research-article

Noninvasive glucose monitoring using polarized light

Authors:

Temiloluwa Prioleau,

Xia ZhouAuthors Info & Claims

SenSys '20: Proceedings of the 18th Conference on Embedded Networked Sensor Systems

Pages 544 - 557

https://doi.org/10.1145/3384419.3430720

Published: 16 November 2020 Publication History

Abstract

We propose a compact noninvasive glucose monitoring system using polarized light, where a user simply needs to place her palm on the device for measuring her current glucose concentration level. The primary innovation of our system is the ability to minimize light scattering from the skin and extract weak changes in light polarization to estimate glucose concentration, all using low-cost hardware. Our system exploits multiple wavelengths and light intensity levels to mitigate the effect of user diversity and confounding factors (e.g., collagen and elastin in the dermis). It then infers glucose concentration using a generic learning model, thus no additional calibration is needed. We design and fabricate a compact (17 cm x 10 cm x 5 cm) and low-cost (i.e., <$250) prototype using off-the-shelf hardware. We evaluate our system with 41 diabetic patients and 9 healthy participants. In comparison to a continuous glucose monitor approved by U.S. Food and Drug Administration (FDA), 89% of our results are within zone A (clinically accurate) of the Clarke Error Grid. The absolute relative difference (ARD) is 10%. The r and p values of the Pearson correlation coefficients between our predicted glucose concentration and reference glucose concentration are 0.91 and 1.6 x 10^-143, respectively. These errors are comparable with FDA-approved glucose sensors, which achieve ≈90% clinical accuracy with a 10% mean ARD.

References

[1]

2019. Diabetes Statistics. https://www.diabetesresearch.org/diabetes-statistics. (2019).

[2]

2019. FreeStyle Libre CGM sensors. https://www.freestylelibre.us/. (2019).

[3]

2019. Stereochemistry of Sugars: Diastereorners. http://www.chem.uiuc.edu/organic/. (2019).

[4]

Simon Alaluf, Alan Heath, NIK Carter, Derek Atkins, Harish Mahalingam, Karen Barrett, RIA Kolb, and Nico Smit. 2001. Variation in melanin content and composition in type V and VI photoexposed and photoprotected human skin: the dominant role of DHI. Pigment Cell Research 14, 5 (2001), 337--347.

[5]

Alexandra Amaro-Ortiz, Betty Yan, and John A D'Orazio. 2014. Ultraviolet radiation, aging and the skin: prevention of damage by topical cAMP manipulation. Molecules 19, 5 (2014), 6202--6219.

[6]

Caerwyn Ash, Michael Dubec, Kelvin Donne, and Tim Bashford. 2017. Effect of wavelength and beam width on penetration in light-tissue interaction using computational methods. Lasers in medical science 32, 8 (2017), 1909--1918.

[7]

Amay J Bandodkar, Wenzhao Jia, Ceren Yardimci, Xuan Wang, Julian Ramirez, and Joseph Wang. 2014. Tattoo-based noninvasive glucose monitoring: a proof-of-concept study. Analytical chemistry 87, 1 (2014), 394--398.

[8]

Ananda Basu, Simmi Dube, Michael Slama, Isabel Errazuriz, Jose Carlos Amezcua, Yogish C Kudva, Thomas Peyser, Rickey E Carter, Claudio Cobelli, and Rita Basu. 2013. Time lag of glucose from intravascular to interstitial compartment in humans. Diabetes 62, 12 (2013), 4083--4087.

[9]

Alexander Bauer, Otto Hertzberg, Arne Küderle, Dominik Strobel, Miguel A Pleitez, and Werner Mäntele. 2018. IR-spectroscopy of skin in vivo: Optimal skin sites and properties for non-invasive glucose measurement by photoacoustic and photothermal spectroscopy. Journal of biophotonics 11, 1 (2018), e201600261.

