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1. A Privacy-Preserving Domain Adversarial Federated learning for multi-site brain functional connectivity analysis

Author

Zhang, Yipu, Wang, Likai, Su, Kuan-Jui, Zhang, Aiying, Zhu, Hao, Liu, Xiaowen, Shen, Hui, Calhoun, Vince D., Wang, Yuping, and Deng, Hongwen

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Electrical Engineering and Systems Science - Image and Video Processing
Abstract

Resting-state functional magnetic resonance imaging (rs-fMRI) and its derived functional connectivity networks (FCNs) have become critical for understanding neurological disorders. However, collaborative analyses and the generalizability of models still face significant challenges due to privacy regulations and the non-IID (non-independent and identically distributed) property of multiple data sources. To mitigate these difficulties, we propose Domain Adversarial Federated Learning (DAFed), a novel federated deep learning framework specifically designed for non-IID fMRI data analysis in multi-site settings. DAFed addresses these challenges through feature disentanglement, decomposing the latent feature space into domain-invariant and domain-specific components, to ensure robust global learning while preserving local data specificity. Furthermore, adversarial training facilitates effective knowledge transfer between labeled and unlabeled datasets, while a contrastive learning module enhances the global representation of domain-invariant features. We evaluated DAFed on the diagnosis of ASD and further validated its generalizability in the classification of AD, demonstrating its superior classification accuracy compared to state-of-the-art methods. Additionally, an enhanced Score-CAM module identifies key brain regions and functional connectivity significantly associated with ASD and MCI, respectively, uncovering shared neurobiological patterns across sites. These findings highlight the potential of DAFed to advance multi-site collaborative research in neuroimaging while protecting data confidentiality., Comment: 34pages, 13 figures

Published
2025

2. A Staged Approach using Machine Learning and Uncertainty Quantification to Predict the Risk of Hip Fracture

Author

Shaik, Anjum, Larsen, Kristoffer, Lane, Nancy E., Zhao, Chen, Su, Kuan-Jui, Keyak, Joyce H., Tian, Qing, Sha, Qiuying, Shen, Hui, Deng, Hong-Wen, and Zhou, Weihua

Subjects
Physics - Medical Physics, Computer Science - Machine Learning
Abstract

Despite advancements in medical care, hip fractures impose a significant burden on individuals and healthcare systems. This paper focuses on the prediction of hip fracture risk in older and middle-aged adults, where falls and compromised bone quality are predominant factors. We propose a novel staged model that combines advanced imaging and clinical data to improve predictive performance. By using CNNs to extract features from hip DXA images, along with clinical variables, shape measurements, and texture features, our method provides a comprehensive framework for assessing fracture risk. A staged machine learning-based model was developed using two ensemble models: Ensemble 1 (clinical variables only) and Ensemble 2 (clinical variables and DXA imaging features). This staged approach used uncertainty quantification from Ensemble 1 to decide if DXA features are necessary for further prediction. Ensemble 2 exhibited the highest performance, achieving an AUC of 0.9541, an accuracy of 0.9195, a sensitivity of 0.8078, and a specificity of 0.9427. The staged model also performed well, with an AUC of 0.8486, an accuracy of 0.8611, a sensitivity of 0.5578, and a specificity of 0.9249, outperforming Ensemble 1, which had an AUC of 0.5549, an accuracy of 0.7239, a sensitivity of 0.1956, and a specificity of 0.8343. Furthermore, the staged model suggested that 54.49% of patients did not require DXA scanning. It effectively balanced accuracy and specificity, offering a robust solution when DXA data acquisition is not always feasible. Statistical tests confirmed significant differences between the models, highlighting the advantages of the advanced modeling strategies. Our staged approach could identify individuals at risk with a high accuracy but reduce the unnecessary DXA scanning. It has great promise to guide interventions to prevent hip fractures with reduced cost and radiation., Comment: 29 pages, 5 figures, 6 tables

