Your search keyword '"Luo Luyang"' showing total 9 results

1. Development and validation of an interpretable model integrating multimodal information for improving ovarian cancer diagnosis

Author

Xiang, Huiling, Xiao, Yongjie, Li, Fang, Li, Chunyan, Liu, Lixian, Deng, Tingting, Yan, Cuiju, Zhou, Fengtao, Wang, Xi, Ou, Jinjing, Lin, Qingguang, Hong, Ruixia, Huang, Lishu, Luo, Luyang, Lin, Huangjing, Lin, Xi, and Chen, Hao

Published

2024

2. Triplet attention and dual-pool contrastive learning for clinic-driven multi-label medical image classification

Author

Zhang, Yuhan, Luo, Luyang, Dou, Qi, and Heng, Pheng-Ann

Published

2023

3. Oxidative damages of maize seedlings caused by exposure to a combination of potassium deficiency and salt stress

Author

Gong, Xiaolan, Chao, Liu, Zhou, Min, Hong, Mengmeng, Luo, Luyang, Wang, Ling, Ying, Wang, Cai, Jingwei, Songjie, Gong, and Hong, Fashui

Published

2011

4. Influences of magnesium deficiency and cerium on antioxidant system of spinach chloroplasts

Author

Ze, Yuguan, Yin, Sitao, Ji, Zhe, Luo, Luyang, Liu, Chao, and Hong, Fashui

Published

2009

5. UD-MIL: Uncertainty-Driven Deep Multiple Instance Learning for OCT Image Classification.

Author

Wang, Xi, Tang, Fangyao, Chen, Hao, Luo, Luyang, Tang, Ziqi, Ran, An-Ran, Cheung, Carol Y., and Heng, Pheng-Ann

Subjects

CONVOLUTIONAL neural networks, DEEP learning, RECEIVER operating characteristic curves, RECURRENT neural networks, OPTICAL coherence tomography, SUPERVISED learning, NOSOLOGY

Abstract

Deep learning has achieved remarkable success in the optical coherence tomography (OCT) image classification task with substantial labelled B-scan images available. However, obtaining such fine-grained expert annotations is usually quite difficult and expensive. How to leverage the volume-level labels to develop a robust classifier is very appealing. In this paper, we propose a weakly supervised deep learning framework with uncertainty estimation to address the macula-related disease classification problem from OCT images with the only volume-level label being available. First, a convolutional neural network (CNN) based instance-level classifier is iteratively refined by using the proposed uncertainty-driven deep multiple instance learning scheme. To our best knowledge, we are the first to incorporate the uncertainty evaluation mechanism into multiple instance learning (MIL) for training a robust instance classifier. The classifier is able to detect suspicious abnormal instances and abstract the corresponding deep embedding with high representation capability simultaneously. Second, a recurrent neural network (RNN) takes instance features from the same bag as input and generates the final bag-level prediction by considering the individually local instance information and globally aggregated bag-level representation. For more comprehensive validation, we built two large diabetic macular edema (DME) OCT datasets from different devices and imaging protocols to evaluate the efficacy of our method, which are composed of 30,151 B-scans in 1,396 volumes from 274 patients (Heidelberg-DME dataset) and 38,976 B-scans in 3,248 volumes from 490 patients (Triton-DME dataset), respectively. We compare the proposed method with the state-of-the-art approaches, and experimentally demonstrate that our method is superior to alternative methods, achieving volume-level accuracy, F1-score and area under the receiver operating characteristic curve (AUC) of 95.1%, 0.939 and 0.990 on Heidelberg-DME and those of 95.1%, 0.935 and 0.986 on Triton-DME, respectively. Furthermore, the proposed method also yields competitive results on another public age-related macular degeneration OCT dataset, indicating the high potential as an effective screening tool in the clinical practice. [ABSTRACT FROM AUTHOR]

Published

2020

6. Deep Mining External Imperfect Data for Chest X-Ray Disease Screening.

Author

Luo, Luyang, Yu, Lequan, Chen, Hao, Liu, Quande, Wang, Xi, Xu, Jiaqi, and Heng, Pheng-Ann

Subjects

*X-rays, *NOSOLOGY, *X-ray imaging, *DEEP learning, *CHEST X rays

Abstract

Deep learning approaches have demonstrated remarkable progress in automatic Chest X-ray analysis. The data-driven feature of deep models requires training data to cover a large distribution. Therefore, it is substantial to integrate knowledge from multiple datasets, especially for medical images. However, learning a disease classification model with extra Chest X-ray (CXR) data is yet challenging. Recent researches have demonstrated that performance bottleneck exists in joint training on different CXR datasets, and few made efforts to address the obstacle. In this paper, we argue that incorporating an external CXR dataset leads to imperfect training data, which raises the challenges. Specifically, the imperfect data is in two folds: domain discrepancy, as the image appearances vary across datasets; and label discrepancy, as different datasets are partially labeled. To this end, we formulate the multi-label thoracic disease classification problem as weighted independent binary tasks according to the categories. For common categories shared across domains, we adopt task-specific adversarial training to alleviate the feature differences. For categories existing in a single dataset, we present uncertainty-aware temporal ensembling of model predictions to mine the information from the missing labels further. In this way, our framework simultaneously models and tackles the domain and label discrepancies, enabling superior knowledge mining ability. We conduct extensive experiments on three datasets with more than 360,000 Chest X-ray images. Our method outperforms other competing models and sets state-of-the-art performance on the official NIH test set with 0.8349 AUC, demonstrating its effectiveness of utilizing the external dataset to improve the internal classification. [ABSTRACT FROM AUTHOR]

