Subdiffuse scattering and absorption model for single fiber reflectance spectroscopy

Anouk L. Post; Dirk J. Faber; Henricus J. C. M. Sterenborg; Ton G. Van Leeuwen

doi:https://doi.org/10.1364/BOE.402466

Subdiffuse scattering and absorption model for single fiber reflectance spectroscopy

Anouk L. Post, Dirk J. Faber, Henricus J. C. M. Sterenborg, Ton G. Van Leeuwen

Research output: Contribution to journal › Article › Academic › peer-review

9 Citations (Scopus)

Abstract

Single fiber reflectance (SFR) spectroscopy is a technique that is sensitive to smallscale changes in tissue. An additional benefit is that SFR measurements can be performed through endoscopes or biopsy needles. In SFR spectroscopy, a single fiber emits and collects light. Tissue optical properties can be extracted from SFR spectra and related to the disease state of tissue. However, the model currently used to extract optical properties was derived for tissues with modified Henyey-Greenstein phase functions only and is inadequate for other tissue phase functions. Here, we will present a model for SFR spectroscopy that provides accurate results for a large range of tissue phase functions, reduced scattering coefficients, and absorption coefficients. Our model predicts the reflectance with a median error of 5.6% compared to 19.3% for the currently used model. For two simulated tissue spectra, our model fit provides accurate results.

Original language	English
Pages (from-to)	6620-6633
Number of pages	14
Journal	Biomedical Optics Express
Volume	11
Issue number	11
DOIs	https://doi.org/10.1364/BOE.402466
Publication status	Published - 1 Nov 2020

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title = "Subdiffuse scattering and absorption model for single fiber reflectance spectroscopy",

abstract = "Single fiber reflectance (SFR) spectroscopy is a technique that is sensitive to smallscale changes in tissue. An additional benefit is that SFR measurements can be performed through endoscopes or biopsy needles. In SFR spectroscopy, a single fiber emits and collects light. Tissue optical properties can be extracted from SFR spectra and related to the disease state of tissue. However, the model currently used to extract optical properties was derived for tissues with modified Henyey-Greenstein phase functions only and is inadequate for other tissue phase functions. Here, we will present a model for SFR spectroscopy that provides accurate results for a large range of tissue phase functions, reduced scattering coefficients, and absorption coefficients. Our model predicts the reflectance with a median error of 5.6% compared to 19.3% for the currently used model. For two simulated tissue spectra, our model fit provides accurate results.",

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AU - Post, Anouk L.

AU - Faber, Dirk J.

AU - Sterenborg, Henricus J. C. M.

AU - Van Leeuwen, Ton G.

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N2 - Single fiber reflectance (SFR) spectroscopy is a technique that is sensitive to smallscale changes in tissue. An additional benefit is that SFR measurements can be performed through endoscopes or biopsy needles. In SFR spectroscopy, a single fiber emits and collects light. Tissue optical properties can be extracted from SFR spectra and related to the disease state of tissue. However, the model currently used to extract optical properties was derived for tissues with modified Henyey-Greenstein phase functions only and is inadequate for other tissue phase functions. Here, we will present a model for SFR spectroscopy that provides accurate results for a large range of tissue phase functions, reduced scattering coefficients, and absorption coefficients. Our model predicts the reflectance with a median error of 5.6% compared to 19.3% for the currently used model. For two simulated tissue spectra, our model fit provides accurate results.

AB - Single fiber reflectance (SFR) spectroscopy is a technique that is sensitive to smallscale changes in tissue. An additional benefit is that SFR measurements can be performed through endoscopes or biopsy needles. In SFR spectroscopy, a single fiber emits and collects light. Tissue optical properties can be extracted from SFR spectra and related to the disease state of tissue. However, the model currently used to extract optical properties was derived for tissues with modified Henyey-Greenstein phase functions only and is inadequate for other tissue phase functions. Here, we will present a model for SFR spectroscopy that provides accurate results for a large range of tissue phase functions, reduced scattering coefficients, and absorption coefficients. Our model predicts the reflectance with a median error of 5.6% compared to 19.3% for the currently used model. For two simulated tissue spectra, our model fit provides accurate results.

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Subdiffuse scattering and absorption model for single fiber reflectance spectroscopy

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