Published
2024

3. Multi-View Variational Autoencoder for Missing Value Imputation in Untargeted Metabolomics

Author

Zhao, Chen, Su, Kuan-Jui, Wu, Chong, Cao, Xuewei, Sha, Qiuying, Li, Wu, Luo, Zhe, Qin, Tian, Qiu, Chuan, Zhao, Lan Juan, Liu, Anqi, Jiang, Lindong, Zhang, Xiao, Shen, Hui, Zhou, Weihua, and Deng, Hong-Wen

Subjects
Quantitative Biology - Genomics, Computer Science - Information Retrieval, Computer Science - Machine Learning, Statistics - Applications
Abstract

Background: Missing data is a common challenge in mass spectrometry-based metabolomics, which can lead to biased and incomplete analyses. The integration of whole-genome sequencing (WGS) data with metabolomics data has emerged as a promising approach to enhance the accuracy of data imputation in metabolomics studies. Method: In this study, we propose a novel method that leverages the information from WGS data and reference metabolites to impute unknown metabolites. Our approach utilizes a multi-view variational autoencoder to jointly model the burden score, polygenetic risk score (PGS), and linkage disequilibrium (LD) pruned single nucleotide polymorphisms (SNPs) for feature extraction and missing metabolomics data imputation. By learning the latent representations of both omics data, our method can effectively impute missing metabolomics values based on genomic information. Results: We evaluate the performance of our method on empirical metabolomics datasets with missing values and demonstrate its superiority compared to conventional imputation techniques. Using 35 template metabolites derived burden scores, PGS and LD-pruned SNPs, the proposed methods achieved R^2-scores > 0.01 for 71.55% of metabolites. Conclusion: The integration of WGS data in metabolomics imputation not only improves data completeness but also enhances downstream analyses, paving the way for more comprehensive and accurate investigations of metabolic pathways and disease associations. Our findings offer valuable insights into the potential benefits of utilizing WGS data for metabolomics data imputation and underscore the importance of leveraging multi-modal data integration in precision medicine research., Comment: 19 pages, 3 figures

Published
2023

4. Somatomotor-Visual Resting State Functional Connectivity Increases After Two Years in the UK Biobank Longitudinal Cohort

Author

Orlichenko, Anton, Su, Kuan-Jui, Tian, Qing, Shen, Hui, Deng, Hong-Wen, and Wang, Yu-Ping

Subjects
Quantitative Biology - Neurons and Cognition
Abstract

Purpose: Functional magnetic resonance imaging (fMRI) and functional connectivity (FC) have been used to follow aging in both children and older adults. Robust changes have been observed in children, where high connectivity among all brain regions changes to a more modular structure with maturation. In this work, we examine changes in FC in older adults after two years of aging in the UK Biobank longitudinal cohort. Approach: We process data using the Power264 atlas, then test whether FC changes in the 2,722-subject longitudinal cohort are statistically significant using a Bonferroni-corrected t-test. We also compare the ability of Power264 and UKB-provided, ICA-based FC to determine which of a longitudinal scan pair is older. Results: We find a 6.8\% average increase in SMT-VIS connectivity from younger to older scan (from $\rho=0.39$ to $\rho=0.42$) that occurs in male, female, older subject ($>65$ years old), and younger subject ($<55$ years old) groups. Among all inter-network connections, this average SMT-VIS connectivity is the best predictor of relative scan age, accurately predicting which scan is older 57\% of the time. Using the full FC and a training set of 2,000 subjects, one is able to predict which scan is older 82.5\% of the time using either the full Power264 FC or the UKB-provided ICA-based FC. Conclusions: We conclude that SMT-VIS connectivity increases in the longitudinal cohort, while resting state FC increases generally with age in the cross-sectional cohort. However, we consider the possibility of a change in resting state scanner task between UKB longitudinal data acquisitions., Comment: 11 pages, 12 figures, 4 tables

