A Non-Invasive Infrared Glucose Monitor Double Wavelength Based

Authors

  • Samuel dos Santos Cardoso Maria Valéria Rodrigues dos Santos https://orcid.org/0000-0001-5076-500X
  • Marcio Bender Machado Federal Institute of Education, Science and Technology of São Paulo, Campinas, SP, Brazil https://orcid.org/0000-0002-3887-5211
  • Julio Cesar Mesquita Ruzicki Federal Institute of Education, Science and Technology Sul-rio-grandense, Pelotas, RS, Brazil

Keywords:

Non-invasive, infrared, glucose monitor, eletronic patient, NIR

Abstract

This paper presents the analysis and implementation of a non-invasive blood glucose monitor using a near infrared absorption technique. The architecture is composed by two light emitters, with a wavelength of 940 nm and 805 nm. Contrary to most of the systems presented in the literature, our prototype considers the absorptive influence of hemoglobins in the measure. The results were carried out in-vitro through a electronic patient that emulates the basic characteristics of absorption in biological tissues. The experimental results obtained from the prototype, verify the funcionality of the system and signal some of the advantages over the some of the state-of-the-art techniques.

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Author Biographies

Samuel dos Santos Cardoso, Maria Valéria Rodrigues dos Santos

Is graduated in Electrical Engineering from the Federal Institute of Education, Science and Technology Sul-rio-grandense (IFsul) and is specialist in Software Engineering for Mobile Devices from the International University Center (Uninter). Currently he is a Master's degree student in the Graduate Program in Electrical Engineering at the Federal University of Santa Catarina (PPGEEL-UFSC), at the Institute of Biomedical Engineering (IEB-UFSC).

Marcio Bender Machado, Federal Institute of Education, Science and Technology of São Paulo, Campinas, SP, Brazil

Has Master and PhD in Electrical Engineering from the Federal University of Santa Catarina (doctorate in cooperation with Polystim Neurotechnology laboratory at Ecole Polytechnique in Montreal, Canada), graduated in Telecommunications from CEFET-RS. He received the award for best PhD thesis in microelectronics of the year 2015, by the Brazilian Microelectronics Society. He has research experience in the field of analog microelectronics, with emphasis on energy harvesting and biomedical engineering circuits. He has been a professor at the Federal Institutes of Brazil network since 2006. Currently, he is a professor of the Federal Institute of São Paulo.

Julio Cesar Mesquita Ruzicki, Federal Institute of Education, Science and Technology Sul-rio-grandense, Pelotas, RS, Brazil

Is graduated in Electrical Engineering with emphasis on Electronics from the Catholic University of Pelotas (UCPel). Master in Computer Science from the Federal University of Pelotas (UFPel). Currently, he is a professor in the Electrical Engineering Course at the Federal Institute of Education, Science and Technology Sul-rio-grandense (IFsul). He has experience in Embedded Systems, Industrial Automation and Instrumentation.

References

BRASIL, “Caderno de atenc¸ ˜ao b´asica n 16-diabetes mellitus,” 2006.

P. B¨ohme, M. Floriot, M.-A. Sirveaux, D. Durain, O. Ziegler, P. Drouin, and B. Guerci, “Evolution of analytical performance in portable glucose meters in the last decade,” Diabetes care, vol. 26, no. 4, pp. 1170–1175, 2003.

J. L. Smith, “The pursuit of noninvasive glucose,” Hunting the deceitful Turkey, 2006.

J. Yadav, A. Rani, V. Singh, and B. M. Murari, “Prospects and limitations of non-invasive blood glucose monitoring using near-infrared spectroscopy,” Biomedical signal processing and control, vol. 18, pp. 214–227, 2015.

R. Castro J´unior, “Glicos´ımetro de pulso,” Ph.D. dissertation, Universidade de S˜ao Paulo, 2010. [Online]. Available: http://www.teses.usp.br/teses/disponiveis/3/3142/tde-16082010-161914/

S. C. Lam, J. W. Chung, K. L. Fan, and T. K. Wong, “Non-invasive blood glucose measurement by near infrared spectroscopy: Machine drift, time drift and physiological effect,” Journal of Spectroscopy, vol. 24, no. 6, pp. 629–639, 2010.

