Endometrial cancer (EC), a growing malignancy among women, underscores an urgent need for early detection and intervention, critical for enhancing patient outcomes and survival rates. Traditional diagnostic approaches, including ultrasound (US), magnetic resonance imaging (MRI), hysteroscopy, and histopathology, have been essential in establishing robust diagnostic and prognostic frameworks for EC. These methods offer detailed insights into tumor morphology, vital for clinical decision-making. However, their analysis relies heavily on the expertise of radiologists and pathologists, a process that is not only time-consuming and labor-intensive but also prone to human error. The emergence of deep learning (DL) in computer vision has significantly transformed medical image analysis, presenting substantial potential for EC diagnosis. DL models, capable of autonomously learning and extracting complex features from imaging and histopathological data, have demonstrated remarkable accuracy in discriminating EC and stratifying patient prognoses. This review comprehensively examines and synthesizes the current literature on DL-based imaging techniques for EC diagnosis and management. It also aims to identify challenges faced by DL in this context and to explore avenues for its future development. Through these detailed analyses, our objective is to inform future research directions and promote the integration of DL into EC diagnostic and treatment strategies, thereby enhancing the precision and efficiency of clinical practice.
Keywords: Deep learning; convolutional neural networks; endometrial cancer; imaging techniques.
© The Author(s) 2024.