Laser light scattering in turbid media Part I: Experimental and simulated results for the spatial intensity distribution

Berrocal, Edouard; Sedarsky, David; Paciaroni, Megan; Meglinski, Igor; Linne, Mark

doi:10.1364/oe.15.010649

Cited by 130 publications

(89 citation statements)

References 11 publications

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“…With D=5 µm particles at OD=10, the FWHM predicted by the old and the new models differs by ∼5% (3.43 mm versus 3.27 mm). The experimentally measured FWHM was 3.19 mm in this case [6] . Therefore, both the old and the new models over-predicted the FWHM, by ∼7.5% and ∼2.5% relative to the experimental measurements, respectively.…”

mentioning

confidence: 56%

“…On the other hand, the limitations of the MC method are also well recognized, and the development of new MC methods continues to be an active area of research. For example, considerable progress has been made in the experimental validation of MC methods [6,7] and in the improvement of their efficiency [9,10] . Meanwhile, new MC methods have been developed to track the polarization during multiple scattering [11,12] and to capture the propagation of an ultra-short laser pulse in optically dense media [13] .…”

mentioning

confidence: 99%

“…(2)-(6) have been discussed previously [15,16] , but they are also often neglected [1,6,7] . Therefore, one goal of this study is to quantitatively examine such effects.…”

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confidence: 99%

“…We first briefly summarized the experiments performed in Refs. [6,18] to facilitate the discussion in this study.…”

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confidence: 99%

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Improved Monte Carlo model for multiple scattering calculations

Cai¹,

Ma²

2012

中国光学快报

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confidence: 56%

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confidence: 99%

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Improved Monte Carlo model for multiple scattering calculations

Cai¹,

Ma²

2012

中国光学快报

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show abstract

“…However, multiple-scattering problems usually are complicated and have to be solved numerically, which is computationally costly and often does not provide intuitive understanding of the problem. As an example, Monte Carlo simulation [3][4][5][6], which is an extensively used numerical technique, can be prohibitively expensive when probing large optical depth. Considerable efforts have been investigated to overcome this limitation, and one notable technique demonstrated recently [7] involves the use of GPU (Graphical Processing Units) to parallelize and accelerate Monte Carlo simulations.…”

Section: Introductionmentioning

confidence: 99%

Scaling Law for Photon Transmission through Optically Turbid Slabs Based on Random Walk Theory

2012

Applied Sciences

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Past work has demonstrated the value of a random walk theory (RWT) to solve multiple-scattering problems arising in numerous contexts. This paper's goal is to investigate the application range of the RWT using Monte Carlo simulations and extending it to anisotropic media using scaling laws. Meanwhile, this paper also reiterates rules for converting RWT formulas to real physical dimensions, and corrects some errors which appear in an earlier publication. The RWT theory, validated by the Monte Carlo simulations and combined with the scaling law, is expected to be useful to study multiple scattering and to greatly reduce the computation cost.

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Development of a microstructured tissue phantom with adaptable optical properties for use with microscopes and fluorescence lifetime imaging systems

et al. 2022

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Objectives: For the development and validation of diagnostic procedures based on microscopic methods, knowledge about the imaging depth and achievable resolution in tissue is crucial. This poses the challenge to develop a microscopic artificial phantom focused on the microscopic instead of the macroscopic optical tissue characteristics. Methods: As existing artificial tissue phantoms designed for image forming systems are primarily targeted at wide field applications, they are unsuited for reaching the formulated objective. Therefore, a microscopy-and microendoscopy-suited artificial tissue phantom was developed and characterized. It is based on a microstructured glass surface coated with fluorescent beads at known depths covered by a scattering agent with modifiable optical properties. The phantom was examined with different kinds of microscopy systems in order to characterize its quality and stability and to demonstrate its usefulness for instrument comparison, for example, regarding structural as well as fluorescence lifetime analysis. Results: The analysis of the manufactured microstructured glass surfaces showed high regularity in their physical dimensions in accordance with the specifications. Measurements of the optical parameters of the scattering medium were consistent with simulations. The fluorescent beads coating proved to be stable for a respectable period of time (about a week). The developed artificial tissue phantom was successfully used to detect differences in image quality between a research microscope and an endoscopy based system. Plausible causes for the observed differences could be derived based on the well known microstructure of the phantom. Conclusions: The artificial tissue phantom is well suited for the intended use with microscopic and microendoscopic systems. Due to its configurable design, it can be adapted to a wide range of applications. It is especially targeted at the characterization and calibration of clinical imaging systems that often lack extensive positioning capabilities such as an intrinsic z-stage.

show abstract

Laser light scattering in turbid media Part I: Experimental and simulated results for the spatial intensity distribution

Cited by 130 publications

References 11 publications

Improved Monte Carlo model for multiple scattering calculations

Improved Monte Carlo model for multiple scattering calculations

Scaling Law for Photon Transmission through Optically Turbid Slabs Based on Random Walk Theory

Development of a microstructured tissue phantom with adaptable optical properties for use with microscopes and fluorescence lifetime imaging systems

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