Optimal beam size for light delivery to absorption-enhanced tumors buried in biological tissues and effect of multiple-beam delivery: a Monte Carlo study

Wang, Lihong V.; Nordquist, Robert E.; Chen, Wei R.

doi:10.1364/ao.36.008286

Cited by 52 publications

(33 citation statements)

References 13 publications

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“…Compared to the recent developed analytical approximation method, 5 Monte Carlo method is more°e xible and reliable, especially for nonin¯nite medium. There are several widely used Monte Carlo simulation techniques o®ered in our¯eld, such as the one for layered tissue model (MCML), 6 the one for medical image depicted tissue model (tMCimg), 7 the one for mathematical geometry depicted tissue model (MCLS), 8 and the one for 3D voxelized media (MCVM). 9 Although these methods have been accepted in biomedical¯eld in accurate light propagation computation, the MCML and MCLS are only applicable layered tissue model or the model depicted with cube, sphere, or cylinder.…”

Section: Introductionmentioning

confidence: 99%

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Photon penetration depth in human brain for light stimulation and treatment: A realistic Monte Carlo simulation study

Xue²,

Wang³

et al. 2017

J. Innov. Opt. Health Sci.

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Light has been clinically utilized as a stimulation in medical treatment, such as Low-level laser therapy and photodynamic therapy, which has been more and more widely accepted in public. The penetration depth of the treatment light is important for precision treatment and safety control. The issue of light penetration has been highlighted in biomedical optics¯eld for decades. However, quantitative research is sparse and even there are con°icts of view on the capability of near-infrared light penetration into brain tissue. This study attempts to quantitatively revisit this issue by innovative high-realistic 3D Monte Carlo modeling of stimulated light penetration within high-precision Visible Chinese human head. The properties of light, such as its wavelength, illumination pro¯le and size are concern in this study. We made straightforward and quantitative comparisons among the e®ects by the light properties (i.e., wavelengths: 660, 810 and 980 nm; beam types: Gaussian and°at beam; beam diameters: 0, 2, 4 and 6 cm) which are in the range of light treatment. The¯ndings include about 3% of light dosage within brain tissue; the combination of Gaussian beam and 810 nm light make the maximum light penetration §

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Section: Introductionmentioning

confidence: 99%

“…8,10,11,15 There was only one Monte Carlo study on light penetration depth on realistic head model, 13 which uses a MRI head model in which precision is not high enough. A more realistic and precised head model was recommended to model light propagation.…”

Section: Introductionmentioning

confidence: 99%

Photon penetration depth in human brain for light stimulation and treatment: A realistic Monte Carlo simulation study

Xue²,

Wang³

et al. 2017

J. Innov. Opt. Health Sci.

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“…Second, the laser power is finite such that the beam diameter cannot be too large, because the sources at the rim will not couple well to the target location. Therefore, there exists an optimal beam diameter that can efficiently deliver light to the target location 12 . Figure 2.…”

Section: Optimal Beam Size Of the Incident Lightmentioning

confidence: 99%

Optical focusing through biological tissue and tissue-mimicking phantoms up to 9.6 centimeters thick with digital optical phase conjugation

Shen

Liu

et al. 2017

SPIE Proceedings

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Optical phase conjugation (OPC) based wavefront shaping techniques focus light through or within scattering media, which is critically important for deep-tissue optical imaging, manipulation, and therapy. However, to date, the sample thicknesses used in wavefront shaping experiments have been limited to only a few millimeters or several transport mean free paths. Here, by using a long-coherence-length laser and an optimized digital OPC system that efficiently delivers light power, we focused 532 nm light through tissue-mimicking phantoms up to 9.6 cm thick, as well as through ex vivo chicken breast tissue up to 2.5 cm thick.

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“…However, a large dark-field area may reduce the optical fluence reaching the targeted area. The optimal illumination radius was estimated to be 7 mm using the concept of effective attenuation coefficient, 13 the exponential decay rate of fluence far from the source, with typical tissue parameters. Consequently, leaving a ϳ1-mm width right below the array elements as the dark field gives approximately the best performance.…”

Section: Optics and Light Deliverymentioning

confidence: 99%

Fast 3-D dark-field reflection-mode photoacoustic microscopy in vivo with a 30-MHz ultrasound linear array

et al. 2008

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Abstract. We present an in vivo dark-field reflection-mode photoacoustic microscopy system that performs cross-sectional ͑B-scan͒ imaging at 50 Hz with real-time beamforming and 3-D imaging consisting of 166 B-scan frames at 1 Hz with postbeamforming. To our knowledge, this speed is currently the fastest in photoacoustic imaging. A custom-designed light delivery system is integrated with a 30-MHz ultrasound linear array to realize dark-field reflection-mode imaging. Linear mechanical scanning of the array produces 3-D images. The system has axial, lateral, and elevational resolutions of 25, 70, and 200 m, respectively, and can image 3 mm deep in scattering biological tissues. Volumetric images of subcutaneous vasculature in rats are demonstrated in vivo. Fast 3-D photoacoustic microscopy is anticipated to facilitate applications of photoacoustic imaging in biomedical studies that involve dynamics and clinical procedures that demand immediate diagnosis.

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Optimal beam size for light delivery to absorption-enhanced tumors buried in biological tissues and effect of multiple-beam delivery: a Monte Carlo study

Cited by 52 publications

References 13 publications

Photon penetration depth in human brain for light stimulation and treatment: A realistic Monte Carlo simulation study

Photon penetration depth in human brain for light stimulation and treatment: A realistic Monte Carlo simulation study

Optical focusing through biological tissue and tissue-mimicking phantoms up to 9.6 centimeters thick with digital optical phase conjugation

Fast 3-D dark-field reflection-mode photoacoustic microscopy in vivo with a 30-MHz ultrasound linear array

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