Your search keyword '"Lure, Fleming Y. M."' showing total 13 results

1. Artificial intelligence for stepwise diagnosis and monitoring of COVID-19

Author

Liang, Hengrui, Guo, Yuchen, Chen, Xiangru, Ang, Keng-Leong, He, Yuwei, Jiang, Na, Du, Qiang, Zeng, Qingsi, Lu, Ligong, Gao, Zebin, Li, Linduo, Li, Quanzheng, Nie, Fangxing, Ding, Guiguang, Huang, Gao, Chen, Ailan, Li, Yimin, Guan, Weijie, Sang, Ling, Xu, Yuanda, Chen, Huai, Chen, Zisheng, Li, Shiyue, Zhang, Nuofu, Chen, Ying, Huang, Danxia, Li, Run, Li, Jianfu, Cheng, Bo, Zhao, Yi, Li, Caichen, Xiong, Shan, Wang, Runchen, Liu, Jun, Wang, Wei, Huang, Jun, Cui, Fei, Xu, Tao, Lure, Fleming Y. M., Zhan, Meixiao, Huang, Yuanyi, Yang, Qiang, Dai, Qionghai, Liang, Wenhua, He, Jianxing, and Zhong, Nanshan

Published

2022

2. Usage of compromised lung volume in monitoring steroid therapy on severe COVID-19

Author

Su, Ying, Qiu, Ze-song, Chen, Jun, Ju, Min-jie, Ma, Guo-guang, He, Jin-wei, Yu, Shen-ji, Liu, Kai, Lure, Fleming Y. M., Tu, Guo-wei, Zhang, Yu-yao, and Luo, Zhe

Published

2022

3. E-BDL: Enhanced Band-Dependent Learning Framework for Augmented Radar Sensing.

Author

Cai, Fulin, Wu, Teresa, and Lure, Fleming Y. M.

Subjects

DOPPLER effect, RADAR, ALZHEIMER'S disease, MOTION capture (Human mechanics), DEEP learning, ADAPTIVE filters, MULTISPECTRAL imaging

Abstract

Radar sensors, leveraging the Doppler effect, enable the nonintrusive capture of kinetic and physiological motions while preserving privacy. Deep learning (DL) facilitates radar sensing for healthcare applications such as gait recognition and vital-sign measurement. However, band-dependent patterns, indicating variations in patterns and power scales associated with frequencies in time–frequency representation (TFR), challenge radar sensing applications using DL. Frequency-dependent characteristics and features with lower power scales may be overlooked during representation learning. This paper proposes an Enhanced Band-Dependent Learning framework (E-BDL) comprising an adaptive sub-band filtering module, a representation learning module, and a sub-view contrastive module to fully detect band-dependent features in sub-frequency bands and leverage them for classification. Experimental validation is conducted on two radar datasets, including gait abnormality recognition for Alzheimer's disease (AD) and AD-related dementia (ADRD) risk evaluation and vital-sign monitoring for hemodynamics scenario classification. For hemodynamics scenario classification, E-BDL-ResNet achieves competitive performance in overall accuracy and class-wise evaluations compared to recent methods. For ADRD risk evaluation, the results demonstrate E-BDL-ResNet's superior performance across all candidate models, highlighting its potential as a clinical tool. E-BDL effectively detects salient sub-bands in TFRs, enhancing representation learning and improving the performance and interpretability of DL-based models. [ABSTRACT FROM AUTHOR]

Published

2024

4. Tailoring steroids in the treatment of COVID-19 pneumonia assisted by CT scans: three case reports.

Author

Su, Ying, Han, Yi, Liu, Jie, Qiu, Yue, Tan, Qian, Zhou, Zhen, Yu, Yi-zhou, Chen, Jun, Giger, Maryellen L., Lure, Fleming Y. M., and Luo, Zhe

Subjects

COVID-19, STEROIDS, IMAGE analysis, PNEUMONIA, COMPUTED tomography

Abstract

In this article, we analyze and report cases of three patients who were admitted to Renmin Hospital, Wuhan University, China, for treating COVID-19 pneumonia in February 2020 and were unresponsive to initial treatment of steroids. They were then received titrated steroids treatment based on the assessment of computed tomography (CT) images augmented and analyzed with the artificial intelligence (AI) tool and output. Three patients were finally recovered and discharged. The result indicated that sufficient steroids may be effective in treating the COVID-19 patients after frequent evaluation and timely adjustment according to the disease severity assessed based on the quantitative analysis of the images of serial CT scans. [ABSTRACT FROM AUTHOR]

Published

2020

5. Comparison of a cathode-ray-tube and film for display of computed radiographic images.

Author

Cook, Larry T., Cox, Glendon G., Insana, Michael F., McFadden, Michael A., Hall, Timothy J., Gaborski, Roger S., and Lure, Fleming Y. M.

