Exploring the bias: how skin color influences oxygen saturation readings via Monte Carlo simulations.

IF 3 3区医学 Q2 BIOCHEMICAL RESEARCH METHODS Journal of Biomedical Optics Pub Date : 2024-06-01 Epub Date: 2024-08-29 DOI:10.1117/1.JBO.29.S3.S33308

Suvvi K Narayana Swamy, Chong Liu, Ricardo Correia, Barrie R Hayes-Gill, Stephen P Morgan

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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.

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探索偏差：肤色如何通过蒙特卡罗模拟影响血氧饱和度读数。

意义：我们的目标是了解报告的血氧饱和度（SpO 2）在色素沉着严重的皮肤类型中被高估的根本原因，从而制定解决方案，实现脉搏血氧仪设计的公平性。目的：我们的目标是利用代表手指的三维四层组织模型，从理论上深入了解肤色对 SpO 2 - R 曲线的影响：方法：使用 MCmatlab 软件中基于蒙特卡洛的方法开发了一个手指组织模型，包括表皮、真皮、两根动脉和一根骨头。通过调整表皮层的吸收和散射特性，模拟出浅色和深色两种肤色。随后，在各种组织配置下生成 SpO 2 - R 曲线，包括使用红色和红外线波长的透射和反射模式。此外，还研究了光源-探测器（SD）分离距离对浅色和深色皮肤组织模型的影响：在透射模式下，SpO 2 - R 曲线不会随着肤色的变化而偏离，因为脉动和非脉动项在红色和红外线波长下的衰减相同。然而，在反射模式下，SpO 2 - R 曲线出现了明显的可测量变化。这是由于红色成分的衰减不同，导致深色皮肤在红色波长下的灌注指数较低。随着标清分离度的增加，肤色对反射模式下 SpO 2 - R 曲线的影响变得不那么明显，标清分离度最大时的影响与透射模式下观察到的影响相似：蒙特卡罗模拟表明，在反射模式脉搏血氧仪中，组织内不同的光路长度会导致肤色较深的人高估 SpO 2。增加标距间隔可减轻肤色对 SpO 2 读数的影响。在透射模式中没有观察到这些趋势；不过，使用更复杂的组织模型进行进一步的计划研究是非常必要的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Biomedical Optics 医学-光学

CiteScore

6.40

自引率

5.70%

发文量

263

审稿时长

2 months

期刊介绍： The Journal of Biomedical Optics publishes peer-reviewed papers on the use of modern optical technology for improved health care and biomedical research.