[10]

Brent D Cameron and Gerard L Cote. 1997. Noninvasive glucose sensing utilizing a digital closed-loop polarimetric approach. IEEE Transactions on Biomedical Engineering 44, 12 (1997), 1221--1227.

[11]

Chih-Chung Chang and Chih-Jen Lin. 2011. LIBSVM: A library for support vector machines. ACM transactions on intelligent systems and technology (TIST) 2, 3 (2011), 1--27.

Digital Library

[12]

Jason Yuanzhe Chen, Qi Zhou, Gu Xu, Ryan Taoran Wang, Edward Guangqing Tai, Longhan Xie, Qianzhi Zhang, Yanyan Guan, and Xiaochun Huang. 2019. Non-invasive blood glucose measurement of 95% certainty by pressure regulated Mid-IR. Talanta 197 (2019), 211--217.

[13]

Tseng-Lin Chen, Yu-Lung Lo, Chia-Chi Liao, and Quoc-Hung Phan. 2018. Noninvasive measurement of glucose concentration on human fingertip by optical coherence tomography. Journal of biomedical optics 23, 4 (2018), 047001.

[14]

Zhen-cheng Chen, Xing-liang Jin, Jian-ming Zhu, Di-ya Wang, and Ting-ting Zhang. 2009. Non-invasive glucose measuring apparatus based on conservation of energy method. Journal of Central South University of Technology 16, 6 (2009), 982.

[15]

Ok Kyung Cho, Yoon Ok Kim, Hiroshi Mitsumaki, and Katsuhiko Kuwa. 2004. Noninvasive measurement of glucose by metabolic heat conformation method. Clinical chemistry 50, 10 (2004), 1894--1898.

[16]

Soyun Cho, Mi Hee Shin, Yeon Kyung Kim, Jo-Eun Seo, Young Mee Lee, Chi-Hyun Park, and Jin Ho Chung. 2009. Effects of infrared radiation and heat on human skin aging in vivo. In Journal of Investigative Dermatology Symposium Proceedings, Vol. 14. Elsevier, 15--19.

[17]

Md Koushik Chowdhury, S Anuj, S Neeraj, and S Shiru. 2015. Error Grid Analysis of Reference and Predicted Blood Glucose Level Values as Obtained from The Normal and Prediabetic Human Volunteer. American Journal of Biomedical Engineering 5, 1 (2015), 6--14.

[18]

Mark Christiansen, Timothy Bailey, Elaine Watkins, David Liljenquist, David Price, Katherine Nakamura, Robert Boock, and Thomas Peyser. 2013. A new-generation continuous glucose monitoring system: improved accuracy and reliability compared with a previous-generation system. Diabetes technology & therapeutics 15, 10 (2013), 881--888.

[19]

Claudio Cobelli, Michele Schiavon, Chiara Dalla Man, Ananda Basu, and Rita Basu. 2016. Interstitial fluid glucose is not just a shifted-in-time but a distorted mirror of blood glucose: insight from an in silico study. Diabetes technology & therapeutics 18, 8 (2016), 505--511.

[20]

Gerard L Cote. 2001. Noninvasive and minimally-invasive optical monitoring technologies. The Journal of nutrition 131, 5 (2001), 1596S--1604S.

[21]

Leszek Czupryniak, László Barkai, Svetlana Bolgarska, Agata Bronisz, Jan Broz, Katarzyna Cypryk, Marek Honka, Andrej Janez, Mladen Krnic, Nebojsa Lalic, and others. 2014. Self-monitoring of blood glucose in diabetes: from evidence to clinical reality in Central and Eastern Europe---recommendations from the international Central-Eastern European expert group. Diabetes technology & therapeutics 16, 7 (2014), 460--475.

[22]

Carlos Eduardo Ferrante do Amaral and Benhard Wolf. 2008. Current development in non-invasive glucose monitoring. Medical engineering & physics 30, 5 (2008), 541--549.

