氧化酶偶联电子介质组成。该装置在1-15 mM的线性检测范围内实现了葡萄糖生理水平的电化学检测，足以准确监测患者血液中的葡萄糖水平。此外，这种葡萄糖传感器表现出低干扰其他电活性物质通常存在于人体组织，包括血液。这种全碳电极传感器是在我们的生物源基板上制造的，有助于开发下一代无金属、环保的医疗监测设备。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IEEE Sensors Letters Engineering-Electrical and Electronic Engineering

CiteScore

3.50

自引率

7.10%

发文量

194