Published

1998

6. Can AI generate diagnostic reports for radiologist approval on CXR images? A multi-reader and multi-case observer performance study.

Author

Guo L, Xia L, Zheng Q, Zheng B, Jaeger S, Giger ML, Fuhrman J, Li H, Lure FYM, Li H, and Li L

Subjects

Humans, Retrospective Studies, Sensitivity and Specificity, Observer Variation, Female, Male, Lung diagnostic imaging, Middle Aged, Adult, Lung Diseases diagnostic imaging, Aged, Adolescent, Young Adult, Radiographic Image Interpretation, Computer-Assisted methods, Artificial Intelligence, Radiography, Thoracic methods, Radiologists

Abstract

Background: Accurately detecting a variety of lung abnormalities from heterogenous chest X-ray (CXR) images and writing radiology reports is often difficult and time-consuming., Objective: To access the utility of a novel artificial intelligence (AI) system (MOM-ClaSeg) in enhancing the accuracy and efficiency of radiologists in detecting heterogenous lung abnormalities through a multi-reader and multi-case (MRMC) observer performance study., Methods: Over 36,000 CXR images were retrospectively collected from 12 hospitals over 4 months and used as the experiment group and the control group. In the control group, a double reading method is used in which two radiologists interpret CXR to generate a final report, while in the experiment group, one radiologist generates the final reports based on AI-generated reports., Results: Compared with double reading, the diagnostic accuracy and sensitivity of single reading with AI increases significantly by 1.49% and 10.95%, respectively (P < 0.001), while the difference in specificity is small (0.22%) and without statistical significance (P = 0.255). Additionally, the average image reading and diagnostic time in the experimental group is reduced by 54.70% (P < 0.001)., Conclusion: This MRMC study demonstrates that MOM-ClaSeg can potentially serve as the first reader to generate the initial diagnostic reports, with a radiologist only reviewing and making minor modifications (if needed) to arrive at the final decision. It also shows that single reading with AI can achieve a higher diagnostic accuracy and efficiency than double reading.

Published

2024

7. Corrections to "STRIDE: Systematic Radar Intelligence Analysis for ADRD Risk Evaluation with Gait Signature Simulation and Deep Learning".

Author

Cai F, Patharkar A, Wu T, Lure FYM, Chen H, and Chen VC

Abstract

[This corrects the article PMC10399976.].

Published

2023

8. STRIDE: Systematic Radar Intelligence Analysis for ADRD Risk Evaluation with Gait Signature Simulation and Deep Learning.

Author

Cai F, Patharkar A, Wu T, Lure FYM, Chen H, and Chen VC

Abstract

Abnormal gait is a significant non-cognitive biomarker for Alzheimer's disease (AD) and AD-related dementia (ADRD). Micro-Doppler radar, a non-wearable technology, can capture human gait movements for potential early ADRD risk assessment. In this research, we propose to design STRIDE integrating micro-Doppler radar sensors with advanced artificial intelligence (AI) technologies. STRIDE embeds a new deep learning (DL) classification framework. As a proof of concept, we develop a "digital-twin" of STRIDE, consisting of a human walking simulation model and a micro-Doppler radar simulation model, to generate a gait signature dataset. Taking established human walking parameters, the walking model simulates individuals with ADRD under various conditions. The radar model based on electromagnetic scattering and the Doppler frequency shift model is employed to generate micro-Doppler signatures from different moving body parts (e.g., foot, limb, joint, torso, shoulder, etc.). A band-dependent DL framework is developed to predict ADRD risks. The experimental results demonstrate the effectiveness and feasibility of STRIDE for evaluating ADRD risk.