[23]

Annika MK Enejder, Thomas G Scecina, Jeankun Oh, Martin Hunter, WeiChuan Shih, Slobodan Sasic, Gary L Horowitz, and Michael S Feld. 2005. Raman spectroscopy for noninvasive glucose measurements. Journal of Biomedical Optics 10, 3 (2005), 031114.

[24]

Michael M Engelgau, KM Narayan, and William H Herman. 2000. Screening for type 2 diabetes. Diabetes care 23, 10 (2000), 1563--1580.

[25]

A Ergin, MJ Vilaboy, A Tchouassi, R Greene, and GA Thomas. 2003. Detection and analysis of glucose at metabolic concentration using Raman spectroscopy. In 2003 IEEE 29th Annual Proceedings of Bioengineering Conference. IEEE, 337--338.

[26]

Jerome H Friedman. 2002. Stochastic gradient boosting. Computational statistics & data analysis 38, 4 (2002), 367--378.

Digital Library

[27]

Nirmalya Ghosh, Michael FG Wood, Shu-hong Li, Richard D Weisel, Brian C Wilson, Ren-Ke Li, and I Alex Vitkin. 2009. Mueller matrix decomposition for polarized light assessment of biological tissues. Journal of biophotonics 2, 3 (2009), 145--156.

[28]

Willemijn Groenendaal, Golo Von Basum, Kristiane A Schmidt, Peter AJ Hilbers, and Natal AW van Riel. 2010. Quantifying the composition of human skin for glucose sensor development. (2010).

[29]

Xinxin Guo, Michael FG Wood, Nirmalya Ghosh, and I Alex Vitkin. 2010. Depolarization of light in turbid media: a scattering event resolved Monte Carlo study. Applied optics 49, 2 (2010), 153--162.

[30]

Steven L Jacques, Kenneth Lee, and Jessica C Ramella-Roman. 2000. Scattering of polarized light by biological tissues. In Saratov Fall Meeting'99: Optical Technologies in Biophysics and Medicine, Vol. 4001. International Society for Optics and Photonics, 14--28.

[31]

Jayoung Kim, Alan S Campbell, and Joseph Wang. 2018. Wearable non-invasive epidermal glucose sensors: A review. Talanta 177 (2018), 163--170.

[32]

DF Kimball, D Budker, DS English, C-H Li, A-T Nguyen, SM Rochester, A Sushkov, VV Yashchuk, and M Zolotorev. 2001. Progress towards fundamental symmetry tests with nonlinear optical rotation. In AIP Conference Proceedings, Vol. 596. AIP, 84--107.

[33]

Jae B Ko, Ok K Cho, Yoon O Kim, and Kazuo Yasuda. 2004. Body metabolism provides a foundation for noninvasive blood glucose monitoring. Diabetes care 27, 5 (2004), 1211--1212.

[34]

Paul AJ Kolarsick, Maria Ann Kolarsick, and Carolyn Goodwin. 2011. Anatomy and physiology of the skin. Journal of the Dermatology Nurses' Association 3, 4 (2011), 203--213.

[35]

Jonas Kottmann, Julien Rey, and Markus Sigrist. 2016. Mid-Infrared photoacoustic detection of glucose in human skin: towards non-invasive diagnostics. Sensors 16, 10 (2016), 1663.

[36]

Jonas Kottmann, Julien M Rey, Joachim Luginbühl, Ernst Reichmann, and Markus W Sigrist. 2012. Glucose sensing in human epidermis using mid-infrared photoacoustic detection. Biomedical optics express 3, 4 (2012), 667--680.

[37]

Chak-hing Lam. 2009. Clinical evaluation of non-invasive blood glucose measurement by using near infrared spectroscopy via inter-and intra-subject analysis. Ph.D. Dissertation. The Hong Kong Polytechnic University.

