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Shortwave infrared diffuse optical wearable probe for quantification of water and lipid content in emulsion phantoms using deep learning

SIGNIFICANCE: The shortwave infrared (SWIR, [Formula: see text] to 2000 nm) holds promise for label-free measurements of water and lipid content in thick tissue, owed to the chromophore-specific absorption features and low scattering in this range. In vivo water and lipid estimations have potential...

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Autores principales: Spink, Samuel S., Pilvar, Anahita, Wei, Lina Lin, Frias, Jodee, Anders, Kylee, Franco, Sabrina T., Rose, Olivia Claire, Freeman, Megan, Bag, Grace, Huang, Huiru, Roblyer, Darren
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Society of Photo-Optical Instrumentation Engineers 2023
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10258729/
https://www.ncbi.nlm.nih.gov/pubmed/37313427
http://dx.doi.org/10.1117/1.JBO.28.9.094808
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author Spink, Samuel S.
Pilvar, Anahita
Wei, Lina Lin
Frias, Jodee
Anders, Kylee
Franco, Sabrina T.
Rose, Olivia Claire
Freeman, Megan
Bag, Grace
Huang, Huiru
Roblyer, Darren
author_facet Spink, Samuel S.
Pilvar, Anahita
Wei, Lina Lin
Frias, Jodee
Anders, Kylee
Franco, Sabrina T.
Rose, Olivia Claire
Freeman, Megan
Bag, Grace
Huang, Huiru
Roblyer, Darren
author_sort Spink, Samuel S.
collection PubMed
description SIGNIFICANCE: The shortwave infrared (SWIR, [Formula: see text] to 2000 nm) holds promise for label-free measurements of water and lipid content in thick tissue, owed to the chromophore-specific absorption features and low scattering in this range. In vivo water and lipid estimations have potential applications including the monitoring of hydration, volume status, edema, body composition, weight loss, and cancer. To the best of our knowledge, there are currently no point-of-care or wearable devices available that exploit the SWIR wavelength range, limiting clinical and at-home translation of this technology. AIM: To design and fabricate a diffuse optical wearable SWIR probe for water and lipid quantification in tissue. APPROACH: Simulations were first performed to confirm the theoretical advantage of SWIR wavelengths over near infrared (NIR). The probe was then fabricated, consisting of light emitting diodes at three wavelengths (980, 1200, 1300 nm) and four source-detector (S-D) separations (7, 10, 13, 16 mm). In vitro validation was then performed on emulsion phantoms containing varying concentrations of water, lipid, and deuterium oxide ([Formula: see text]). A deep neural network was developed as the inverse model for quantity estimation. RESULTS: Simulations indicated that SWIR wavelengths could reduce theoretical water and lipid extraction errors from [Formula: see text] to [Formula: see text] when compared to NIR wavelengths. The SWIR probe had good signal-to-noise ratio ([Formula: see text] up to 10 mm S-D) and low drift ([Formula: see text] up to 10 mm S-D). Quantification error in emulsion phantoms was [Formula: see text] for water and [Formula: see text] for lipid. Water estimation during a [Formula: see text] dilution experiment had an error of [Formula: see text]. CONCLUSIONS: This diffuse optical SWIR probe was able to quantify water and lipid contents in vitro with good accuracy, opening the door to human investigations.
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spelling pubmed-102587292023-06-13 Shortwave infrared diffuse optical wearable probe for quantification of water and lipid content in emulsion phantoms using deep learning Spink, Samuel S. Pilvar, Anahita Wei, Lina Lin Frias, Jodee Anders, Kylee Franco, Sabrina T. Rose, Olivia Claire Freeman, Megan Bag, Grace Huang, Huiru Roblyer, Darren J Biomed Opt Special Section on Short Wave Infrared Techniques and Applications in Biomedical Optics SIGNIFICANCE: The shortwave infrared (SWIR, [Formula: see text] to 2000 nm) holds promise for label-free measurements of water and lipid content in thick tissue, owed to the chromophore-specific absorption features and low scattering in this range. In vivo water and lipid estimations have potential applications including the monitoring of hydration, volume status, edema, body composition, weight loss, and cancer. To the best of our knowledge, there are currently no point-of-care or wearable devices available that exploit the SWIR wavelength range, limiting clinical and at-home translation of this technology. AIM: To design and fabricate a diffuse optical wearable SWIR probe for water and lipid quantification in tissue. APPROACH: Simulations were first performed to confirm the theoretical advantage of SWIR wavelengths over near infrared (NIR). The probe was then fabricated, consisting of light emitting diodes at three wavelengths (980, 1200, 1300 nm) and four source-detector (S-D) separations (7, 10, 13, 16 mm). In vitro validation was then performed on emulsion phantoms containing varying concentrations of water, lipid, and deuterium oxide ([Formula: see text]). A deep neural network was developed as the inverse model for quantity estimation. RESULTS: Simulations indicated that SWIR wavelengths could reduce theoretical water and lipid extraction errors from [Formula: see text] to [Formula: see text] when compared to NIR wavelengths. The SWIR probe had good signal-to-noise ratio ([Formula: see text] up to 10 mm S-D) and low drift ([Formula: see text] up to 10 mm S-D). Quantification error in emulsion phantoms was [Formula: see text] for water and [Formula: see text] for lipid. Water estimation during a [Formula: see text] dilution experiment had an error of [Formula: see text]. CONCLUSIONS: This diffuse optical SWIR probe was able to quantify water and lipid contents in vitro with good accuracy, opening the door to human investigations. Society of Photo-Optical Instrumentation Engineers 2023-06-12 2023-09 /pmc/articles/PMC10258729/ /pubmed/37313427 http://dx.doi.org/10.1117/1.JBO.28.9.094808 Text en © 2023 The Authors https://creativecommons.org/licenses/by/4.0/Published by SPIE under a Creative Commons Attribution 4.0 International License. Distribution or reproduction of this work in whole or in part requires full attribution of the original publication, including its DOI.
spellingShingle Special Section on Short Wave Infrared Techniques and Applications in Biomedical Optics
Spink, Samuel S.
Pilvar, Anahita
Wei, Lina Lin
Frias, Jodee
Anders, Kylee
Franco, Sabrina T.
Rose, Olivia Claire
Freeman, Megan
Bag, Grace
Huang, Huiru
Roblyer, Darren
Shortwave infrared diffuse optical wearable probe for quantification of water and lipid content in emulsion phantoms using deep learning
title Shortwave infrared diffuse optical wearable probe for quantification of water and lipid content in emulsion phantoms using deep learning
title_full Shortwave infrared diffuse optical wearable probe for quantification of water and lipid content in emulsion phantoms using deep learning
title_fullStr Shortwave infrared diffuse optical wearable probe for quantification of water and lipid content in emulsion phantoms using deep learning
title_full_unstemmed Shortwave infrared diffuse optical wearable probe for quantification of water and lipid content in emulsion phantoms using deep learning
title_short Shortwave infrared diffuse optical wearable probe for quantification of water and lipid content in emulsion phantoms using deep learning
title_sort shortwave infrared diffuse optical wearable probe for quantification of water and lipid content in emulsion phantoms using deep learning
topic Special Section on Short Wave Infrared Techniques and Applications in Biomedical Optics
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10258729/
https://www.ncbi.nlm.nih.gov/pubmed/37313427
http://dx.doi.org/10.1117/1.JBO.28.9.094808
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