基于二氧化锡纳米结构的丙酮呼吸分析传感器

IF 4.7 Q2 NANOSCIENCE & NANOTECHNOLOGY Micro and Nano Systems Letters Pub Date : 2024-01-04 DOI:10.1186/s40486-023-00196-5
Arunkumar Shanmugasundaram, Karthikeyan Munirathinam, Dong-Weon Lee
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引用次数: 0

摘要

世界卫生组织报告称,代谢紊乱在全球死亡率中占很大比例。有鉴于此,呼吸传感器作为监测和诊断代谢紊乱的有效工具,在最近的科技进步中占据了重要地位。在人类呼出的气体中,已发现 870 多种不同的挥发性有机成分 (VOC)。在几种挥发性有机化合物中,呼出气体中丙酮的检测在生物医学应用中受到了广泛关注。研究表明,人体呼气中丙酮含量高与多种疾病(如哮喘、口臭、肺癌和糖尿病)密切相关。例如,丙酮作为糖尿病的生物标志物尤其值得注意,因为在糖尿病患者呼出的气体中,丙酮的浓度往往超过百万分之 1.76,而健康人的浓度则低于百万分之 0.8。在这种非侵入性技术的帮助下,对与丙酮水平升高有关的疾病进行早期诊断和干预,有可能显著降低死亡率和医疗保健的经济负担。随着时间的推移,人们开发出了各种纳米结构气体传感技术,用于检测环境空气和呼出气体中的丙酮。本文简要回顾了丙酮气体传感的前沿研究,特别关注纳米结构金属氧化物。文章讨论了影响丙酮气体传感器性能的关键因素,包括影响其灵敏度、选择性和响应时间的丙酮浓度水平和工作温度。本综述旨在鼓励利用纳米结构材料进一步推动高性能丙酮气体传感器的开发,为更有效地控制代谢紊乱做出贡献。
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SnO2 nanostructure-based acetone sensors for breath analysis

The World Health Organization reports that metabolic disorders are responsible for a significant proportion of global mortality. Considering this, breath sensors have gained prominence as effective tools for monitoring and diagnosing metabolic disorders, thanks to recent advancements in science and technology. In human exhaled breath, over 870 distinct volatile organic components (VOCs) have been identified. Among several VOCs, the detection of acetone in exhaled breath has received considerable attention in biomedical applications. Research indicates a strong correlation between high acetone levels in human breath and several diseases, such as asthma, halitosis, lung cancer, and diabetes mellitus. For instance, acetone is particularly noteworthy as a biomarker in diabetes, where its concentration in exhaled breath often surpasses 1.76 parts per million (ppm), compared to less than 0.8 ppm in healthy individuals. Early diagnosis and intervention in diseases associated with elevated acetone levels, aided by such non-invasive techniques, have the potential to markedly reduce both mortality and the financial burden of healthcare. Over time, various nanostructured gas sensing technologies have been developed for detecting acetone in both ambient air and exhaled breath. This article presents a mini review of cutting-edge research on acetone gas sensing, focusing specifically on nanostructured metal oxides. It discusses critical factors influencing the performance of acetone gas sensors, including acetone concentration levels and operational temperature, which affect their sensitivity, selectivity, and response times. The aim of this review is to encourage further advancements in the development of high-performance acetone gas sensors utilizing nanostructured materials, contributing to more effective management of metabolic disorders.

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来源期刊
Micro and Nano Systems Letters
Micro and Nano Systems Letters Engineering-Biomedical Engineering
CiteScore
10.60
自引率
5.60%
发文量
16
审稿时长
13 weeks
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