Enhancement of photoacoustic signal using a novel light illumination improvement device: In vivo feasibility animal study

Yu, Jaesok; Jung, Young-Soo; Kang, Jeeun; Lee, Sang Goo; Chang, Jin Ho; Lee, Jung‐Kun; Kim, Kang

doi:10.1109/ultsym.2014.0086

Cited by 2 publications

(1 citation statement)

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“…Some efforts have been made to avoid the impact of nonuniform and nonstationary illumination on imaging quality by optimizing the illumination pattern or improving the illumination devices, such as rotating partial illumination (Lou et al 2015(Lou et al , 2016, customized fiber-optic illumination (Mc Larney et al 2019), light catcher (Yu et al 2014(Yu et al , 2017, and internal illumination (Lin et al 2015, Li et al 2018.…”

Section: Optimizing Illumination Patternsmentioning

confidence: 99%

Quantitative photoacoustic tomography with light fluence compensation based on radiance Monte Carlo model

et al. 2023

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Objective: Photoacoustic tomography (PAT) is a rapidly evolving imaging modality that provides images with high contrast and spatial resolution showing the optical properties of biological tissues. The photoacoustic pressure is proportional to the product of the optical absorption coefficient and the local light fluence. The essential challenge in reconstructing quantitative images representing spatially varying absorption coefficients is the unknown light fluence. In addition, optical attenuation induces spatial variations in the light fluence, and the heterogeneity of the fluence determines the limits of reconstruction quality and depth. Approach: In this work, a reconstruction enhancement scheme is proposed to compensate for the variation of the light fluence in the absorption coefficient recovery. The inverse problem of the radiance Monte Carlo model describing light transport through the tissue is solved by using an alternating optimization strategy. In the iteration, the absorption coefficients and photon weights are alternately updated. Main results: The method provides highly accurate quantitative images of absorption coefficients in simulations, phantoms, and in vivo studies. The results show that the method has great potential for improving the accuracy of absorption coefficient recovery compared to conventional reconstruction methods that ignore light fluence variations. Comparison with state-of-the-art fluence compensation methods shows significant improvements in root mean square error, normalized mean square absolute distance, and structural similarity metrics. Significance: This method achieves high precision quantitative imaging by compensating for non-uniform light fluence without increasing the complexity and operation of the imaging system.

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