Published

2023

9. Deep learning-based pulmonary tuberculosis automated detection on chest radiography: large-scale independent testing.

Author

Zhou W, Cheng G, Zhang Z, Zhu L, Jaeger S, Lure FYM, and Guo L

Abstract

Background: It is critical to have a deep learning-based system validated on an external dataset before it is used to assist clinical prognoses. The aim of this study was to assess the performance of an artificial intelligence (AI) system to detect tuberculosis (TB) in a large-scale external dataset., Methods: An artificial, deep convolutional neural network (DCNN) was developed to differentiate TB from other common abnormalities of the lung on large-scale chest X-ray radiographs. An internal dataset with 7,025 images was used to develop the AI system, including images were from five sources in the U.S. and China, after which a 6-year dynamic cohort accumulation dataset with 358,169 images was used to conduct an independent external validation of the trained AI system., Results: The developed AI system provided a delineation of the boundaries of the lung region with a Dice coefficient of 0.958. It achieved an AUC of 0.99 and an accuracy of 0.948 on the internal data set, and an AUC of 0.95 and an accuracy of 0.931 on the external data set when it was used to detect TB from normal images. The AI system achieved an AUC of more than 0.9 on the internal data set, and an AUC of over 0.8 on the external data set when it was applied to detect TB, non-TB abnormal and normal images., Conclusions: We conducted a real-world independent validation, which showed that the trained system can be used as a TB screening tool to flag possible cases for rapid radiologic review and guide further examinations for radiologists., Competing Interests: Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at https://qims.amegroups.com/article/view/10.21037/qims-21-676/coif). FYML has the stock of Shenzhen Smart Imaging Healthcare Co., Ltd., and Lin Guo is the Medical Director of Shenzhen Smart Imaging Healthcare Co., Ltd. The other authors have no conflicts of interest to declare., (2022 Quantitative Imaging in Medicine and Surgery. All rights reserved.)

Published

2022

10. Using artificial intelligence to assist radiologists in distinguishing COVID-19 from other pulmonary infections.

Author

Yang Y, Lure FYM, Miao H, Zhang Z, Jaeger S, Liu J, and Guo L

Subjects

Adult, Aged, Algorithms, Clinical Competence statistics & numerical data, Deep Learning, Diagnosis, Differential, Female, Humans, Lung diagnostic imaging, Lung pathology, Male, Middle Aged, Respiratory Tract Infections diagnostic imaging, SARS-CoV-2, Sensitivity and Specificity, Young Adult, Artificial Intelligence, COVID-19 diagnostic imaging, Radiologists statistics & numerical data, Tomography, X-Ray Computed methods

Abstract

Background: Accurate and rapid diagnosis of coronavirus disease (COVID-19) is crucial for timely quarantine and treatment., Purpose: In this study, a deep learning algorithm-based AI model using ResUNet network was developed to evaluate the performance of radiologists with and without AI assistance in distinguishing COVID-19 infected pneumonia patients from other pulmonary infections on CT scans., Methods: For model development and validation, a total number of 694 cases with 111,066 CT slides were retrospectively collected as training data and independent test data in the study. Among them, 118 are confirmed COVID-19 infected pneumonia cases and 576 are other pulmonary infection cases (e.g. tuberculosis cases, common pneumonia cases and non-COVID-19 viral pneumonia cases). The cases were divided into training and testing datasets. The independent test was performed by evaluating and comparing the performance of three radiologists with different years of practice experience in distinguishing COVID-19 infected pneumonia cases with and without the AI assistance., Results: Our final model achieved an overall test accuracy of 0.914 with an area of the receiver operating characteristic (ROC) curve (AUC) of 0.903 in which the sensitivity and specificity are 0.918 and 0.909, respectively. The deep learning-based model then achieved a comparable performance by improving the radiologists' performance in distinguish COVOD-19 from other pulmonary infections, yielding better average accuracy and sensitivity, from 0.941 to 0.951 and from 0.895 to 0.942, respectively, when compared to radiologists without using AI assistance., Conclusion: A deep learning algorithm-based AI model developed in this study successfully improved radiologists' performance in distinguishing COVID-19 from other pulmonary infections using chest CT images.

Published

2021

11. Cascaded deep transfer learning on thoracic CT in COVID-19 patients treated with steroids.

Author

Fuhrman JD, Chen J, Dong Z, Lure FYM, Luo Z, and Giger ML

Abstract

Purpose: Given the recent COVID-19 pandemic and its stress on global medical resources, presented here is the development of a machine intelligent method for thoracic computed tomography (CT) to inform management of patients on steroid treatment. Approach: Transfer learning has demonstrated strong performance when applied to medical imaging, particularly when only limited data are available. A cascaded transfer learning approach extracted quantitative features from thoracic CT sections using a fine-tuned VGG19 network. The extracted slice features were axially pooled to provide a CT-scan-level representation of thoracic characteristics and a support vector machine was trained to distinguish between patients who required steroid administration and those who did not, with performance evaluated through receiver operating characteristic (ROC) curve analysis. Least-squares fitting was used to assess temporal trends using the transfer learning approach, providing a preliminary method for monitoring disease progression. Results: In the task of identifying patients who should receive steroid treatments, this approach yielded an area under the ROC curve of 0.85 ± 0.10 and demonstrated significant separation between patients who received steroids and those who did not. Furthermore, temporal trend analysis of the prediction score matched expected progression during hospitalization for both groups, with separation at early timepoints prior to convergence near the end of the duration of hospitalization. Conclusions: The proposed cascade deep learning method has strong clinical potential for informing clinical decision-making and monitoring patient treatment., (© 2020 The Authors.)