E. S. Julian, K. Prawiroredjo, and G. Tjahjadi, “The model of near infrared sensor output voltage as a function of glucose concentration in solution,” in 2017 15th International Conference on Quality in Research (QiR): International Symposium on Electrical and Computer Engineering. IEEE, 2017, pp. 146–149.

S. Haxha and J. Jhoja, “Optical based noninvasive glucose monitoring sensor prototype,” IEEE Photonics Journal, vol. 8, no. 6, pp. 1–11, 2016.

O. Amir, D. Weinstein, S. Zilberman, M. Less, D. Perl-Treves, H. Primack, A. Weinstein, E. Gabis, B. Fikhte, and A. Karasik, “Continuous noninvasive glucose monitoring technology based on “occlusion spectroscopy”,” 2007.

J. Yadav, A. Rani, V. Singh, and B. M. Murari, “Near-infrared led based non-invasive blood glucose sensor,” in 2014 International Conference on Signal Processing and Integrated Networks (SPIN). IEEE, 2014, pp. 591–594.

J. G. Webster, Design of pulse oximeters. CRC Press, 1997.

J. T. Moyle, Pulse oximetry. BMJ books, 2002.

P. Narkhede, S. Dhalwar, and B. Karthikeyan, “Nir based non-invasive blood glucose measurement,” Indian Journal of Science and Technology, vol. 9, no. 41, 2016.

Y. Mendelson and J. C. Kent, “Variations in optical absorption spectra of adult and fetal haemoglobins and its effect on pulse oximetry,” IEEE Transactions on Biomedical Engineering, vol. 36, no. 8, pp. 844–848, 1989.

I. Fine and A. Weinreb, “Multiple scattering effect in transmission pulse oximetry,” Medical and Biological Engineering and Computing, vol. 33, no. 5, pp. 709–712, 1995.

L. N. T. Nghia, “Design of a spo2 pulse oximeter phototype,” Ph.D. dissertation, International University HCMC, Vietnam, 2012.

Z. Xu, “Method and system for non-invasive optical blood glucose detection utilizing spectral data analysis,” Dec. 25 2012, uS Patent 8,340,738.

L. E. Frenzel, Eletrˆonica Moderna. McGrawHill Education, 2012.

N. S. N. Santos and S. M. S. Motoyam, “A large scale platform using wban technology for patient monitoring,” IEEE Latin America Transactions, vol. 16, no. 3, pp. 705–711, 2018.

C. C. Porto, Semiologia m´edica. Guanabara Koogan, 2009.

M. J. Hayes and P. R. Smith, “A new method for pulse oximetry possessing inherent insensitivity to artifact,” IEEE Transactions on Biomedical Engineering, vol. 48, no. 4, pp. 452–461, 2001.

J. P. Tello, O. Manjarres, M. Quijano, A. Blanco, F. Varona, and M. Manrique, “Remote monitoring system of ecg and human body temperature signals,” IEEE Latin America Transactions, vol. 11, no. 1, pp. 314–318, 2013.

R. Terzi, Monitorizac¸ ˜ao respirat´oria em UTI. S˜ao Paulo: Atheneu, 1998.

D. E. ISO, “15197: In vitro diagnostic test systems– requirements for blood glucose monitoring systems for self-testing in managing diabetes mellitus,” (ISO 15197:2003), 2003.

ISO, “9919: Medical electrical equipment – particular requirements for the basic safety and essential performance of pulse oximeter equipment for medical use,” (ISO 9919:2005), 2005.

W. L. Clarke, D. Cox, L. A. Gonder-Frederick, W. Carter, and S. L. Pohl, “Evaluating clinical accuracy of systems for self-monitoring of blood glucose,” Diabetes care, vol. 10, no. 5, pp. 622–628, 1987.

R. Rosenthal, L. Paynter, and L. Mackie, “Non-invasive measurement of blood glucose,” Jul. 2 1991, uS Patent 5,028,787. [Online]. Available: https://www.google.com/patents/US5028787

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Published

2021-03-13

How to Cite

Cardoso, S., Bender Machado, M., & Mesquita Ruzicki, J. C. . (2021). A Non-Invasive Infrared Glucose Monitor Double Wavelength Based. IEEE Latin America Transactions, 18(9), 1572–1580. Retrieved from https://latamt.ieeer9.org/index.php/transactions/article/view/2704

Issue

Vol. 18 No. 9 (2020): Ordinary Issue

Section

Articles