Modeling toolchain for realistic simulation of photoacoustic data acquisition

Jan-Willem Muller; M.Ü. Arabul; Hans-Martin Schwab; Marcel C.M. Rutten; Marc R.H.M. van Sambeek; Min Wu; Richard G.P. Lopata

doi:10.1117/1.JBO.27.9.096005

Modeling toolchain for realistic simulation of photoacoustic data acquisition

Jan-Willem Muller (Corresponding author), M.Ü. Arabul, Hans-Martin Schwab, Marcel C.M. Rutten, Marc R.H.M. van Sambeek, Min Wu, Richard G.P. Lopata

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

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Abstract

Significance: Physics-based simulations of photoacoustic (PA) signals are used to validate new methods, to characterize PA setups and to generate training datasets for machine learning. However, a thoroughly validated PA simulation toolchain that can simulate realistic images is still lacking.

Aim: A quantitative toolchain was developed to model PA image acquisition in complex tissues, by simulating both the optical fluence and the acoustic wave propagation.

Approach: Sampling techniques were developed to decrease artifacts in acoustic simulations. The performance of the simulations was analyzed by measuring the point spread function (PSF) and using a rotatable three-channel phantom, filled with cholesterol, a human carotid plaque sample, and porcine blood. Ex vivo human plaque samples were simulated to validate the methods in more complex tissues.

Results: The sampling techniques could enhance the quality of the simulated PA images effectively. The resolution and intensity of the PSF in the turbid medium matched the experimental data well. Overall, the appearance, signal-to-noise ratio and speckle of the images could be simulated accurately.

Conclusions: A PA toolchain was developed and validated, and the results indicate a great potential of PA simulations in more complex and heterogeneous media.

Original language	English
Article number	096005
Number of pages	17
Journal	Journal of Biomedical Optics
Volume	27
Issue number	9
DOIs	https://doi.org/10.1117/1.JBO.27.9.096005
Publication status	Published - 14 Sept 2022

Keywords

Monte–Carlo
k-wave
modeling
photoacoustic imaging
toolchain

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title = "Modeling toolchain for realistic simulation of photoacoustic data acquisition",

abstract = "Significance: Physics-based simulations of photoacoustic (PA) signals are used to validate new methods, to characterize PA setups and to generate training datasets for machine learning. However, a thoroughly validated PA simulation toolchain that can simulate realistic images is still lacking.Aim: A quantitative toolchain was developed to model PA image acquisition in complex tissues, by simulating both the optical fluence and the acoustic wave propagation.Approach: Sampling techniques were developed to decrease artifacts in acoustic simulations. The performance of the simulations was analyzed by measuring the point spread function (PSF) and using a rotatable three-channel phantom, filled with cholesterol, a human carotid plaque sample, and porcine blood. Ex vivo human plaque samples were simulated to validate the methods in more complex tissues.Results: The sampling techniques could enhance the quality of the simulated PA images effectively. The resolution and intensity of the PSF in the turbid medium matched the experimental data well. Overall, the appearance, signal-to-noise ratio and speckle of the images could be simulated accurately.Conclusions: A PA toolchain was developed and validated, and the results indicate a great potential of PA simulations in more complex and heterogeneous media.",

keywords = "Monte–Carlo, k-wave, modeling, photoacoustic imaging, toolchain",

author = "Jan-Willem Muller and M.{\"U}. Arabul and Hans-Martin Schwab and Rutten, \{Marcel C.M.\} and \{van Sambeek\}, \{Marc R.H.M.\} and Min Wu and Lopata, \{Richard G.P.\}",

year = "2022",

month = sep,

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doi = "10.1117/1.JBO.27.9.096005",

language = "English",

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AU - Muller, Jan-Willem

AU - Arabul, M.Ü.

AU - Schwab, Hans-Martin

AU - Rutten, Marcel C.M.

AU - van Sambeek, Marc R.H.M.

AU - Wu, Min

AU - Lopata, Richard G.P.

PY - 2022/9/14

Y1 - 2022/9/14

N2 - Significance: Physics-based simulations of photoacoustic (PA) signals are used to validate new methods, to characterize PA setups and to generate training datasets for machine learning. However, a thoroughly validated PA simulation toolchain that can simulate realistic images is still lacking.Aim: A quantitative toolchain was developed to model PA image acquisition in complex tissues, by simulating both the optical fluence and the acoustic wave propagation.Approach: Sampling techniques were developed to decrease artifacts in acoustic simulations. The performance of the simulations was analyzed by measuring the point spread function (PSF) and using a rotatable three-channel phantom, filled with cholesterol, a human carotid plaque sample, and porcine blood. Ex vivo human plaque samples were simulated to validate the methods in more complex tissues.Results: The sampling techniques could enhance the quality of the simulated PA images effectively. The resolution and intensity of the PSF in the turbid medium matched the experimental data well. Overall, the appearance, signal-to-noise ratio and speckle of the images could be simulated accurately.Conclusions: A PA toolchain was developed and validated, and the results indicate a great potential of PA simulations in more complex and heterogeneous media.

AB - Significance: Physics-based simulations of photoacoustic (PA) signals are used to validate new methods, to characterize PA setups and to generate training datasets for machine learning. However, a thoroughly validated PA simulation toolchain that can simulate realistic images is still lacking.Aim: A quantitative toolchain was developed to model PA image acquisition in complex tissues, by simulating both the optical fluence and the acoustic wave propagation.Approach: Sampling techniques were developed to decrease artifacts in acoustic simulations. The performance of the simulations was analyzed by measuring the point spread function (PSF) and using a rotatable three-channel phantom, filled with cholesterol, a human carotid plaque sample, and porcine blood. Ex vivo human plaque samples were simulated to validate the methods in more complex tissues.Results: The sampling techniques could enhance the quality of the simulated PA images effectively. The resolution and intensity of the PSF in the turbid medium matched the experimental data well. Overall, the appearance, signal-to-noise ratio and speckle of the images could be simulated accurately.Conclusions: A PA toolchain was developed and validated, and the results indicate a great potential of PA simulations in more complex and heterogeneous media.

KW - Monte–Carlo

KW - k-wave

KW - modeling

KW - photoacoustic imaging

KW - toolchain

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Modeling toolchain for realistic simulation of photoacoustic data acquisition

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Cardiovascular Medicine

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Modeling toolchain for realistic simulation of photoacoustic data acquisition

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Research areas

Cardiovascular Medicine

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