Contextual Regularization-Based Energy Optimization for Segmenting Breast Tumor in DCE-MRI

Contextual Regularization-Based Energy Optimization for Segmenting Breast Tumor in DCE-MRI

Accurate breast tumor segmentation is crucial for precise diagnosis, effective treatment planning, and the development of automated decision-support systems in clinical practice. The imprecision of trending segmentation models in differentiating tumors from their surrounding tissues, particularly in...

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Bibliographic Details
Main Authors: Priyadharshini Babu, Mythili Asaithambi, Sudhakar Mogappair Suriyakumar
Format: Article
Language:English
Published: IEEE 2025-01-01
Series:IEEE Access
Subjects:
Breast tumor segmentation
contextual regularization-based energy optimization (CRBEO)
DCE-MRI
gradient optimization
Hessian
Huber criteria
Online Access:https://ieeexplore.ieee.org/document/10935791/
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Summary:Accurate breast tumor segmentation is crucial for precise diagnosis, effective treatment planning, and the development of automated decision-support systems in clinical practice. The imprecision of trending segmentation models in differentiating tumors from their surrounding tissues, particularly in weighing the boundary pixels across tumor regions poses a significant challenge in precise tumor delineation. Dynamic contrast-enhanced magnetic resonance imaging (DCE-MRI) effectively captures tumor vascularity and perfusion dynamics and is a reliable modality for extracting the region of interest (ROI). Nevertheless, the intricate intensity variations in DCE-MRI owing to heterogeneous tumor morphology pose considerable challenges in tumor delineation, necessitating a highly adaptive and robust model for precise tumor segmentation. Accordingly, this manuscript presents a Contextual Regularization-Based Energy Optimization (CRBEO) model that effectively captures these intensity variations in the form of energies contributed by data fidelity and regularization terms. The formulated non-linear energy-based convex optimizer is adaptively tuned by a variational Minimax principle to achieve the desired solution. An iterative gradient descent algorithm is engaged to minimize the energy-based cost function, obtaining stable convergence towards the optimal solution. The extensive relative analysis of CRBEO on complex breast DCE-MRI datasets including QIN breast DCE-MRI, TCGA-BRCA, BreastDM, RIDER, and ISPY1 has recorded significant dice improvements of 30.16%, 11.48%, 20.66%, 1.012%, and 28.107%, respectively on par with trending SOTA methods. The complexity analysis of CRBEO with time and space has justified its extension to real-time clinical diagnosis.
ISSN:2169-3536

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