Published
2023

5. Identifiability in Functional Connectivity May Unintentionally Inflate Prediction Results

Author

Orlichenko, Anton, Qu, Gang, Su, Kuan-Jui, Liu, Anqi, Shen, Hui, Deng, Hong-Wen, and Wang, Yu-Ping

Subjects
Quantitative Biology - Neurons and Cognition, Quantitative Biology - Quantitative Methods
Abstract

Functional magnetic resonance (fMRI) is an invaluable tool in studying cognitive processes in vivo. Many recent studies use functional connectivity (FC), partial correlation connectivity (PC), or fMRI-derived brain networks to predict phenotypes with results that sometimes cannot be replicated. At the same time, FC can be used to identify the same subject from different scans with great accuracy. In this paper, we show a method by which one can unknowingly inflate classification results from 61% accuracy to 86% accuracy by treating longitudinal or contemporaneous scans of the same subject as independent data points. Using the UK Biobank dataset, we find one can achieve the same level of variance explained with 50 training subjects by exploiting identifiability as with 10,000 training subjects without double-dipping. We replicate this effect in four different datasets: the UK Biobank (UKB), the Philadelphia Neurodevelopmental Cohort (PNC), the Bipolar and Schizophrenia Network for Intermediate Phenotypes (BSNIP), and an OpenNeuro Fibromyalgia dataset (Fibro). The unintentional improvement ranges between 7% and 25% in the four datasets. Additionally, we find that by using dynamic functional connectivity (dFC), one can apply this method even when one is limited to a single scan per subject. One major problem is that features such as ROIs or connectivities that are reported alongside inflated results may confuse future work. This article hopes to shed light on how even minor pipeline anomalies may lead to unexpectedly superb results., Comment: 8 pages, 11 with references

Published
2023

6. Multi-view information fusion using multi-view variational autoencoder to predict proximal femoral fracture load

Author

Zhao, Chen, Keyak, Joyce H, Cao, Xuewei, Sha, Qiuying, Wu, Li, Luo, Zhe, Zhao, Lan-Juan, Tian, Qing, Serou, Michael, Qiu, Chuan, Su, Kuan-Jui, Shen, Hui, Deng, Hong-Wen, and Zhou, Weihua

Subjects
Biomedical and Clinical Sciences, Clinical Sciences, Bioengineering, Biomedical Imaging, Human Genome, Physical Injury - Accidents and Adverse Effects, Osteoporosis, Genetics, Networking and Information Technology R&D (NITRD), 4.2 Evaluation of markers and technologies, Musculoskeletal, Humans, Male, Genome-Wide Association Study, Proximal Femoral Fractures, Absorptiometry, Photon, Hip Fractures, hip fracture, proximal femur, finite element analysis, deep learning, variational autoencoder, Nutrition and Dietetics, Clinical sciences
Abstract

BackgroundHip fracture occurs when an applied force exceeds the force that the proximal femur can support (the fracture load or "strength") and can have devastating consequences with poor functional outcomes. Proximal femoral strengths for specific loading conditions can be computed by subject-specific finite element analysis (FEA) using quantitative computerized tomography (QCT) images. However, the radiation and availability of QCT limit its clinical usability. Alternative low-dose and widely available measurements, such as dual energy X-ray absorptiometry (DXA) and genetic factors, would be preferable for bone strength assessment. The aim of this paper is to design a deep learning-based model to predict proximal femoral strength using multi-view information fusion.ResultsWe developed new models using multi-view variational autoencoder (MVAE) for feature representation learning and a product of expert (PoE) model for multi-view information fusion. We applied the proposed models to an in-house Louisiana Osteoporosis Study (LOS) cohort with 931 male subjects, including 345 African Americans and 586 Caucasians. We performed genome-wide association studies (GWAS) to select 256 genetic variants with the lowest p-values for each proximal femoral strength and integrated whole genome sequence (WGS) features and DXA-derived imaging features to predict proximal femoral strength. The best prediction model for fall fracture load was acquired by integrating WGS features and DXA-derived imaging features. The designed models achieved the mean absolute percentage error of 18.04%, 6.84% and 7.95% for predicting proximal femoral fracture loads using linear models of fall loading, nonlinear models of fall loading, and nonlinear models of stance loading, respectively.ConclusionThe proposed models are capable of predicting proximal femoral strength using WGS features and DXA-derived imaging features. Though this tool is not a substitute for predicting FEA using QCT images, it would make improved assessment of hip fracture risk more widely available while avoiding the increased radiation exposure from QCT.

