评估中红外皮肤光谱技术在无创血糖监测中的机遇与局限性。

Evaluation of Opportunities and Limitations of Mid-Infrared Skin Spectroscopy for Noninvasive Blood Glucose Monitoring.

机构信息

South-Westphalia University of Applied Sciences, Interdisciplinary Center for Life Sciences, Iserlohn, Germany.

出版信息

J Diabetes Sci Technol. 2021 Jan;15(1):19-27. doi: 10.1177/1932296820936224. Epub 2020 Jun 26.

DOI:10.1177/1932296820936224

PMID:32590911

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7780363/

Abstract

BACKGROUND

A wide range of optical techniques has recently been presented for the development of noninvasive methods for blood glucose sensing based on multivariate skin spectrum analysis, and most recent studies are reviewed in short by us. The vibrational spectral fingerprints of glucose, as especially found in the mid-infrared or Raman spectrum, have been suggested for achieving largest selectivity for the development of noninvasive blood glucose methods.

METHODS

Here, the different aspects on integral skin measurements are presented, which are much dependent on the absorption characteristics of water as the main skin constituent. In particular, different mid-infrared measurement techniques as realized recently are discussed. The limitations of the use of the attenuated total reflection technique in particular are elaborated, and confounding skin or saliva spectral features are illustrated and discussed in the light of recently published works, claiming that the attenuated total reflection technique can be utilized for noninvasive measurements.

RESULTS

It will be shown that the penetration depth of the infrared radiation with wavelengths around 10 µm is the essential parameter, which can be modulated by different measurement techniques as with photothermal or diffuse reflection. However, the law of physics is limiting the option of using the attenuated total reflection technique with waveguides from diamond or similar optical materials.

CONCLUSIONS

There are confounding features from mucosa, , or saliva, which have been misinterpreted for glucose measurements. Results of an earlier study with multivariate evaluation based on glucose fingerprint features are again referred to as a negative experimental proof.

摘要

背景

最近提出了多种光学技术，用于通过多元皮肤光谱分析开发非侵入性血糖传感方法，我们对最近的研究进行了简要综述。已提出葡萄糖的振动光谱指纹（特别是在中红外或拉曼光谱中发现的），以实现非侵入性血糖方法开发的最大选择性。

方法

本文介绍了整体皮肤测量的不同方面，这些方面主要取决于水作为主要皮肤成分的吸收特性。特别讨论了最近实现的不同中红外测量技术。详细阐述了衰减全反射技术的使用限制，并根据最近发表的声称可以用于非侵入性测量的工作，说明了和讨论了有混淆的皮肤或唾液光谱特征。

结果

将表明，波长约为 10 μm 的红外辐射的穿透深度是基本参数，该参数可以通过不同的测量技术（如光热或漫反射）来调制。然而，物理定律限制了使用具有金刚石或类似光学材料的波导的衰减全反射技术的选择。

结论

存在来自粘膜、唾液或口腔的混淆特征，这些特征被错误地解释为用于血糖测量。基于葡萄糖指纹特征的多元评估的早期研究结果再次被作为否定的实验证明。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3f4f/7783022/f26589cb5518/10.1177_1932296820936224-fig6.jpg

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评估中红外皮肤光谱技术在无创血糖监测中的机遇与局限性。

Evaluation of Opportunities and Limitations of Mid-Infrared Skin Spectroscopy for Noninvasive Blood Glucose Monitoring.

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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