Brief review on learning-based methods for optical tomography

Zhang, Lin; Zhang, Guanglei

doi:10.1142/s1793545819300118

Cited by 23 publications

(11 citation statements)

References 63 publications

(67 reference statements)

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“…The DOT image reconstruction is an ill-posed problem that has been tackled using a wide variety of reconstruction methods (see [7], [8] for a review).…”

Section: B Current Dot Image Reconstruction Approachesmentioning

confidence: 99%

Multitask Deep Learning Reconstruction and Localization of Lesions in Limited Angle Diffuse Optical Tomography

Yedder

Cardoen

Shokoufi

et al. 2022

IEEE Trans. Med. Imaging

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Diffuse optical tomography (DOT) leverages near-infrared light propagation through tissue to assess its optical properties and identify abnormalities. DOT image reconstruction is an ill-posed problem due to the highly scattered photons in the medium and the smaller number of measurements compared to the number of unknowns. Limited-angle DOT reduces probe complexity at the cost of increased reconstruction complexity. Reconstructions are thus commonly marred by artifacts and, as a result, it is difficult to obtain an accurate reconstruction of target objects, e.g., malignant lesions. Reconstruction does not always ensure good localization of small lesions. Furthermore, conventional optimization-based reconstruction methods are computationally expensive, rendering them too slow for real-time imaging applications. Our goal is to develop a fast and accurate image reconstruction method using deep learning, where multitask learning ensures accurate lesion localization in addition to improved reconstruction. We apply spatial-wise attention and a distance transform based loss function in a novel multitask learning formulation to improve localization and reconstruction compared to single-task optimized methods. Given the scarcity of realworld sensor-image pairs required for training supervised deep learning models, we leverage physics-based simulation to generate synthetic datasets and use a transfer learning module to align the sensor domain distribution between in silico and real-world data, while taking advantage of cross-domain learning. Applying our method, we find that we can reconstruct and localize lesions faithfully while allowing real-time reconstruction. We also demonstrate that the present algorithm can reconstruct multiple cancer lesions. The results demonstrate that multitask learning provides sharper and more accurate reconstruction.

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“…The DOT image reconstruction is an ill-posed problem that has been tackled using a wide variety of reconstruction methods (see [7], [8] for a review).…”

Section: B Current Dot Image Reconstruction Approachesmentioning

confidence: 99%

Multitask Deep Learning Reconstruction and Localization of Lesions in Limited Angle Diffuse Optical Tomography

Yedder

Cardoen

Shokoufi

et al. 2022

IEEE Trans. Med. Imaging

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“…In [16] a Regularization by Denoising (RED) approach was proposed, while [17] trained a Neural Network for inverting the Lippman-Scwhinger equation, by firstly learning the pseudoinverse of the nonlinear mathematical operator modelling the DOT physics and then applying an encoder-autoencoder network to denoise. We refer to [18] for a review of other related techniques. Here we investigate and adapt the general strategy presented in [19], the so-called Learned SVD.…”

Section: Introductionmentioning

confidence: 99%

A Learned-SVD approach for Regularization in Diffuse Optical Tomography

Benfenati¹,

Bisazza²,

Causin³

2021

Preprint

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Inverse problems arising in Diffuse Optical Tomography are severely ill-conditioned • Traditional approaches rely on regularization functions with fine tuning of parameters • We explore deep learning techniques in a fully data-driven approach • The approach is the deep learning equivalent of the SVD of a nonlinear functional • The solution is robust even in presence of high levels of noise

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“…To overcome this issue, a structural similarity (SSIM) index was first introduced in 2004 to accord with the HVS by considering luminance, contrast, and structure calculation [ 12 ]. Since then, SSIM has become more popular in the field of image quality assessment (IQA), even in biomedical and clinical applications [ 15 , 16 , 17 , 18 , 19 ].…”

Section: Introductionmentioning

confidence: 99%

Objective Numerical Evaluation of Diffuse, Optically Reconstructed Images Using Structural Similarity Index

2021

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Diffuse optical tomography is emerging as a non-invasive optical modality used to evaluate tissue information by obtaining the optical properties’ distribution. Two procedures are performed to produce reconstructed absorption and reduced scattering images, which provide structural information that can be used to locate inclusions within tissues with the assistance of a known light intensity around the boundary. These methods are referred to as a forward problem and an inverse solution. Once the reconstructed image is obtained, a subjective measurement is used as the conventional way to assess the image. Hence, in this study, we developed an algorithm designed to numerically assess reconstructed images to identify inclusions using the structural similarity (SSIM) index. We compared four SSIM algorithms with 168 simulated reconstructed images involving the same inclusion position with different contrast ratios and inclusion sizes. A multiscale, improved SSIM containing a sharpness parameter (MS-ISSIM-S) was proposed to represent the potential evaluation compared with the human visible perception. The results indicated that the proposed MS-ISSIM-S is suitable for human visual perception by demonstrating a reduction of similarity score related to various contrasts with a similar size of inclusion; thus, this metric is promising for the objective numerical assessment of diffuse, optically reconstructed images.

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Brief review on learning-based methods for optical tomography

Cited by 23 publications

References 63 publications

Multitask Deep Learning Reconstruction and Localization of Lesions in Limited Angle Diffuse Optical Tomography

Multitask Deep Learning Reconstruction and Localization of Lesions in Limited Angle Diffuse Optical Tomography

A Learned-SVD approach for Regularization in Diffuse Optical Tomography

Objective Numerical Evaluation of Diffuse, Optically Reconstructed Images Using Structural Similarity Index

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