Published
2023

8. Variability in performance of genetic-enhanced DXA-BMD prediction models across diverse ethnic and geographic populations: A risk prediction study

Author

Liu, Yong, Meng, Xiang-He, Wu, Chong, Su, Kuan-Jui, Liu, Anqi, Tian, Qing, Zhao, Lan-Juan, Qiu, Chuan, Luo, Zhe, Gonzalez-Ramirez, Martha I, Shen, Hui, Xiao, Hong-Mei, and Deng, Hong-Wen

Subjects
Social aspects, Usage, Models, Measurement, Genetic aspects, Bone densitometry -- Usage -- Social aspects, Bone density -- Models -- Measurement -- Genetic aspects, Genes -- Usage, Medical research, Biological models -- Social aspects -- Usage, Medicine, Experimental, Bones -- Density
Abstract

Author(s): Yong Liu 1, Xiang-He Meng 2, Chong Wu 3, Kuan-Jui Su 4, Anqi Liu 4, Qing Tian 4, Lan-Juan Zhao 4, Chuan Qiu 4, Zhe Luo 4, Martha I [...], Background Osteoporosis is a major global health issue, weakening bones and increasing fracture risk. Dual-energy X-ray absorptiometry (DXA) is the standard for measuring bone mineral density (BMD) and diagnosing osteoporosis, but its costliness and complexity impede widespread screening adoption. Predictive modeling using genetic and clinical data offers a cost-effective alternative for assessing osteoporosis and fracture risk. This study aims to develop BMD prediction models using data from the UK Biobank (UKBB) and test their performance across different ethnic and geographical populations. Methods and findings We developed BMD prediction models for the femoral neck (FNK) and lumbar spine (SPN) using both genetic variants and clinical factors (such as sex, age, height, and weight), within 17,964 British white individuals from UKBB. Models based on regression with least absolute shrinkage and selection operator (LASSO), selected based on the coefficient of determination (R.sup.2) from a model selection subset of 5,973 individuals from British white population. These models were tested on 5 UKBB test sets and 12 independent cohorts of diverse ancestries, totaling over 15,000 individuals. Furthermore, we assessed the correlation of predicted BMDs with fragility fractures risk in 10 years in a case-control set of 287,183 European white participants without DXA-BMDs in the UKBB. With single-nucleotide polymorphism (SNP) inclusion thresholds at 5x10.sup.-6 and 5x10.sup.-7, the prediction models for FNK-BMD and SPN-BMD achieved the highest R.sup.2 of 27.70% with a 95% confidence interval (CI) of [27.56%, 27.84%] and 48.28% (95% CI [48.23%, 48.34%]), respectively. Adding genetic factors improved predictions slightly, explaining an additional 2.3% variation for FNK-BMD and 3% for SPN-BMD over clinical factors alone. Survival analysis revealed that the predicted FNK-BMD and SPN-BMD were significantly associated with fragility fracture risk in the European white population (P < 0.001). The hazard ratios (HRs) of the predicted FNK-BMD and SPN-BMD were 0.83 (95% CI [0.79, 0.88], corresponding to a 1.44% difference in 10-year absolute risk) and 0.72 (95% CI [0.68, 0.76], corresponding to a 1.64% difference in 10-year absolute risk), respectively, indicating that for every increase of one standard deviation in BMD, the fracture risk will decrease by 17% and 28%, respectively. However, the model&apos;s performance declined in other ethnic groups and independent cohorts. The limitations of this study include differences in clinical factors distribution and the use of only SNPs as genetic factors. Conclusions In this study, we observed that combining genetic and clinical factors improves BMD prediction compared to clinical factors alone. Adjusting inclusion thresholds for genetic variants (e.g., 5x10.sup.-6 or 5x10.sup.-7) rather than solely considering genome-wide association study (GWAS)-significant variants can enhance the model&apos;s explanatory power. The study highlights the need for training models on diverse populations to improve predictive performance across various ethnic and geographical groups.