Published

2021

12. Longitudinal changes of laboratory measurements after discharged from hospital in 268 COVID-19 pneumonia patients.

Author

Huang D, Miao H, Zhang Z, Yang Y, Zhang L, Lure FYM, Wang Z, Jaeger S, Guo L, Xu T, and Liu J

Subjects

Adolescent, Adult, Aged, Aged, 80 and over, Biomarkers blood, China, Female, Humans, Longitudinal Studies, Lung diagnostic imaging, Male, Middle Aged, Retrospective Studies, SARS-CoV-2, Tomography, X-Ray Computed, Young Adult, COVID-19 diagnosis, Patient Discharge statistics & numerical data

Abstract

Background and Objective: Monitoring recovery process of coronavirus disease 2019 (COVID-19) patients released from hospital is crucial for exploring residual effects of COVID-19 and beneficial for clinical care. In this study, a comprehensive analysis was carried out to clarify residual effects of COVID-19 on hospital discharged patients., Methods: Two hundred sixty-eight cases with laboratory measured data at hospital discharge record and five follow-up visits were retrospectively collected to carry out statistical data analysis comprehensively, which includes multiple statistical methods (e.g., chi-square, T-test and regression) used in this study., Results: Study found that 13 of 21 hematologic parameters in laboratory measured dataset and volume ratio of right lung lesions on CT images highly associated with COVID-19. Moderate patients had statistically significant lower neutrophils than mild and severe patients after hospital discharge, which is probably caused by more efforts on severe patients and slightly neglection of moderate patients. COVID-19 has residual effects on neutrophil-to-lymphocyte ratio (NLR) of patients who have hypertension or chronic obstructive pulmonary disease (COPD). After released from hospital, female showed better performance in T lymphocytes subset cells, especially T helper lymphocyte% (16% higher than male). According to this sex-based differentiation of COVID-19, male should be recommended to take clinical test more frequently to monitor recovery of immune system. Patients over 60 years old showed unstable recovery process of immune cells (e.g., CD45 + lymphocyte) within 75 days after discharge requiring longer clinical care. Additionally, right lung was vulnerable to COVID-19 and required more time to recover than left lung., Conclusions: Criterion of hospital discharge and strategy of clinical care should be flexible in different cases due to residual effects of COVID-19, which depend on several impact factors. Revealing remaining effects of COVID-19 is an effective way to eliminate disorder of mental health caused by COVID-19 infection.

Published

2021

13. Developing and verifying automatic detection of active pulmonary tuberculosis from multi-slice spiral CT images based on deep learning.

Author

Ma L, Wang Y, Guo L, Zhang Y, Wang P, Pei X, Qian L, Jaeger S, Ke X, Yin X, and Lure FYM

Subjects

Adolescent, Adult, Aged, Aged, 80 and over, Algorithms, Child, Child, Preschool, Female, Humans, Lung diagnostic imaging, Male, Middle Aged, Young Adult, Deep Learning, Radiographic Image Interpretation, Computer-Assisted methods, Tomography, X-Ray Computed methods, Tuberculosis, Pulmonary diagnostic imaging

Abstract

Objective: Diagnosis of tuberculosis (TB) in multi-slice spiral computed tomography (CT) images is a difficult task in many TB prevalent locations in which experienced radiologists are lacking. To address this difficulty, we develop an automated detection system based on artificial intelligence (AI) in this study to simplify the diagnostic process of active tuberculosis (ATB) and improve the diagnostic accuracy using CT images., Data: A CT image dataset of 846 patients is retrospectively collected from a large teaching hospital. The gold standard for ATB patients is sputum smear, and the gold standard for normal and pneumonia patients is the CT report result. The dataset is divided into independent training and testing data subsets. The training data contains 337 ATB, 110 pneumonia, and 120 normal cases, while the testing data contains 139 ATB, 40 pneumonia, and 100 normal cases, respectively., Methods: A U-Net deep learning algorithm was applied for automatic detection and segmentation of ATB lesions. Image processing methods are then applied to CT layers diagnosed as ATB lesions by U-Net, which can detect potentially misdiagnosed layers, and can turn 2D ATB lesions into 3D lesions based on consecutive U-Net annotations. Finally, independent test data is used to evaluate the performance of the developed AI tool., Results: For an independent test, the AI tool yields an AUC value of 0.980. Accuracy, sensitivity, specificity, positive predictive value, and negative predictive value are 0.968, 0.964, 0.971, 0.971, and 0.964, respectively, which shows that the AI tool performs well for detection of ATB and differential diagnosis of non-ATB (i.e. pneumonia and normal cases)., Conclusion: An AI tool for automatic detection of ATB in chest CT is successfully developed in this study. The AI tool can accurately detect ATB patients, and distinguish between ATB and non- ATB cases, which simplifies the diagnosis process and lays a solid foundation for the next step of AI in CT diagnosis of ATB in clinical application.

Published

2020