Your search keyword '"Li, Qiwei"' showing total 9 results

1. Image-based profiling and deep learning reveal morphological heterogeneity of colorectal cancer organoids.

Author

Huang K, Li M, Li Q, Chen Z, Zhang Y, and Gu Z

Subjects

Humans, Neoplasm Recurrence, Local metabolism, Neoplasm Recurrence, Local pathology, Organoids metabolism, Organoids pathology, Recurrence, Tumor Microenvironment, Colorectal Neoplasms genetics, Deep Learning

Abstract

Patient-derived organoids have proven to be a highly relevant model for evaluating of disease mechanisms and drug efficacies, as they closely recapitulate in vivo physiology. Colorectal cancer organoids, specifically, exhibit a diverse range of morphologies, which have been analyzed with image-based profiling. However, the relationship between morphological subtypes and functional parameters of the organoids remains underexplored. Here, we identified two distinct morphological subtypes ("cystic" and "solid") across 31360 bright field images using image-based profiling, which correlated differently with viability and apoptosis level of colorectal cancer organoids. Leveraging object detection neural networks, we were able to categorize single organoids achieving higher viability scores as "cystic" than "solid" subtype. Furthermore, a deep generative model was proposed to predict apoptosis intensity based on a apoptosis-featured dataset encompassing over 17000 bright field and matched fluorescent images. Notably, a significant correlation of 0.91 between the predicted value and ground truth was achived, underscoring the feasibility of this generative model as a potential means for assessing organoid functional parameters. The underlying cellular heterogeneity of the organoids, i.e., conserved colonic cell types and rare immune components, was also verified with scRNA sequencing, implying a compromised tumor microenvironment. Additionally, the "cystic" subtype was identified as a relapse phenotype featuring intestinal stem cell signatures, suggesting that this visually discernible relapse phenotype shows potential as a novel biomarker for colorectal cancer diagnosis and prognosis. In summary, our findings demonstrate that the morphological heterogeneity of colorectal cancer organoids explicitly recapitulate the association of phenotypic features and exogenous perturbations through the image-based profiling, providing new insights into disease mechanisms., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier Ltd. All rights reserved.)

Published

2024

2. Automated evaluation of tumor spheroid behavior in 3D culture using deep learning-based recognition.

Author

Chen Z, Ma N, Sun X, Li Q, Zeng Y, Chen F, Sun S, Xu J, Zhang J, Ye H, Ge J, Zhang Z, Cui X, Leong K, Chen Y, and Gu Z

Subjects

Cell Line, Tumor, Cell Survival, Drug Evaluation, Preclinical, Deep Learning, Spheroids, Cellular

Abstract

Three-dimensional in vitro tumor models provide more physiologically relevant responses to drugs than 2D models, but the lack of proper evaluation indices and the laborious quantitation of tumor behavior in 3D have limited the use of 3D tumor models in large-scale preclinical drug screening. Here we propose two indices of 3D tumor invasiveness-the excess perimeter index (EPI) and the multiscale entropy index (MSEI)-and combine these indices with a new convolutional neural network-based algorithm for tumor spheroid boundary detection. This new algorithm for 3D tumor boundary detection and invasiveness analysis is more accurate than any other existing algorithms. We apply this spheroid monitoring and AI-based recognition technique ("SMART") to evaluating the invasiveness of tumor spheroids grown from tumor cell lines and from primary tumor cells in 3D culture., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2021

3. A deep learning-based model for screening and staging pneumoconiosis.

Author

Zhang L, Rong R, Li Q, Yang DM, Yao B, Luo D, Zhang X, Zhu X, Luo J, Liu Y, Yang X, Ji X, Liu Z, Xie Y, Sha Y, Li Z, and Xiao G

Subjects

Databases as Topic, Humans, Pneumoconiosis diagnostic imaging, Pneumoconiosis pathology, Radiologists, Reproducibility of Results, Deep Learning, Mass Screening, Models, Biological, Pneumoconiosis diagnosis

