Multi-landmark environment analysis with reinforcement learning for pelvic abnormality detection and quantification

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Standard

Multi-landmark environment analysis with reinforcement learning for pelvic abnormality detection and quantification. / Bekkouch, Imad Eddine Ibrahim; Maksudov, Bulat; Kiselev, Semen; Mustafaev, Tamerlan; Vrtovec, Tomaž; Ibragimov, Bulat.

I: Medical Image Analysis, Bind 78, 102417, 2022.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Bekkouch, IEI, Maksudov, B, Kiselev, S, Mustafaev, T, Vrtovec, T & Ibragimov, B 2022, 'Multi-landmark environment analysis with reinforcement learning for pelvic abnormality detection and quantification', Medical Image Analysis, bind 78, 102417. https://doi.org/10.1016/j.media.2022.102417

APA

Bekkouch, I. E. I., Maksudov, B., Kiselev, S., Mustafaev, T., Vrtovec, T., & Ibragimov, B. (2022). Multi-landmark environment analysis with reinforcement learning for pelvic abnormality detection and quantification. Medical Image Analysis, 78, [102417]. https://doi.org/10.1016/j.media.2022.102417

Vancouver

Bekkouch IEI, Maksudov B, Kiselev S, Mustafaev T, Vrtovec T, Ibragimov B. Multi-landmark environment analysis with reinforcement learning for pelvic abnormality detection and quantification. Medical Image Analysis. 2022;78. 102417. https://doi.org/10.1016/j.media.2022.102417

Author

Bekkouch, Imad Eddine Ibrahim ; Maksudov, Bulat ; Kiselev, Semen ; Mustafaev, Tamerlan ; Vrtovec, Tomaž ; Ibragimov, Bulat. / Multi-landmark environment analysis with reinforcement learning for pelvic abnormality detection and quantification. I: Medical Image Analysis. 2022 ; Bind 78.

Bibtex

@article{2b29131c9edb4d5288a4c4430277894d,
title = "Multi-landmark environment analysis with reinforcement learning for pelvic abnormality detection and quantification",
abstract = "Morphological abnormalities of the femoroacetabular (hip) joint are among the most common human musculoskeletal disorders and often develop asymptomatically at early easily treatable stages. In this paper, we propose an automated framework for landmark-based detection and quantification of hip abnormalities from magnetic resonance (MR) images. The framework relies on a novel idea of multi-landmark environment analysis with reinforcement learning. In particular, we merge the concepts of the graphical lasso and Morris sensitivity analysis with deep neural networks to quantitatively estimate the contribution of individual landmark and landmark subgroup locations to the other landmark locations. Convolutional neural networks for image segmentation are utilized to propose the initial landmark locations, and landmark detection is then formulated as a reinforcement learning (RL) problem, where each landmark-agent can adjust its position by observing the local MR image neighborhood and the locations of the most-contributive landmarks. The framework was validated on T1-, T2- and proton density-weighted MR images of 260 patients with the aim to measure the lateral center-edge angle (LCEA), femoral neck-shaft angle (NSA), and the anterior and posterior acetabular sector angles (AASA and PASA) of the hip, and derive the quantitative abnormality metrics from these angles. The framework was successfully tested using the UNet and feature pyramid network (FPN) segmentation architectures for landmark proposal generation, and the deep Q-network (DeepQN), deep deterministic policy gradient (DDPG), twin delayed deep deterministic policy gradient (TD3), and actor-critic policy gradient (A2C) RL networks for landmark position optimization. The resulting overall landmark detection error of 1.5 mm and angle measurement error of 1.4° indicates a superior performance in comparison to existing methods. Moreover, the automatically estimated abnormality labels were in 95% agreement with those generated by an expert radiologist.",
keywords = "landmark detection, magnetic resonance, pelvic abnormalities, reinforcement learning",
author = "Bekkouch, {Imad Eddine Ibrahim} and Bulat Maksudov and Semen Kiselev and Tamerlan Mustafaev and Toma{\v z} Vrtovec and Bulat Ibragimov",
note = "Publisher Copyright: {\textcopyright} 2022 The Author(s)",
year = "2022",
doi = "10.1016/j.media.2022.102417",
language = "English",
volume = "78",
journal = "Medical Image Analysis",
issn = "1361-8415",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Multi-landmark environment analysis with reinforcement learning for pelvic abnormality detection and quantification

