Development and Analysis of a Multi-Wavelength Near-Infrared Sensor for Monitoring Skin Hydration and Validation Using Monte Carlo Simulation

Iman Gidado; Raghda Al-Halawani; Meha Qassem; Panicos Kyriacou

doi:10.1007/s13320-024-0719-z

Photonic Sensors ›› 2024, Vol. 14 ›› Issue (3) : 240306. DOI: 10.1007/s13320-024-0719-z

Regular

Development and Analysis of a Multi-Wavelength Near-Infrared Sensor for Monitoring Skin Hydration and Validation Using Monte Carlo Simulation

Author information +

History +

Abstract

The monitoring of an individual’s hydration levels is a vital measurement required for the maintenance of a healthy skin barrier function as well as the avoidance of dehydration. The current commercial devices for this measure are typically based on electrical methodologies, such as capacitance, which allows for the extraction of skin hydration using the ionic balance deviations in the stratum corneum. The use of optical-based methods such as near-infrared spectroscopy (NIRS) has been recently explored for the measurement of skin hydration. Optical approaches have the ability to penetrate deeper into the skin layers and provide detailed information on the optical properties of present water bands. This paper presents the development of a multi-wavelength optical sensor and its capability of assessing skin hydration in an in vitro experiment utilizing porcine skin. Regression analysis of the results showed to be in line with standard reference measurements (R ² CV=0.952257), validating the accuracy of the developed sensor in measuring dermal water content. A Monte Carlo model of the human skin was also developed and simulated to predict the optical sensor’s performance at variable water concentrations. This model serves as a tool for validating the sensor measurement accuracy. The output from this model gave a standard expectation of the device, which agreed with trends seen in the in vitro work. This research strongly suggests that non-invasive (wearable) NIR based sensors could be used for the comprehensive assessment of skin hydration.

Keywords

Skin hydration / NIRS / optical sensor / biosensors / wearables / Monte Carlo simulation

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾

Iman Gidado, Raghda Al-Halawani, Meha Qassem, Panicos Kyriacou. Development and Analysis of a Multi-Wavelength Near-Infrared Sensor for Monitoring Skin Hydration and Validation Using Monte Carlo Simulation. Photonic Sensors, 2024, 14(3): 240306 https://doi.org/10.1007/s13320-024-0719-z

References

Publishing order | Descend order by publishing year | Descend order by cited within

[[1]]

Pross

. Effects of dehydration on brain functioning: a life-span perspective. Annals of Nutrition and Metabolism, 2017, 70(Suppl.1): 30-36,

CrossRef Google scholar

[[2]]

Montero-Vilchez

, Segura-Fernández-Nogueras

M V

, Pérez-Rodríguez

, Soler-Gongora

, Martinez-Lopez

, Fernández-González

, et al.. Skin barrier function in psoriasis and atopic dermatitis: transepidermal water loss and temperature as useful tools to assess disease severity. Journal of Clinical Medicine, 2021, 10(2): 359,

CrossRef Google scholar

[[3]]

Maughan

R J

, Shirreffs

S M

. Dehydration and rehydration in competative sport. Scandinavian Journal of Medicine & Science in Sports, 2010, 20(s3): 40-47,

CrossRef Google scholar

[[4]]

Martini

F H

, Nath

J L

. . Fundamentals of Anatomy & Physiology, 2008 8th edition San Francisco Pearson

[[5]]

Jéquier

, Constant

. Water as an essential nutrient: the physiological basis of hydration. European Journal of Clinical Nutrition, 2010, 64(2): 115-123,

CrossRef Google scholar

[[6]]

Princeton Consumer Research, “Skin moisturizer clinical trials ∣ moisturization testing,” online available: https://www.princetonconsumer.com/moisturization-testing/.

[[7]]

Balabin

R M

, Safieva

R Z

, Lomakina

E I

. Comparison of linear and nonlinear calibration models based on near infrared (NIR) spectroscopy data for gasoline properties prediction. Chemometrics and Intelligent Laboratory Systems, 2007, 88(2): 183-188,

CrossRef Google scholar

[[8]]

LSBU, “Water_absorption_spectrum.pdf,” online available: https://www.idc-online.com/technical_references/pdfs/chemical_engineering/Water_absorption_spectrum.pdf.

[[9]]

A. M. C. Davies, “An introduction to near infrared (NIR) spectroscopy ∣ IM Publications Open,” Retrieved March 8, 2024 from https://www.impopen.com/introduction-near-infrared-nirspectroscopy.

[[10]]

M. Qassem and P. A. Kyriacou, “In vitro spectrophotometric near infrared measurements of skin absorption and dehydration,” in 2012 Annual International Conference of the IEEE Engineering in Medicine and Biology Society, San Diego, USA, 2012, pp. 6044–6047.

