Evaluation of layered tissue scattering properties: a time-domain spatially resolved spectroscopy approach.

IF 3 3区医学 Q2 BIOCHEMICAL RESEARCH METHODS

Journal of Biomedical Optics Pub Date : 2025-07-01 Epub Date: 2025-07-21 DOI:10.1117/1.JBO.30.7.075002

Elisabetta Avanzi, Laura Di Sieno, Alberto Dalla Mora, Lorenzo Spinelli, Alessandro Torricelli

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引用次数: 0

Abstract

Significance: The spatially resolved spectroscopy (SRS) approach is widely used in continuous wave near-infrared spectroscopy to estimate tissue oxygen saturation in the skeletal muscle and cerebral cortex. The extension of the SRS approach to the time domain (TD) has never been proposed. We hypothesize that the time-domain spatially resolved spectroscopy (TD SRS) approach, relying on simple models and linear fit, avoiding nonlinear model-based analysis approaches, could be able to assess the homogeneity of the scattering of the explored tissue.

Aim: We aim to explore the potential of the TD SRS approach for estimating $μ_{s}^{'}$ from the spatial derivative of the measured signal in a homogeneous and in a two-layer medium and by considering also the effect of the instrument response function (IRF).

Approach: A theoretical expression for $μ_{s}^{'}$ depending on the spatial derivative of the attenuation is derived. Then, numerical simulations are conducted using solutions of the radiative transfer equation under the diffusion approximation. We consider a reflectance geometry with source-detector distance in the range 1 to 5 cm in 0.5 cm step, either in a homogenous semi-infinite or two-layer diffusive medium. Convolution with a real IRF is also carried out to mimic experimental scenarios.

Results: In a homogeneous medium, the TD SRS approach is able to retrieve $μ_{s}^{'}$ over a large range of values, being minimally affected by the IRF. In a two-layer medium, the TD SRS approach can only provide information on the changes of $μ_{s}^{'}$ with depth but fails to provide a robust estimate of the absolute value of $μ_{s}^{'}$ in either of the two layers. Moreover, the IRF can greatly affect the results in the case of the two-layer medium.

Conclusions: The TD SRS approach can be a simple way to estimate spatial changes of $μ_{s}^{'}$ but not the absolute value of $μ_{s}^{'}$ . Care should be taken to use a TD system with proper IRF.

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层状组织散射特性的评估：一种时域空间分辨光谱方法。

意义：空间分辨光谱（SRS）方法在连续波近红外光谱中广泛应用于骨骼肌和大脑皮层组织氧饱和度的估计。将SRS方法扩展到时域（TD）从未被提出过。我们假设时域空间分辨光谱（TD SRS）方法依赖于简单的模型和线性拟合，避免了基于非线性模型的分析方法，能够评估被探测组织散射的均匀性。目的：通过考虑仪器响应函数（IRF）的影响，探索TD SRS方法在均匀介质和双层介质中从测量信号的空间导数中估计μ s '的潜力。方法：导出了μ s '随衰减的空间导数的理论表达式。然后，利用扩散近似下的辐射传递方程解进行数值模拟。我们考虑在均匀半无限介质或两层扩散介质中，源-探测器距离在0.5 cm步长范围内为1至5 cm的反射几何。与真实IRF的卷积也进行了模拟实验场景。结果：在均匀介质中，TD SRS方法能够在大范围内检索μ s值，并且受IRF的影响最小。在两层介质中，TD SRS方法只能提供μ s ‘随深度变化的信息，但不能提供两层中μ s ’绝对值的鲁棒估计。此外，在两层介质的情况下，IRF对结果有很大的影响。结论：TD SRS方法可以简单地估计μ s ‘的空间变化，但不能估计μ s ’的绝对值。应注意使用具有适当IRF的TD系统。

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.