随机森林
接收机工作特性
卷积神经网络
深度学习
人工智能
医学
逻辑回归
淋巴结转移
机器学习
百分位
计算机科学
放射科
癌症
转移
内科学
统计
数学
作者
Dong Hoon Kang,Han Jo Jeon,Jie‐Hyun Kim,Sang-Il Oh,Ye Seul Seong,Jae Young Jang,Jungwook Kim,Joon Sung Kim,Seung‐Joo Nam,Chang Seok Bang,Hyuk Soon Choi,Seung-Joo Nam,Chang Seok Bang,Hyuk Soon Choi
出处
期刊:Cancers
[Multidisciplinary Digital Publishing Institute]
日期:2025-03-03
卷期号:17 (5): 869-869
被引量:4
标识
DOI:10.3390/cancers17050869
摘要
Objectives: The accurate prediction of lymph node metastasis (LNM) and lymphovascular invasion (LVI) is crucial for determining treatment strategies for early gastric cancer (EGC). This study aimed to develop and validate a deep learning-based clinical decision support system (CDSS) to predict LNM including LVI in EGC using real-world data. Methods: A deep learning-based CDSS was developed by integrating endoscopic images, demographic data, biopsy pathology, and CT findings from the data of 2927 patients with EGC across five institutions. We compared a transformer-based model to an image-only (basic convolutional neural network (CNN)) model and a multimodal classification (CNN with random forest) model. Internal testing was conducted on 449 patients from the five institutions, and external validation was performed on 766 patients from two other institutions. Model performance was assessed using the area under the receiver operating characteristic curve (AUC), probability density function, and clinical utility curve. Results: In the training, internal, and external validation cohorts, LNM/LVI was observed in 379 (12.95%), 49 (10.91%), 15 (9.09%), and 41 (6.82%) patients, respectively. The transformer-based model achieved an AUC of 0.9083, sensitivity of 85.71%, and specificity of 90.75%, outperforming the CNN (AUC 0.5937) and CNN with random forest (AUC 0.7548). High sensitivity and specificity were maintained in internal and external validations. The transformer model distinguished 91.8% of patients with LNM in the internal validation dataset, and 94.0% and 89.1% in the two different external datasets. Conclusions: We propose a deep learning-based CDSS for predicting LNM/LVI in EGC by integrating real-world data, potentially guiding treatment strategies in clinical settings.
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