[38]

Sabbir Liakat, Kevin A Bors, Laura Xu, Callie M Woods, Jessica Doyle, and Claire F Gmachl. 2014. Noninvasive in vivo glucose sensing on human subjects using mid-infrared light. Biomedical optics express 5, 7 (2014), 2397--2404.

[39]

Chia-Chi Liao and Yu-Lung Lo. 2015. Extraction of linear anisotropic parameters using optical coherence tomography and hybrid Mueller matrix formalism. Optics Express 23, 8 (2015), 10653--10667.

[40]

Tamar Lin, Avner Gal, Yulia Mayzel, Keren Horman, and Karnit Bahartan. 2017. Non-invasive glucose monitoring: a review of challenges and recent advances. Curr. Trends Biomed. Eng. Biosci 6 (2017), 1--8.

[41]

Yu-Lung Lo and Tsung-Chih Yu. 2006. A polarimetric glucose sensor using a liquid-crystal polarization modulator driven by a sinusoidal signal. Optics communications 259, 1 (2006), 40--48.

[42]

A Losoya-Leal, S Camacho-León, G Dieck-Assad, and SO Martínez-Chapa. 2012. State of the art and new perspectives in non-invasive glucose sensors. Revista Mexicana De Ingeniería Biomédica 33, 1 (2012), 41--52.

[43]

Signe M Lundsgaard-Nielsen, Anders Pors, Stefan O Banke, Jan E Henriksen, Dietrich K Hepp, and Anders Weber. 2018. Critical-depth Raman spectroscopy enables home-use non-invasive glucose monitoring. PloS one 13, 5 (2018), e0197134.

[44]

Mon Arjay Malbog and Noel Linsangan. 2018. Non-invasive glucose meter for android-based devices. In Proceedings of the 2018 10th International Conference on Computer and Automation Engineering. 161--165.

Digital Library

[45]

Roger Mazze, Yariv Yogev, and Oded Langer. 2012. Measuring glucose exposure and variability using continuous glucose monitoring in normal and abnormal glucose metabolism in pregnancy. The Journal of Maternal-Fetal & Neonatal Medicine 25, 7 (2012), 1171--1175.

[46]

Roger J McNichols and Gerard L Cote. 2000. Optical glucose sensing in biological fluids: an overview. Journal of biomedical optics 5, 1 (2000), 5--17.

[47]

Mehrdad Mehdizadeh. 2010. Microwave/RF Applicators and Probes. (2010).

[48]

Pradipta Mukherjee, Nathan Hagen, and Yukitoshi Otani. 2019. Glucose sensing in the presence of scattering by analyzing a partial Mueller matrix. Optik 180 (2019), 775--781.

[49]

Asmat Nawaz, Per Øhlckers, Steinar Sælid, Morten Jacobsen, and M Nadeem Akram. 2016. Non-invasive continuous blood glucose measurement techniques. Journal of Bioinformatics and Diabetes 1, 3 (2016), 01.

[50]

Praful P Pai, Pradyut Kumar Sanki, Arijit De, and Swapna Banerjee. 2015. NIR photoacoustic spectroscopy for non-invasive glucose measurement. In 2015 37th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC). IEEE, 7978--7981.

[51]

Quoc-Hung Phan, Tzu-Hsiang Jian, Yu-Ru Huang, You-Rui Lai, Wei-Zhe Xiao, and Shin-Wei Chen. 2020. Combination of surface plasmon resonance and differential Mueller matrix formalism for noninvasive glucose sensing. Optics and Lasers in Engineering 134 (2020), 106268.

[52]

Raju Poddar, Joseph Thomas Andrews, Pratyoosh Shukla, and Pratima Sen. 2008. Non-invasive glucose monitoring techniques: A review and current trends. arXiv preprint arXiv:0810.5755 (2008).

[53]

Russell O Potts, Janet A. Tamada, and Michael J. Tierney. 2002. Glucose monitoring by reverse iontophoresis. Diabetes/metabolism research and reviews 18, S1 (2002), S49--S53.

