Value of endoscopic ultrasound models based on deep learning, radiomics, and combined features in differentiating gastric stromal tumors from leiomyomas

doi:10.3877/cma.j.issn.2095-7157.2026.02.005

Abstract

Abstract:

Objective

To investigate the value of endoscopic ultrasound (EUS)-based deep learning, radiomics, and their combined model in differentiating gastric gastrointestinal stromal tumors (GIST) from leiomyomas.

Methods

Clinical and imaging data from 895 patients (totaling 4, 802 EUS images) at the First Medical Center of the Chinese PLA General Hospital between January 2010 and April 2025 were retrospectively analyzed.Cases were randomly divided into training and test sets at an 8∶2 ratio based on lesions.Radiomic features and fine-grained deep learning features based on the Transformer architecture were extracted from EUS images to construct single-modality and combined-modality machine learning classification models (support vector machine, extreme gradient boosting, random forest).Model performance and clinical utility were comprehensively evaluated using receiver operating characteristic (ROC) curves, the DeLong test, calibration curves, and decision curve analysis.

Results

In the test set, both the deep learning model and the combined model demonstrated significantly better diagnostic performance than the traditional radiomics model. Among these, the combined model using the support vector machine achieved the best performance, with an area under the curve (AUC), accuracy, sensitivity, and specificity of 0.852, 0.792, 0.831, and 0.707, respectively.

Conclusion

EUS-based deep learning features serve as the primary driver for differentiating gastric GIST from leiomyomas, with diagnostic performance significantly superior to that of traditional radiomic features.

Key words: Endoscopic ultrasound, Gastric stromal tumor, Leiomyoma, Deep learning, Radiomics, Differential diagnosis

Yunyun Zhao, Chen Du, Huikai Li, Jichao Pang, Honghao Xu, Qi Zong, Qianqian Chen, Enqiang Linghu. Value of endoscopic ultrasound models based on deep learning, radiomics, and combined features in differentiating gastric stromal tumors from leiomyomas[J]. Chinese Journal of Gastrointestinal Endoscopy(Electronic Edition), 2026, 13(02): 101-107.

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References 20

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临床特征	训练集	测试集	P值
年龄(岁)	57(50，63)	57(48，63)	0.399
性别			0.470
男	294(40.9)	68(38.0)
女	424(59.1)	111(62.0)
大小(cm)	1.5(1.0，2.5)	1.5(1.0，2.6)	0.627
病理类别			0.351
间质瘤	464(64.4)	122(68.2)
平滑肌瘤	256(35.6)	57(31.8)
病变部位			0.699
胃上部	442(61.4)	104(58.1)
胃中部	226(31.4)	60(33.5)
胃下部	52(7.2)	15(8.4)
间质瘤危险分级			0.979
极低危	270(58.2)	72(59.0)
低危	137(29.5)	35(28.7)
中危	41(8.8)	10(8.2)
高危	16(3.4)	5(4.1)

临床特征	训练集	测试集	P值
年龄(岁)	57(50，63)	57(48，63)	0.399
性别			0.470
男	294(40.9)	68(38.0)
女	424(59.1)	111(62.0)
大小(cm)	1.5(1.0，2.5)	1.5(1.0，2.6)	0.627
病理类别			0.351
间质瘤	464(64.4)	122(68.2)
平滑肌瘤	256(35.6)	57(31.8)
病变部位			0.699
胃上部	442(61.4)	104(58.1)
胃中部	226(31.4)	60(33.5)
胃下部	52(7.2)	15(8.4)
间质瘤危险分级			0.979
极低危	270(58.2)	72(59.0)
低危	137(29.5)	35(28.7)
中危	41(8.8)	10(8.2)
高危	16(3.4)	5(4.1)

模型	AUC(95%CI)	准确度	灵敏度	特异度	F₁值
训练集
支持向量机
影像组学	0.842 (0.829~0.855)	0.770	0.752	0.804	0.811
深度学习	1.000	1.000	1.000	1.000	1.000
联合模型	1.000	1.000	1.000	1.000	1.000
极端梯度提升
影像组学	0.793 (0.778~0.808)	0.723	0.706	0.756	0.770
深度学习	0.999 (0.998~1.000)	0.993	0.991	0.996	0.995
联合模型	1.000	0.991	0.989	0.997	0.993
随机森林
影像组学	0.807 (0.793~0.821)	0.730	0.699	0.789	0.773
深度学习	1.000	0.996	0.998	0.992	0.997
联合模型	1.000	0.995	0.997	0.992	0.996
测试集
支持向量机
影像组学	0.766 (0.735~0.796)	0.697	0.715	0.658	0.763
深度学习	0.851 (0.824~0.876)	0.793	0.840	0.691	0.847
联合模型	0.852 (0.825~0.877)	0.792	0.831	0.707	0.845
极端梯度提升
影像组学	0.757 (0.726~0.788)	0.685	0.674	0.711	0.745
深度学习	0.826 (0.798~0.854)	0.769	0.752	0.806	0.816
联合模型	0.824 (0.796~0.851)	0.764	0.753	0.786	0.813
随机森林
影像组学	0.762 (0.731~0.793)	0.670	0.652	0.707	0.730
深度学习	0.831 (0.803~0.859)	0.779	0.820	0.691	0.835
联合模型	0.824 (0.796~0.852)	0.774	0.790	0.740	0.827

模型	AUC(95%CI)	准确度	灵敏度	特异度	F₁值
训练集
支持向量机
影像组学	0.842 (0.829~0.855)	0.770	0.752	0.804	0.811
深度学习	1.000	1.000	1.000	1.000	1.000
联合模型	1.000	1.000	1.000	1.000	1.000
极端梯度提升
影像组学	0.793 (0.778~0.808)	0.723	0.706	0.756	0.770
深度学习	0.999 (0.998~1.000)	0.993	0.991	0.996	0.995
联合模型	1.000	0.991	0.989	0.997	0.993
随机森林
影像组学	0.807 (0.793~0.821)	0.730	0.699	0.789	0.773
深度学习	1.000	0.996	0.998	0.992	0.997
联合模型	1.000	0.995	0.997	0.992	0.996
测试集
支持向量机
影像组学	0.766 (0.735~0.796)	0.697	0.715	0.658	0.763
深度学习	0.851 (0.824~0.876)	0.793	0.840	0.691	0.847
联合模型	0.852 (0.825~0.877)	0.792	0.831	0.707	0.845
极端梯度提升
影像组学	0.757 (0.726~0.788)	0.685	0.674	0.711	0.745
深度学习	0.826 (0.798~0.854)	0.769	0.752	0.806	0.816
联合模型	0.824 (0.796~0.851)	0.764	0.753	0.786	0.813
随机森林
影像组学	0.762 (0.731~0.793)	0.670	0.652	0.707	0.730
深度学习	0.831 (0.803~0.859)	0.779	0.820	0.691	0.835
联合模型	0.824 (0.796~0.852)	0.774	0.790	0.740	0.827

模型比较	P值
极端梯度提升
影像组学与联合模型	<0.05
影像组学与深度学习	<0.05
深度学习与联合模型	0.741
支持向量机
影像组学与联合模型	<0.05
影像组学与深度学习	<0.05
深度学习与联合模型	0.580
随机森林
影像组学与联合模型	<0.05
影像组学与深度学习	<0.05
深度学习与联合模型	0.435

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