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Ultrasound Radiogenomics-based Prediction Models for Gene Mutation Status in Breast Cancer
Received date: 2024-04-29
Revised date: 2024-05-17
Accepted date: 2024-05-27
Online published: 2025-02-08
Ultrasound radiogenomics, an emerging field at the intersection of radiology and genomics, employs high-throughput methods to convert radiological images into high-dimensional data, which are then processed to extract and analyze radiomic features. These features, including shape, texture, and intensity variations, are correlated with specific genetic mutations such as TP53 and PIK3CA, critical for cancer progression and treatment response. By integrating clinical data with ultrasonic features, predictive models are developed using machine learning techniques, aiming to refine the capability to diagnose and personalize treatment plans for breast cancer patients. This approach reduces the need for invasive biopsies and medical costs for patients through a better understanding of the tumor’s biological behavior using ultrasound images. This review focuses on the application of ultrasound radiogenomics for predicting gene mutations in breast cancer, highlighting its transformative potential in clinical practice and discussing ongoing challenges and future directions in this field.
Key words: Ultrasound; Radiogenomics; Breast cancer; Gene mutation; Prediction models
Zhai Yue , Tan Dianhuan , Lin Xiaona , Lv Heng , Chen Yan , Li Yongbin , Luo Haiyu , Dan Qing , Zhao Chenyang , Xiang Hongjin , Zheng Tingting , Sun Desheng . Ultrasound Radiogenomics-based Prediction Models for Gene Mutation Status in Breast Cancer[J]. ADVANCED ULTRASOUND IN DIAGNOSIS AND THERAPY, 2025 , 9(1) : 10 -20 . DOI: 10.37015/AUDT.2025.240010
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