Published
2024
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11. Gut microbiota impacts bone via Bacteroides vulgatus-valeric acid-related pathways

Author

Lin, Xu, Xiao, Hong-Mei, Liu, Hui-Min, Lv, Wan-Qiang, Greenbaum, Jonathan, Gong, Rui, Zhang, Qiang, Chen, Yuan-Cheng, Peng, Cheng, Xu, Xue-Juan, Pan, Dao-Yan, Chen, Zhi, Li, Zhang-Fang, Zhou, Rou, Wang, Xia-Fang, Lu, Jun-Min, Ao, Zeng-Xin, Song, Yu-Qian, Zhang, Yin-Hua, Su, Kuan-Jui, Meng, Xiang-He, Ge, Chang-Li, Lv, Feng-Ye, Luo, Zhe, Shi, Xing-Ming, Zhao, Qi, Guo, Bo-Yi, Yi, Neng-Jun, Shen, Hui, Papasian, Christopher J., Shen, Jie, and Deng, Hong-Wen

Published
2023
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14. Genomic structural variations link multiple genes to bone mineral density in a multi-ethnic cohort study: Louisiana osteoporosis study.

Author

Su, Kuan-Jui, Qiu, Chuan, Greenbaum, Jonathan, Zhang, Xiao, Liu, Anqi, Liu, Yong, Luo, Zhe, Mungasavalli Gnanesh, Shashank Sajjan, Tian, Qing, Zhao, Lan-Juan, Shen, Hui, and Deng, Hong-Wen

Abstract

Osteoporosis, characterized by low BMD, is a highly heritable metabolic bone disorder. Although single nucleotide variations (SNVs) have been extensively studied, they explain only a fraction of BMD heritability. Although genomic structural variations (SVs) are large-scale genomic alterations that contribute to genetic diversity in shaping phenotypic variations, the role of SVs in osteoporosis susceptibility remains poorly understood. This study aims to identify and prioritize genes that harbor BMD-related SVs. We performed whole genome sequencing on 4982 subjects from the Louisiana Osteoporosis Study. To obtain high-confidence SVs, the detection of SVs was performed using an ensemble approach. The SVs were tested for association with BMD variation at the hip (HIP), femoral neck (FNK), and lumbar spine (SPN), respectively. Additionally, we conducted co-occurrence analysis using multi-omics approaches to prioritize the identified genes based on their functional importance. Stratification was employed to explore the sex- and ethnicity-specific effects. We identified significant SV-BMD associations: 125 for FNK-BMD, 99 for SPN-BMD, and 83 for HIP-BMD. We observed SVs that were commonly associated with both FNK and HIP BMDs in our combined and stratified analyses. These SVs explain 13.3% to 19.1% of BMD variation. Novel bone-related genes emerged, including LINC02370, ZNF family genes, and ZDHHC family genes. Additionally, FMN2, carrying BMD-related deletions, showed associations with FNK or HIP BMDs, with sex-specific effects. The co-occurrence analysis prioritized an RNA gene LINC00494 and ZNF family genes positively associated with BMDs at different skeletal sites. Two potential causal genes, IBSP and SPP1, for osteoporosis were also identified. Our study uncovers new insights into genetic factors influencing BMD through SV analysis. We highlight BMD-related SVs, revealing a mix of shared and specific genetic influences across skeletal sites and gender or ethnicity. These findings suggest potential roles in osteoporosis pathophysiology, opening avenues for further research and therapeutic targets. [ABSTRACT FROM AUTHOR]

Published
2024
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15. Identification of the serum metabolites associated with cow milk consumption in Chinese Peri-/Postmenopausal women.