[54]

Georgeanne Purvinis, Brent D Cameron, and Douglas M Altrogge. 2011. Noninvasive polarimetric-based glucose monitoring: an in vivo study. Journal of diabetes science and technology 5, 2 (2011), 380--387.

[55]

Yun Qian, Yanchun Liang, Mu Li, Guoxiang Feng, and Xiaohu Shi. 2014. A resampling ensemble algorithm for classification of imbalance problems. Neuro-computing 143 (2014), 57--67.

Digital Library

[56]

Bernard Querleux, Thérèse Baldeweck, Stéphane Diridollou, Jean De Rigal, Etienne Huguet, Frédéric Leroy, and Victoria Holloway Barbosa. 2009. Skin from various ethnic origins and aging: an in vivo cross-sectional multimodality imaging study. Skin Research and Technology 15, 3 (2009), 306--313.

[57]

Anthony V Rawlings. 2006. Ethnic skin types: are there differences in skin structure and function? 1. International journal of cosmetic science 28, 2 (2006), 79--93.

[58]

Florian Reiterer, Philipp Polterauer, Michael Schoemaker, Guenther Schmelzeisen-Redecker, Guido Freckmann, Lutz Heinemann, and Luigi Del Re. 2017. Significance and reliability of MARD for the accuracy of CGM systems. Journal of diabetes science and technology 11, 1 (2017), 59--67.

[59]

Zhong Ren, Guodong Liu, and Zhen Huang. 2014. Noninvasive detection of glucose level based on tunable pulsed laser induced photoacoustic technique. In International Symposium on Optoelectronic Technology and Application 2014: Laser and Optical Measurement Technology; and Fiber Optic Sensors, Vol. 9297. International Society for Optics and Photonics, 929709.

[60]

David Rodbard. 2017. Continuous glucose monitoring: a review of recent studies demonstrating improved glycemic outcomes. Diabetes technology & therapeutics 19, S3 (2017), S-25.

[61]

Silonie Sachdeva and others. 2009. Fitzpatrick skin typing: Applications in dermatology. Indian Journal of Dermatology, Venereology, and Leprology 75, 1 (2009), 93.

[62]

Sanjiv Sharma, Zhenyi Huang, Michelle Rogers, Martyn Boutelle, and Anthony EG Cass. 2016. Evaluation of a minimally invasive glucose biosensor for continuous tissue monitoring. Analytical and bioanalytical chemistry 408, 29 (2016), 8427--8435.

[63]

Joo Yong Sim, Chang-Geun Ahn, Eun-Ju Jeong, and Bong Kyu Kim. 2018. In vivo microscopic photoacoustic spectroscopy for non-invasive glucose monitoring invulnerable to skin secretion products. Scientific reports 8, 1 (2018), 1059.

[64]

Jitendra Solanki, Om Prakash Choudhary, Pratima Sen, and Joseph Thomas Andrews. 2013. Polarization sensitive optical low-coherence reflectometry for blood glucose monitoring in human subjects. Review of Scientific Instruments 84, 7 (2013), 073114.

[65]

MJ Tierney, HL Kim, MD Burns, JA Tamada, and RO Potts. 2000. Electroanalysis of glucose in transcutaneously extracted samples. Electroanalysis: An International Journal Devoted to Fundamental and Practical Aspects of Electroanalysis 12, 9 (2000), 666--671.

[66]

GT Tucker and MS Lennard. 1990. Enantiomer specific pharmacokinetics. Pharmacology & therapeutics 45, 3 (1990), 309--329.

[67]

Sandeep Kumar Vashist. 2012. Non-invasive glucose monitoring technology in diabetes management: A review. Analytica chimica acta 750 (2012), 16--27.

