Your search keyword '"Yang, Yingjian"' showing total 4 results

1. COPD stage detection: leveraging the auto-metric graph neural network with inspiratory and expiratory chest CT images

Author

Deng, Xingguang, Li, Wei, Yang, Yingjian, Wang, Shicong, Zeng, Nanrong, Xu, Jiaxuan, Hassan, Haseeb, Chen, Ziran, Liu, Yang, Miao, Xiaoqiang, Guo, Yingwei, Chen, Rongchang, and Kang, Yan

Published

2024

2. Lung Radiomics Features Selection for COPD Stage Classification Based on Auto-Metric Graph Neural Network.

Author

Yang, Yingjian, Wang, Shicong, Zeng, Nanrong, Duan, Wenxin, Chen, Ziran, Liu, Yang, Li, Wei, Guo, Yingwei, Chen, Huai, Li, Xian, Chen, Rongchang, and Kang, Yan

Subjects

*RADIOMICS, *FEATURE selection, *FEATURE extraction, *CHRONIC obstructive pulmonary disease, *CONVOLUTIONAL neural networks

Abstract

Chronic obstructive pulmonary disease (COPD) is a preventable, treatable, progressive chronic disease characterized by persistent airflow limitation. Patients with COPD deserve special consideration regarding treatment in this fragile population for preclinical health management. Therefore, this paper proposes a novel lung radiomics combination vector generated by a generalized linear model (GLM) and Lasso algorithm for COPD stage classification based on an auto-metric graph neural network (AMGNN) with a meta-learning strategy. Firstly, the parenchyma images were segmented from chest high-resolution computed tomography (HRCT) images by ResU-Net. Second, lung radiomics features are extracted from the parenchyma images by PyRadiomics. Third, a novel lung radiomics combination vector (3 + 106) is constructed by the GLM and Lasso algorithm for determining the radiomics risk factors (K = 3) and radiomics node features (d = 106). Last, the COPD stage is classified based on the AMGNN. The results show that compared with the convolutional neural networks and machine learning models, the AMGNN based on constructed novel lung radiomics combination vector performs best, achieving an accuracy of 0.943, precision of 0.946, recall of 0.943, F1-score of 0.943, and ACU of 0.984. Furthermore, it is found that our method is effective for COPD stage classification. [ABSTRACT FROM AUTHOR]

Published

2022

3. A Focus on the Role of DSC-PWI Dynamic Radiomics Features in Diagnosis and Outcome Prediction of Ischemic Stroke.

Author

Guo, Yingwei, Yang, Yingjian, Cao, Fengqiu, Wang, Mingming, Luo, Yu, Guo, Jia, Liu, Yang, Zeng, Xueqiang, Miu, Xiaoqiang, Zaman, Asim, Lu, Jiaxi, and Kang, Yan

Subjects

*ISCHEMIC stroke, *RADIOMICS, *NEUROLOGIC examination, *FEATURE selection, *EXPERIMENTAL groups

Abstract

Background: The ability to accurately detect ischemic stroke and predict its neurological recovery is of great clinical value. This study intended to evaluate the performance of whole-brain dynamic radiomics features (DRF) for ischemic stroke detection, neurological impairment assessment, and outcome prediction. Methods: The supervised feature selection (Lasso) and unsupervised feature-selection methods (five-feature dimension-reduction algorithms) were used to generate four experimental groups with DRF in different combinations. Ten machine learning models were used to evaluate their performance by ten-fold cross-validation. Results: In experimental group_A, the best AUCs (0.873 for stroke detection, 0.795 for NIHSS assessment, and 0.818 for outcome prediction) were obtained by outstanding DRF selected by Lasso, and the performance of significant DRF was better than the five-feature dimension-reduction algorithms. The selected outstanding dimension-reduction DRF in experimental group_C obtained a better AUC than dimension-reduction DRF in experimental group_A but were inferior to the outstanding DRF in experimental group_A. When combining the outstanding DRF with each dimension-reduction DRF (experimental group_B), the performance can be improved in ischemic stroke detection (best AUC = 0.899) and NIHSS assessment (best AUC = 0.835) but failed in outcome prediction (best AUC = 0.806). The performance can be further improved when combining outstanding DRF with outstanding dimension-reduction DRF (experimental group_D), achieving the highest AUC scores in all three evaluation items (0.925 for stroke detection, 0.853 for NIHSS assessment, and 0.828 for outcome prediction). By the method in this study, comparing the best AUC of Ft-test in experimental group_A and the best_AUC in experimental group_D, the AUC in stroke detection increased by 19.4% (from 0.731 to 0.925), the AUC in NIHSS assessment increased by 20.1% (from 0.652 to 0.853), and the AUC in prognosis prediction increased by 14.9% (from 0.679 to 0.828). This study provided a potential clinical tool for detailed clinical diagnosis and outcome prediction before treatment. [ABSTRACT FROM AUTHOR]

Published

2022

4. Novel Survival Features Generated by Clinical Text Information and Radiomics Features May Improve the Prediction of Ischemic Stroke Outcome.

Author

Guo, Yingwei, Yang, Yingjian, Cao, Fengqiu, Li, Wei, Wang, Mingming, Luo, Yu, Guo, Jia, Zaman, Asim, Zeng, Xueqiang, Miu, Xiaoqiang, Li, Longyu, Qiu, Weiyan, and Kang, Yan

Subjects

*RADIOMICS, *ISCHEMIC stroke, *MACHINE learning, *FORECASTING, *FUNCTIONAL status

Abstract

Background: Accurate outcome prediction is of great clinical significance in customizing personalized treatment plans, reducing the situation of poor recovery, and objectively and accurately evaluating the treatment effect. This study intended to evaluate the performance of clinical text information (CTI), radiomics features, and survival features (SurvF) for predicting functional outcomes of patients with ischemic stroke. Methods: SurvF was constructed based on CTI and mRS radiomics features (mRSRF) to improve the prediction of the functional outcome in 3 months (90-day mRS). Ten machine learning models predicted functional outcomes in three situations (2-category, 4-category, and 7-category) using seven feature groups constructed by CTI, mRSRF, and SurvF. Results: For 2-category, ALL (CTI + mRSRF+ SurvF) performed best, with an mAUC of 0.884, mAcc of 0.864, mPre of 0.877, mF1 of 0.86, and mRecall of 0.864. For 4-category, ALL also achieved the best mAuc of 0.787, while CTI + SurvF achieved the best score with mAcc = 0.611, mPre = 0.622, mF1 = 0.595, and mRe-call = 0.611. For 7-category, CTI + SurvF performed best, with an mAuc of 0.788, mPre of 0.519, mAcc of 0.529, mF1 of 0.495, and mRecall of 0.47. Conclusions: The above results indicate that mRSRF + CTI can accurately predict functional outcomes in ischemic stroke patients with proper machine learning models. Moreover, combining SurvF will improve the prediction effect compared with the original features. However, limited by the small sample size, further validation on larger and more varied datasets is necessary. [ABSTRACT FROM AUTHOR]

Published

2022