[[11]]

Zhang

S L

, Meyers

C L

, Subramanyan

, Hancewicz

T M

. Near infrared imaging for measuring and visualizing skin hydration. A comparison with visual assessment and electrical methods. Journal of Biomedical Optics, 2005, 10(3): 031107,

CrossRef Google scholar

[[12]]

Gidado

I M

, Qassem

, Triantis

I F

, Kyriacou

P A

. Review of advances in the measurement of skin hydration based on sensing of optical and electrical tissue properties. Sensors, 2022, 22(19): 7151,

CrossRef Google scholar

[[13]]

M. Qassem. and P. A. Kyriacou, “In vivo optical investigation of short term skin water contact and moisturizer application using NIR spectroscopy,” in Annual International Conference of the IEEE Engineering in Medicine and Biology Society, Osaka, Japan, 2013, pp. 2392–2395.

[[14]]

Kilpatrick-Liverman

, Kazmi

, Wolff

, Polefka

T G

. The use of near-infrared spectroscopy in skin care applications. Skin Research and Technology, 2006, 12(3): 162-169,

CrossRef Google scholar

[[15]]

Kelman

Y T

, Asraf

, Ozana

, Shabairou

, Zalevsky

. Optical tissue probing: human skin hydration detection by speckle patterns analysis. Biomedical Optics Express, 2019, 10(9): 4874,

CrossRef Google scholar

[[16]]

Shen

, Lan

, Zhao

, Xiong

, Yang

, Du

. Characterization of skin moisture and evaluation of cosmetic moisturizing properties using miniature near-infrared spectrometer. Infrared Physics & Technology, 2023, 132: 104759,

CrossRef Google scholar

[[17]]

Budidha

, Rybynok

, Kyriacou

P A

. Design and development of a modular, multichannel photoplethysmography system. IEEE Transactions on Instrumentation and Measurement, 2018, 67(8): 1954-1965,

CrossRef Google scholar

[[18]]

Bashkatov

A N

, Genina

E A

, Tuchin

V V

. Optical properties of skin, subcutaneous, and muscle tissues: a review. Journal of Innovative Optical Health Sciences, 2011, 4(1): 9-38,

CrossRef Google scholar

[[19]]

Zamora-Rojas

, Aernouts

, Garrido-Varo

, Pérez-Marín

, Guerrero-Ginel

J E

, Saeys

. Double integrating sphere measurements for estimating optical properties of pig subcutaneous adipose tissue. Innovative Food Science & Emerging Technologies, 2013, 19: 218-226,

CrossRef Google scholar

[[20]]

Bashkatov

A N

. Optical properties of the subcutaneous adipose tissue in the spectral range 400 to 2 500nm. Optics and Spectroscopy, 2005, 99(5): 836-842,

CrossRef Google scholar

[[21]]

Robertson

C W

, Williams

. Lambert absorption coefficients of water in the infrared. Journal of the Optical Society of America, 1971, 61(10): 1316-1320,

CrossRef Google scholar

[[22]]

Wold

, Sjöström

, Eriksson

. PLS-regression: a basic tool of chemometrics. Chemometrics and Intelligent Laboratory Systems, 2001, 58(2): 109-130,

CrossRef Google scholar

[[23]]

A. Hayes, “Multiple linear regression (MLR) definition, formula, and example,” online available: https://www.investopedia.com/terms/m/mlr.asp.

[[24]]

Arimoto

, Egawa

. Non-contact skin moisture measurement based on near-infrared spectroscopy. Applied Spectroscopy, 2004, 58(12): 1439-1446,

CrossRef Google scholar

[[25]]

Fujita

A K L

, da Rocha

R W

, Escobar

, de Nardi

A B

, Bagnato

V S

, de Menezes

P F C

. Correlation between porcine and human skin models by optical methods. Human Skin Cancers - Pathways, Mechanisms, Targets and Treatments, 2018 London IntechOpen

[[26]]

Mamouei

, Chatterjee

, Razban

, Qassem

, Kyriacou

P A

. Design and analysis of a continuous and non-invasive multi-wavelength optical sensor for measurement of dermal water content. Sensors, 2021, 21(6): 2162,

CrossRef Google scholar

[[27]]

Green

, Kashetsky

, Feschuk

, Maibach

H I

. Transepidermal water loss (TEWL): environment and pollution - a systematic review. Skin Health and Disease, 2022, 2(2): e104,

CrossRef Google scholar

[[28]]

Ionescu

A M

, Chato-Astrain

, Cardona

J D L C

, Campos

, Pérez

M M

, Alaminos

, et al.. Evaluation of the optical and biomechanical properties of bioengineered human skin generated with fibrin-agarose biomaterials. Journal of Biomedical Optics, 2020, 25(5): 1,

CrossRef Google scholar

[[29]]

Ruini

, Kendziora

, Ergun

E Z

, Sattler

, Gust

, French

L E

, et al.. In vivo examination of healthy human skin after short-time treatment with moisturizers using confocal Raman spectroscopy and optical coherence tomography: preliminary observations. Skin Research and Technology, 2022, 28(1): 119-132,

CrossRef Google scholar