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Data for 2020-2025 from SciVal
Selected Publications
2024
1.
Swamy, Suvvi K Narayana; Liu, Chong; Correia, Ricardo; Hayes-Gill, Barrie R; Morgan, Stephen P
Exploring the bias: how skin color influences oxygen saturation readings via Monte Carlo simulations Journal Article
In: J. Biomed. Opt., vol. 29, no. Suppl 3, pp. S33308, 2024.
Abstract | Links | Altmetric | Tags: Melanin, Monte Carlo, Occult hypoxemia, oxygen saturation, pulse oximeter, Racial bias, skin color, transmission mode
@article{Narayana_Swamy2024-la,
title = {Exploring the bias: how skin color influences oxygen saturation readings via Monte Carlo simulations},
author = {Suvvi K Narayana Swamy and Chong Liu and Ricardo Correia and Barrie R Hayes-Gill and Stephen P Morgan},
doi = {10.1117/1.JBO.29.S3.S33308},
year = {2024},
date = {2024-06-01},
urldate = {2024-06-01},
journal = {J. Biomed. Opt.},
volume = {29},
number = {Suppl 3},
pages = {S33308},
publisher = {SPIE-Intl Soc Optical Eng},
abstract = {Significance: Our goal is to understand the root cause of
reported oxygen saturation ( SpO 2 ) overestimation in heavily
pigmented skin types to devise solutions toward enabling equity
in pulse oximeter designs. Aim: We aim to gain theoretical
insights into the effect of skin tone on SpO 2 - R curves using
a three-dimensional, four-layer tissue model representing a
finger. Approach: A finger tissue model, comprising the
epidermis, dermis, two arteries, and a bone, was developed using
a Monte Carlo-based approach in the MCmatlab software. Two skin
tones-light and dark-were simulated by adjusting the absorption
and scattering properties within the epidermal layer. Following
this, SpO 2 - R curves were generated in various tissue
configurations, including transmission and reflection modes
using red and infrared wavelengths. In addition, the influence
of source-detector (SD) separation distances on both light and
dark skin tissue models was studied. Results: In transmission
mode, SpO 2 - R curves did not deviate with changes in skin
tones because both pulsatile and non-pulsatile terms experienced
equal attenuation at red and infrared wavelengths. However, in
reflection mode, measurable variations in SpO 2 - R curves were
evident. This was due to differential attenuation of the red
components, which resulted in a lower perfusion index at the red
wavelength in darker skin. As the SD separation increased, the
effect of skin tone on SpO 2 - R curves in reflection mode
became less pronounced, with the largest SD separation
exhibiting effects similar to those observed in transmission
mode. Conclusions: Monte Carlo simulations have demonstrated
that different light pathlengths within the tissue contribute to
the overestimation of SpO 2 in people with darker skin in
reflection mode pulse oximetry. Increasing the SD separation may
mitigate the effect of skin tone on SpO 2 readings. These trends
were not observed in transmission mode; however, further planned
research using more complex models of the tissue is essential.},
keywords = {Melanin, Monte Carlo, Occult hypoxemia, oxygen saturation, pulse oximeter, Racial bias, skin color, transmission mode},
pubstate = {published},
tppubtype = {article}
}
Significance: Our goal is to understand the root cause of
reported oxygen saturation ( SpO 2 ) overestimation in heavily
pigmented skin types to devise solutions toward enabling equity
in pulse oximeter designs. Aim: We aim to gain theoretical
insights into the effect of skin tone on SpO 2 - R curves using
a three-dimensional, four-layer tissue model representing a
finger. Approach: A finger tissue model, comprising the
epidermis, dermis, two arteries, and a bone, was developed using
a Monte Carlo-based approach in the MCmatlab software. Two skin
tones-light and dark-were simulated by adjusting the absorption
and scattering properties within the epidermal layer. Following
this, SpO 2 - R curves were generated in various tissue
configurations, including transmission and reflection modes
using red and infrared wavelengths. In addition, the influence
of source-detector (SD) separation distances on both light and
dark skin tissue models was studied. Results: In transmission
mode, SpO 2 - R curves did not deviate with changes in skin
tones because both pulsatile and non-pulsatile terms experienced
equal attenuation at red and infrared wavelengths. However, in
reflection mode, measurable variations in SpO 2 - R curves were
evident. This was due to differential attenuation of the red
components, which resulted in a lower perfusion index at the red
wavelength in darker skin. As the SD separation increased, the
effect of skin tone on SpO 2 - R curves in reflection mode
became less pronounced, with the largest SD separation
exhibiting effects similar to those observed in transmission
mode. Conclusions: Monte Carlo simulations have demonstrated
that different light pathlengths within the tissue contribute to
the overestimation of SpO 2 in people with darker skin in
reflection mode pulse oximetry. Increasing the SD separation may
mitigate the effect of skin tone on SpO 2 readings. These trends
were not observed in transmission mode; however, further planned
research using more complex models of the tissue is essential.
reported oxygen saturation ( SpO 2 ) overestimation in heavily
pigmented skin types to devise solutions toward enabling equity
in pulse oximeter designs. Aim: We aim to gain theoretical
insights into the effect of skin tone on SpO 2 - R curves using
a three-dimensional, four-layer tissue model representing a
finger. Approach: A finger tissue model, comprising the
epidermis, dermis, two arteries, and a bone, was developed using
a Monte Carlo-based approach in the MCmatlab software. Two skin
tones-light and dark-were simulated by adjusting the absorption
and scattering properties within the epidermal layer. Following
this, SpO 2 - R curves were generated in various tissue
configurations, including transmission and reflection modes
using red and infrared wavelengths. In addition, the influence
of source-detector (SD) separation distances on both light and
dark skin tissue models was studied. Results: In transmission
mode, SpO 2 - R curves did not deviate with changes in skin
tones because both pulsatile and non-pulsatile terms experienced
equal attenuation at red and infrared wavelengths. However, in
reflection mode, measurable variations in SpO 2 - R curves were
evident. This was due to differential attenuation of the red
components, which resulted in a lower perfusion index at the red
wavelength in darker skin. As the SD separation increased, the
effect of skin tone on SpO 2 - R curves in reflection mode
became less pronounced, with the largest SD separation
exhibiting effects similar to those observed in transmission
mode. Conclusions: Monte Carlo simulations have demonstrated
that different light pathlengths within the tissue contribute to
the overestimation of SpO 2 in people with darker skin in
reflection mode pulse oximetry. Increasing the SD separation may
mitigate the effect of skin tone on SpO 2 readings. These trends
were not observed in transmission mode; however, further planned
research using more complex models of the tissue is essential.
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