Your search keyword '"Sha, Quiying"' showing total 3 results

1. A new method using deep learning to predict the response to cardiac resynchronization therapy

Author

Larsena, Kristoffer, He, Zhuo, Zhao, Chen, Zhang, Xinwei, Sha, Quiying, Mesquitad, Claudio T, Paeze, Diana, Garciaf, Ernest V., Zou, Jiangang, Peix, Amalia, and Zhou, Weihua

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Background. Clinical parameters measured from gated single-photon emission computed tomography myocardial perfusion imaging (SPECT MPI) have value in predicting cardiac resynchronization therapy (CRT) patient outcomes, but still show limitations. The purpose of this study is to combine clinical variables, features from electrocardiogram (ECG), and parameters from assessment of cardiac function with polarmaps from gated SPECT MPI through deep learning (DL) to predict CRT response. Methods. 218 patients who underwent rest gated SPECT MPI were enrolled in this study. CRT response was defined as an increase in left ventricular ejection fraction (LVEF) > 5% at a 6-month follow up. A DL model was constructed by combining a pre-trained VGG16 module and a multilayer perceptron. Two modalities of data were input to the model: polarmap images from SPECT MPI and tabular data from clinical features and ECG parameters. Gradient-weighted Class Activation Mapping (Grad-CAM) was applied to the VGG16 module to provide explainability for the polarmaps. For comparison, four machine learning (ML) models were trained using only the tabular features. Results. Modeling was performed on 218 patients who underwent CRT implantation with a response rate of 55.5% (n = 121). The DL model demonstrated average AUC (0.83), accuracy (0.73), sensitivity (0.76), and specificity (0.69) surpassing the ML models and guideline criteria. Guideline recommendations presented accuracy (0.53), sensitivity (0.75), and specificity (0.26). Conclusions. The DL model outperformed the ML models, showcasing the additional predictive benefit of utilizing SPECT MPI polarmaps. Incorporating additional patient data directly in the form of medical imagery can improve CRT response prediction.

Published

2023

2. Multistage designs in the genomic era: providing balance in complex disease studies

Author

Dubé, Marie-Pierre, Schmidt, Silke, Hauser, Elizabeth, Darabi, Hatef, Li, Jing, Barhdadi, Amina, Wang, Xuexia, Sha, Quiying, Zhang, Zhaogong, Wang, Tao, Aschard, Hugues, Guedj, Mickael, Rohlfs, Rori, Anderson, Amy, Taylor, Chelsea, Mirea, Lucia, Nickolov, Radoslav, Milanov, Valentin, Yang, Hsin-Chao, Song, Yeunjoo, Sinha, Ritwik, Department of Statistical Genetics, Université de Montréal (UdeM)-Research Centre of the Montreal Heart Institute, Department of Medicine, Center for Human Genetics-Duke University Medical Center, Méthodologie statistique et épidémiologie génétique de maladies multifactorielles, Université d'Évry-Val-d'Essonne (UEVE)-Institut National de la Santé et de la Recherche Médicale (INSERM), and Hugues, Aschard

Subjects

Operations research, Epidemiology, Computer science, Complex disease, [SDV.GEN] Life Sciences [q-bio]/Genetics, Joint analysis, Machine learning, computer.software_genre, MESH: Phenotype, Statistical power, Article, Humans, MESH: Models, Genetic, Genetics (clinical), MESH: Genome, Human, Genetic complexity, Power loss, [SDV.GEN]Life Sciences [q-bio]/Genetics, MESH: Humans, Models, Genetic, business.industry, Genome, Human, MESH: Research Design, Model complexity, Replication (computing), Range (mathematics), Phenotype, Research Design, Artificial intelligence, business, computer

Abstract

International audience; In this summary paper, we describe the contributions included in the Multistage Design group (Group 14) at the Genetic Analysis Workshop 15, which was held during November 12-14, 2006. Our group contrasted and compared different approaches to reducing complexity in a genetic study through implementation of staged designs. Most groups used the simulated dataset (problem 3), which provided ample opportunities for evaluating various staged designs. A wide range of multistage designs that targeted different aspects of complexity were explored. We categorized these approaches as reducing phenotypic complexity, model complexity, analytic complexity or genetic complexity. In general we learned that: (1) when staged designs are carefully planned and implemented, the power loss compared to a single-stage analysis can be minimized and study cost is greatly reduced; (2) a joint analysis of the results from each stage is generally more powerful than treating the second stage as a replication analysis.

Published

2007

3. Multistage designs in the genomic era: providing balance in complex disease studies.

Author

Dubé MP, Schmidt S, Hauser E, Darabi H, Li J, Barhdadi A, Wang X, Sha Q, Zhang Z, Wang T, Aschard H, Guedj M, Rohlfs R, Anderson A, Taylor C, Mirea L, Nickolov R, Milanov V, Yang HC, Song Y, and Sinha R

Subjects

Humans, Models, Genetic, Phenotype, Research Design, Genome, Human

Abstract

In this summary paper, we describe the contributions included in the Multistage Design group (Group 14) at the Genetic Analysis Workshop 15, which was held during November 12-14, 2006. Our group contrasted and compared different approaches to reducing complexity in a genetic study through implementation of staged designs. Most groups used the simulated dataset (problem 3), which provided ample opportunities for evaluating various staged designs. A wide range of multistage designs that targeted different aspects of complexity were explored. We categorized these approaches as reducing phenotypic complexity, model complexity, analytic complexity or genetic complexity. In general we learned that: (1) when staged designs are carefully planned and implemented, the power loss compared to a single-stage analysis can be minimized and study cost is greatly reduced; (2) a joint analysis of the results from each stage is generally more powerful than treating the second stage as a replication analysis., ((c) 2007 Wiley-Liss, Inc.)

Published

2007