Abstract

This study aims to develop an artificial intelligence (AI)-based model to assist radiologists in pneumoconiosis screening and staging using chest radiographs. The model, based on chest radiographs, was developed using a training cohort and validated using an independent test cohort. Every image in the training and test datasets were labeled by experienced radiologists in a double-blinded fashion. The computational model started by segmenting the lung field into six subregions. Then, convolutional neural network classification model was used to predict the opacity level for each subregion respectively. Finally, the diagnosis for each subject (normal, stage I, II, or III pneumoconiosis) was determined by summarizing the subregion-based prediction results. For the independent test cohort, pneumoconiosis screening accuracy was 0.973, with both sensitivity and specificity greater than 0.97. The accuracy for pneumoconiosis staging was 0.927, better than that achieved by two groups of radiologists (0.87 and 0.84, respectively). This study develops a deep learning-based model for screening and staging of pneumoconiosis using man-annotated chest radiographs. The model outperformed two groups of radiologists in the accuracy of pneumoconiosis staging. This pioneer work demonstrates the feasibility and efficiency of AI-assisted radiography screening and diagnosis in occupational lung diseases.

Published

2021

4. Organoids revealed: morphological analysis of the profound next generation in-vitro model with artificial intelligence

Author

Du, Xuan, Chen, Zaozao, Li, Qiwei, Yang, Sheng, Jiang, Lincao, Yang, Yi, Li, Yanhui, and Gu, Zhongze

Published

2023

5. A Gallbladder Cancer Survival Prediction Model Based on Multimodal Fusion Analysis

Author

Yin, Ziming, Chen, Tao, Shu, Yijun, Li, Qiwei, Yuan, Zhiqing, Zhang, Yijue, Xu, Xinsen, and Liu, Yingbin

Published

2023

6. Deep Learning-Based Automated Measurement of Murine Bone Length in Radiographs.

Author

Rong, Ruichen, Denton, Kristin, Jin, Kevin W., Quan, Peiran, Wen, Zhuoyu, Kozlitina, Julia, Lyon, Stephen, Wang, Aileen, Wise, Carol A., Beutler, Bruce, Yang, Donghan M., Li, Qiwei, Rios, Jonathan J., and Xiao, Guanghua

Subjects

BONE measurement, X-ray imaging, LENGTH measurement, GENETIC models, PHENOTYPIC plasticity

Abstract

Genetic mouse models of skeletal abnormalities have demonstrated promise in the identification of phenotypes relevant to human skeletal diseases. Traditionally, phenotypes are assessed by manually examining radiographs, a tedious and potentially error-prone process. In response, this study developed a deep learning-based model that streamlines the measurement of murine bone lengths from radiographs in an accurate and reproducible manner. A bone detection and measurement pipeline utilizing the Keypoint R-CNN algorithm with an EfficientNet-B3 feature extraction backbone was developed to detect murine bone positions and measure their lengths. The pipeline was developed utilizing 94 X-ray images with expert annotations on the start and end position of each murine bone. The accuracy of our pipeline was evaluated on an independent dataset test with 592 images, and further validated on a previously published dataset of 21,300 mouse radiographs. The results showed that our model performed comparably to humans in measuring tibia and femur lengths (R2 > 0.92, p-value = 0) and significantly outperformed humans in measuring pelvic lengths in terms of precision and consistency. Furthermore, the model improved the precision and consistency of genetic association mapping results, identifying significant associations between genetic mutations and skeletal phenotypes with reduced variability. This study demonstrates the feasibility and efficiency of automated murine bone length measurement in the identification of mouse models of abnormal skeletal phenotypes. [ABSTRACT FROM AUTHOR]

Published

2024

7. MB-GAN: Microbiome Simulation via Generative Adversarial Network.

Author

Rong, Ruichen, Jiang, Shuang, Xu, Lin, Xiao, Guanghua, Xie, Yang, Liu, Dajiang J, Li, Qiwei, and Zhan, Xiaowei

Subjects

GENERATIVE adversarial networks, DEEP learning, HUMAN microbiota, GUT microbiome, STATISTICAL models, PROBABILISTIC generative models

Abstract

Background Trillions of microbes inhabit the human body and have a profound effect on human health. The recent development of metagenome-wide association studies and other quantitative analysis methods accelerate the discovery of the associations between human microbiome and diseases. To assess the strengths and limitations of these analytical tools, simulating realistic microbiome datasets is critically important. However, simulating the real microbiome data is challenging because it is difficult to model their correlation structure using explicit statistical models. Results To address the challenge of simulating realistic microbiome data, we designed a novel simulation framework termed MB-GAN, by using a generative adversarial network (GAN) and utilizing methodology advancements from the deep learning community. MB-GAN can automatically learn from given microbial abundances and compute simulated abundances that are indistinguishable from them. In practice, MB-GAN showed the following advantages. First, MB-GAN avoids explicit statistical modeling assumptions, and it only requires real datasets as inputs. Second, unlike the traditional GANs, MB-GAN is easily applicable and can converge efficiently. Conclusions By applying MB-GAN to a case-control gut microbiome study of 396 samples, we demonstrated that the simulated data and the original data had similar first-order and second-order properties, including sparsity, diversities, and taxa-taxa correlations. These advantages are suitable for further microbiome methodology development where high-fidelity microbiome data are needed. [ABSTRACT FROM AUTHOR]

Published

2021

8. A deep-learning wind speed interval forecasting architecture based on modified scaling approach with feature ranking and two-output gated recurrent unit.

