Abstract Objectives This study employs dynamic contrast-enhanced MRI (DCE-MRI) to noninvasively predict the proliferative subtype of hepatocellular carcinoma (HCC).This subtype is marked by high tumor proliferation and aggressive clinical behavior.We developed a deep learning prediction model that employs a dynamic radiomics workflow and self-supervised learning (SSL).The model analyzes temporal and spatial patterns in DCE-MRI data to identify the proliferative subtype efficiently and accurately.Our goal is to improve diagnostic precision and guide personalized treatment planning.
Methods This retrospective study included 381 HCC patiephonnts who underwent curative resection at two medical centers.The cohort was divided into the training (n = 220), internal (n = 93), and external read more (n = 68) test sets.A DL model was developed using DCE-MRI of the primary tumor.Class activation mapping was used to interpret HCC proliferation in HCC.Results The pHCC-SSL model performed well in predicting HCC proliferation, with a training set AUC) of 1.
00, an internal test set AUC of 0.91, and an external test set AUC of 0.94.Without SSL pre-training, the AUC for internal and external testing decreased to 0.81 and 0.
80, respectively.The predictive performance of the derived model was superior to that of the current single-sequence model.Conclusions The pHCC-SSL model employs dynamic radiomics and a two-stage training approach to efficiently predict HCC proliferation from multi-sequence DCE-MRI, surpassing traditional single-stage models in accuracy and speed.Critical relevance statement Our study introduces the pHCC-SSL model, a self-supervised deep learning approach using DCE-MRI that enhances the diagnostic accuracy of HCC subtypes, significantly advancing clinical radiology by enabling personalized treatment strategies.Key Points The proposed model enables noninvasive click here identification of HCC with high proliferation and aggressive behavior.
SSL improves lesion differentiation by reducing redundancy and enhancing feature diversity.Dynamic feature extraction captures vascular infiltration, aiding preoperative metastasis risk assessment.Graphical Abstract.