AU - Bekkouch, Imad Eddine Ibrahim

AU - Maksudov, Bulat

AU - Kiselev, Semen

AU - Mustafaev, Tamerlan

AU - Vrtovec, Tomaž

AU - Ibragimov, Bulat

N1 - Publisher Copyright: © 2022 The Author(s)

PY - 2022

Y1 - 2022

N2 - Morphological abnormalities of the femoroacetabular (hip) joint are among the most common human musculoskeletal disorders and often develop asymptomatically at early easily treatable stages. In this paper, we propose an automated framework for landmark-based detection and quantification of hip abnormalities from magnetic resonance (MR) images. The framework relies on a novel idea of multi-landmark environment analysis with reinforcement learning. In particular, we merge the concepts of the graphical lasso and Morris sensitivity analysis with deep neural networks to quantitatively estimate the contribution of individual landmark and landmark subgroup locations to the other landmark locations. Convolutional neural networks for image segmentation are utilized to propose the initial landmark locations, and landmark detection is then formulated as a reinforcement learning (RL) problem, where each landmark-agent can adjust its position by observing the local MR image neighborhood and the locations of the most-contributive landmarks. The framework was validated on T1-, T2- and proton density-weighted MR images of 260 patients with the aim to measure the lateral center-edge angle (LCEA), femoral neck-shaft angle (NSA), and the anterior and posterior acetabular sector angles (AASA and PASA) of the hip, and derive the quantitative abnormality metrics from these angles. The framework was successfully tested using the UNet and feature pyramid network (FPN) segmentation architectures for landmark proposal generation, and the deep Q-network (DeepQN), deep deterministic policy gradient (DDPG), twin delayed deep deterministic policy gradient (TD3), and actor-critic policy gradient (A2C) RL networks for landmark position optimization. The resulting overall landmark detection error of 1.5 mm and angle measurement error of 1.4° indicates a superior performance in comparison to existing methods. Moreover, the automatically estimated abnormality labels were in 95% agreement with those generated by an expert radiologist.

AB - Morphological abnormalities of the femoroacetabular (hip) joint are among the most common human musculoskeletal disorders and often develop asymptomatically at early easily treatable stages. In this paper, we propose an automated framework for landmark-based detection and quantification of hip abnormalities from magnetic resonance (MR) images. The framework relies on a novel idea of multi-landmark environment analysis with reinforcement learning. In particular, we merge the concepts of the graphical lasso and Morris sensitivity analysis with deep neural networks to quantitatively estimate the contribution of individual landmark and landmark subgroup locations to the other landmark locations. Convolutional neural networks for image segmentation are utilized to propose the initial landmark locations, and landmark detection is then formulated as a reinforcement learning (RL) problem, where each landmark-agent can adjust its position by observing the local MR image neighborhood and the locations of the most-contributive landmarks. The framework was validated on T1-, T2- and proton density-weighted MR images of 260 patients with the aim to measure the lateral center-edge angle (LCEA), femoral neck-shaft angle (NSA), and the anterior and posterior acetabular sector angles (AASA and PASA) of the hip, and derive the quantitative abnormality metrics from these angles. The framework was successfully tested using the UNet and feature pyramid network (FPN) segmentation architectures for landmark proposal generation, and the deep Q-network (DeepQN), deep deterministic policy gradient (DDPG), twin delayed deep deterministic policy gradient (TD3), and actor-critic policy gradient (A2C) RL networks for landmark position optimization. The resulting overall landmark detection error of 1.5 mm and angle measurement error of 1.4° indicates a superior performance in comparison to existing methods. Moreover, the automatically estimated abnormality labels were in 95% agreement with those generated by an expert radiologist.

KW - landmark detection

KW - magnetic resonance

KW - pelvic abnormalities

KW - reinforcement learning

UR - http://www.scopus.com/inward/record.url?scp=85126675060&partnerID=8YFLogxK

U2 - 10.1016/j.media.2022.102417

DO - 10.1016/j.media.2022.102417

M3 - Journal article

C2 - 35325712

AN - SCOPUS:85126675060

VL - 78

JO - Medical Image Analysis

JF - Medical Image Analysis

SN - 1361-8415

M1 - 102417

ER -

ID: 307372433