Published

2020

7. Semi-Supervised Medical Image Classification With Relation-Driven Self-Ensembling Model.

Author

Liu, Quande, Yu, Lequan, Luo, Luyang, Dou, Qi, and Heng, Pheng Ann

Subjects

MEDICAL coding, DIAGNOSTIC imaging, MEDICAL imaging systems, IMAGE analysis, NOSOLOGY, INFORMATION modeling

Abstract

Training deep neural networks usually requires a large amount of labeled data to obtain good performance. However, in medical image analysis, obtaining high-quality labels for the data is laborious and expensive, as accurately annotating medical images demands expertise knowledge of the clinicians. In this paper, we present a novel relation-driven semi-supervised framework for medical image classification. It is a consistency-based method which exploits the unlabeled data by encouraging the prediction consistency of given input under perturbations, and leverages a self-ensembling model to produce high-quality consistency targets for the unlabeled data. Considering that human diagnosis often refers to previous analogous cases to make reliable decisions, we introduce a novel sample relation consistency (SRC) paradigm to effectively exploit unlabeled data by modeling the relationship information among different samples. Superior to existing consistency-based methods which simply enforce consistency of individual predictions, our framework explicitly enforces the consistency of semantic relation among different samples under perturbations, encouraging the model to explore extra semantic information from unlabeled data. We have conducted extensive experiments to evaluate our method on two public benchmark medical image classification datasets, i.e., skin lesion diagnosis with ISIC 2018 challenge and thorax disease classification with ChestX-ray14. Our method outperforms many state-of-the-art semi-supervised learning methods on both single-label and multi-label image classification scenarios. [ABSTRACT FROM AUTHOR]

Published

2020

8. Effects of Cerium on Key Enzymes of Carbon Assimilation of Spinach Under Magnesium Deficiency.

Author

Ze Yuguan, Zhou Min, Luo Luyang, Ji Zhe, Liu Chao, Yin Sitao, Duan Yanmei, Li Na, and Hong Fashui

Abstract

Abstract  The mechanism of the fact that cerium improves the photosynthesis of plants under magnesium deficiency is poorly understood. The main aim of the study was to determine the role of cerium in the amelioration of magnesium deficiency effects in CO2 assimilation of spinach. Spinach plants were cultivated in Hoagland’s solution. They were subjected to magnesium deficiency and to cerium chloride administered in the magnesium-present Hoagland’s media and magnesium-deficient Hoagland’s media. The results showed that the chlorophyll synthesis and oxygen evolution was destroyed, and the activities of Rubisco carboxylasae and Rubisco activase and the expression of Rubisco large subunit (rbcL), Rubisco small subunit (rbcS), and Rubisco activase subunit (rca) were significantly inhibited, then plant growth was inhibited by magnesium deficiency. However, cerium promotes the chlorophyll synthesis, the activities of two key enzymes in CO2 assimilation, and the expression of rbcL, rbcS, and rca, thus leading to the enhancement of spinach growth under magnesium-deficient conditions. [ABSTRACT FROM AUTHOR]

Published

2009

9. Towards multi-center glaucoma OCT image screening with semi-supervised joint structure and function multi-task learning.

Author

Wang, Xi, Chen, Hao, Ran, An-Ran, Luo, Luyang, Chan, Poemen P., Tham, Clement C., Chang, Robert T., Mannil, Suria S., Cheung, Carol Y., and Heng, Pheng-Ann

Subjects

*PERIMETRY, *GLAUCOMA, *OPTICAL coherence tomography, *RETROLENTAL fibroplasia, *REGRESSION analysis, *VISUAL fields, *RECEIVER operating characteristic curves

Abstract

• It is the first study on unifying structure analysis and function regression for glaucoma screening from OCT images. • The semi-supervised smoothness assumption is made to solve the missing regression label problem. • A multi-task learning network is proposed to explore the structure-function relationship for glaucoma screening. • Extensive experiments on large-scale multi-center datasets demonstrate the effectiveness of the multi-task learning model. Glaucoma is the leading cause of irreversible blindness in the world. Structure and function assessments play an important role in diagnosing glaucoma. Nowadays, Optical Coherence Tomography (OCT) imaging gains increasing popularity in measuring the structural change of eyes. However, few automated methods have been developed based on OCT images to screen glaucoma. In this paper, we are the first to unify the structure analysis and function regression to distinguish glaucoma patients from normal controls effectively. Specifically, our method works in two steps: a semi-supervised learning strategy with smoothness assumption is first applied for the surrogate assignment of missing function regression labels. Subsequently, the proposed multi-task learning network is capable of exploring the structure and function relationship between the OCT image and visual field measurement simultaneously, which contributes to classification performance improvement. It is also worth noting that the proposed method is assessed by two large-scale multi-center datasets. In other words, we first build the largest glaucoma OCT image dataset (i.e., HK dataset) involving 975,400 B-scans from 4,877 volumes to develop and evaluate the proposed method, then the model without further fine-tuning is directly applied on another independent dataset (i.e., Stanford dataset) containing 246,200 B-scans from 1,231 volumes. Extensive experiments are conducted to assess the contribution of each component within our framework. The proposed method outperforms the baseline methods and two glaucoma experts by a large margin, achieving volume-level Area Under ROC Curve (AUC) of 0.977 on HK dataset and 0.933 on Stanford dataset, respectively. The experimental results indicate the great potential of the proposed approach for the automated diagnosis system. [ABSTRACT FROM AUTHOR]

Published

2020