[68]

Sandeep Kumar Vashist, Dan Zheng, Khalid Al-Rubeaan, John HT Luong, and Fwu-Shan Sheu. 2011. Advances in carbon nanotube based electrochemical sensors for bioanalytical applications. Biotechnology advances 29, 2 (2011), 169--188.

[69]

Jeanette M Waller and Howard I Maibach. 2005. Age and skin structure and function, a quantitative approach (I): blood flow, pH, thickness, and ultrasound echogenicity. Skin research and technology 11, 4 (2005), 221--235.

[70]

Stuart Alan Weinzimer. 2004. Analysis: PENDRA: The Once and Future Noninvasive Continuous Glucose Monitoring Device? Diabetes technology & therapeutics 6, 4 (2004), 442--444.

[71]

Michael FG Wood, Nirmalya Ghosh, Xinxin Guo, and I Alex Vitkin. 2008. Towards noninvasive glucose sensing using polarization analysis of multiply scattered light. Handbook of optical sensing of glucose in biological fluids and tissues 12 (2008).

[72]

Jyoti Yadav, Asha Rani, Vijander Singh, and Bhaskar Mohan Murari. 2014. Near-infrared LED based non-invasive blood glucose sensor. In 2014 International Conference on Signal Processing and Integrated Networks (SPIN). IEEE, 591--594.

[73]

Kamal Youcef-Toumi and Vidi A Saptari. 1999. Noninvasive blood glucose analysis using near infrared absorption spectroscopy. The Home Automation and Healthcare Consortium (1999), 2--3.

[74]

Chiara Zecchin, Andrea Facchinetti, Giovanni Sparacino, Chiara Dalla Man, Chinmay Manohar, James A Levine, Ananda Basu, Yogish C Kudva, and Claudio Cobelli. 2013. Physical activity measured by physical activity monitoring system correlates with glucose trends reconstructed from continuous glucose monitoring. Diabetes technology & therapeutics 15, 10 (2013), 836--844.

[75]

Huiting Zheng, Jiabin Yuan, and Long Chen. 2017. Short-term load forecasting using EMD-LSTM neural networks with a Xgboost algorithm for feature importance evaluation. Energies 10, 8 (2017), 1168.

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Xiao RZhao LQian FYang LHan JOkoshi TKo JLiKamWa R(2024)Practical Optical Camera Communication Behind Unseen and Complex BackgroundsProceedings of the 22nd Annual International Conference on Mobile Systems, Applications and Services10.1145/3643832.3661866(113-126)Online publication date: 3-Jun-2024
https://dl.acm.org/doi/10.1145/3643832.3661866
Huang PLo YChen YLiu C(2024)Mueller matrix polarimetry approach for noninvasive glucose sensing with absorbance and anisotropic parameters on fingertipsJournal of Biophotonics10.1002/jbio.20240005217:9Online publication date: 2-Jul-2024
https://doi.org/10.1002/jbio.202400052
Di Filippo DSunstrum FKhan JWelsh A(2023)Non-Invasive Glucose Sensing Technologies and Products: A Comprehensive Review for Researchers and CliniciansSensors10.3390/s2322913023:22(9130)Online publication date: 12-Nov-2023
https://doi.org/10.3390/s23229130
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Index Terms

Noninvasive glucose monitoring using polarized light
1. Hardware
  1. Communication hardware, interfaces and storage
    1. Sensor devices and platforms
2. Human-centered computing
  1. Ubiquitous and mobile computing

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SenSys '20: Proceedings of the 18th Conference on Embedded Networked Sensor Systems

November 2020

852 pages

ISBN:9781450375900

DOI:10.1145/3384419

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Published: 16 November 2020

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Huang PLo YChen YLiu C(2024)Mueller matrix polarimetry approach for noninvasive glucose sensing with absorbance and anisotropic parameters on fingertipsJournal of Biophotonics10.1002/jbio.20240005217:9Online publication date: 2-Jul-2024
https://doi.org/10.1002/jbio.202400052
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