Author

Wang, Jianzhou, Li, Qiwei, Zhang, Haipeng, and Wang, Ying

Subjects

*WIND speed, *WIND forecasting, *WIND power, *POWER resources, *FORECASTING

Abstract

Wind power is already an indispensable part of the power supply worldwide, for which wind speed forecasting is technically required as essential work to guarantee its safe and economical generation. To date, the majority of wind speed forecasting models only provide deterministic predictions, which, however, fails in accounting for the uncertainty associated with the wind speed that is critical to practice; the current few models attempting to use interval forecasting to address the uncertainty are always plagued by rigorous hypotheses along with the used interval construction approaches and poor interval quality. To fill the gap, a novel interval forecasting architecture has been developed to better capture the uncertainty. It comprises a modified scaling approach, a two-output Gated Recurrent Unit (GRU), and the efficient feature ranking (FR), getting rid of rigorous hypotheses and constructing reliable prediction intervals. The case study based on real wind farm data sheds light on the advantage of the modified scaling approach, as it outperforms many benchmark approaches and conventional scaling approaches by enhancing the coverage width criterion by 4.07% to 97.76% on average. Further embedding the FR and the deep-learning GRU helps in further narrowing the interval width and reducing the interval deviation. [ABSTRACT FROM AUTHOR]

Published

2023

9. A storm in a teacup -- A biomimetic lung microphysiological system in conjunction with a deep-learning algorithm to monitor lung pathological and inflammatory reactions.

Author

Chen, Zaozao, Huang, Jie, Zhang, Jing, Xu, Zikang, Li, Qiwei, Ouyang, Jun, Yan, Yuchuan, Sun, Shiqi, Ye, Huan, Wang, Fei, Zhu, Jianfeng, Wang, Zhangyan, Chao, Jie, Pu, Yuepu, and Gu, Zhongze

Subjects

*LUNGS, *LUNG diseases, *AIR flow, *DEEP learning, *BACTERIAL diseases, *ARTIFICIAL intelligence, *MICROFLUIDICS

Abstract

Creating a biomimetic in vitro lung model to recapitulate the infection and inflammatory reactions has been an important but challenging task for biomedical researchers. The 2D based cell culture models – culturing of lung epithelium – have long existed but lack multiple key physiological conditions, such as the involvement of different types of immune cells and the creation of connected lung models to study viral or bacterial infection between different individuals. Pioneers in organ-on-a-chip research have developed lung alveoli-on-a-chip and connected two lung chips with direct tubing and flow. Although this model provides a powerful tool for lung alveolar disease modeling, it still lacks interactions among immune cells, such as macrophages and monocytes, and the mimic of air flow and aerosol transmission between lung-chips is missing. Here, we report the development of an improved human lung physiological system (Lung-MPS) with both alveolar and pulmonary bronchial chambers that permits the integration of multiple immune cells into the system. We observed amplified inflammatory signals through the dynamic interactions among macrophages, epithelium, endothelium, and circulating monocytes. Furthermore, an integrated microdroplet/aerosol transmission system was fabricated and employed to study the propagation of pseudovirus particles containing microdroplets in integrated Lung-MPSs. Finally, a deep-learning algorithm was developed to characterize the activation of cells in this Lung-MPS. This Lung-MPS could provide an improved and more biomimetic sensory system for the study of COVID-19 and other high-risk infectious lung diseases. • An automatic Lung-MPS for lung pathological and inflammatory reaction studies. • Introduce immune cells into the micro-system to amplify inflammatory reaction. • Artificial intelligence software with deep-learning algorithms to characterize cell activation. • Achieving real-time "deep-learning based" automated identification of the tissue inflammation. • Successfully monitored the upstream chips induced inflammation in downstream chips. [ABSTRACT FROM AUTHOR]

Published

2023