Author

Tian, Bo, Xu, Lu-Lu, Jiang, Lin-Dong, Lin, Xu, Shen, Jie, Shen, Hui, Su, Kuan-Jui, Gong, Rui, Qiu, Chuan, Luo, Zhe, Yao, Jia-Heng, Wang, Zhuo-Qi, Xiao, Hong-Mei, Zhang, Li-Shu, and Deng, Hong-Wen

Subjects
PARTIAL least squares regression, MILK consumption, DISCRIMINANT analysis, BREAST milk, GUT microbiome
Abstract

Cow milk consumption (CMC) and downstream alterations of serum metabolites are commonly considered important factors regulating human health status. Foods may lead to metabolic changes directly or indirectly through remodelling gut microbiota (GM). We sought to identify the metabolic alterations in Chinese Peri-/Postmenopausal women with habitual CMC and explore if the GM mediates the CMC-metabolite associations. 346 Chinese Peri-/Postmenopausal women participants were recruited in this study. Fixed effects regression and partial least squares discriminant analysis (PLS-DA) were applied to reveal alterations of serum metabolic features in different CMC groups. Spearman correlation coefficient was computed to detect metabolome-metagenome association. 36 CMC-associated metabolites including palmitic acid (FA(16:0)), 7alpha-hydroxy-4-cholesterin-3-one (7alphaC4), citrulline were identified by both fixed effects regression (FDR < 0.05) and PLS-DA (VIP score > 2). Some significant metabolite-GM associations were observed, including FA(16:0) with gut species Bacteroides ovatus, Bacteroides sp.D2. These findings would further prompt our understanding of the effect of cow milk on human health. [ABSTRACT FROM AUTHOR]

Published
2024
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18. Multi-view information fusion using multi-view variational autoencoder to predict proximal femoral fracture load

Author

Zhao, Chen, primary, Keyak, Joyce H., additional, Cao, Xuewei, additional, Sha, Qiuying, additional, Wu, Li, additional, Luo, Zhe, additional, Zhao, Lan-Juan, additional, Tian, Qing, additional, Serou, Michael, additional, Qiu, Chuan, additional, Su, Kuan-Jui, additional, Shen, Hui, additional, Deng, Hong-Wen, additional, and Zhou, Weihua, additional

Published
2023
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19. Metabolomic profiles associated with physical activity in White and African American adult men

Author

Du, Yan, primary, Li, Yuan-Yuan, additional, Choi, Byeong Yeob, additional, Fernadez, Roman, additional, Su, Kuan-Jui, additional, Sharma, Kumar, additional, Qi, Lu, additional, Yin, Zenong, additional, Zhao, Qi, additional, Shen, Hui, additional, Qiu, Chuan, additional, Zhao, Lan-Juan, additional, Luo, Zhe, additional, Wu, Li, additional, Tian, Qing, additional, and Deng, Hong-Wen, additional

Published
2023
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24. Systematic metabolomic studies identified adult adiposity biomarkers with acetylglycine associated with fat loss in vivo

Author

Su, Kuan-Jui, primary, Chen, Xing-Ying, additional, Gong, Rui, additional, Zhao, Qi, additional, Hu, Shi-Di, additional, Feng, Mei-Chen, additional, Li, Ye, additional, Lin, Xu, additional, Zhang, Yin-Hua, additional, Greenbaum, Jonathan, additional, Tian, Qing, additional, Shen, Hui, additional, Xiao, Hong-Mei, additional, Shen, Jie, additional, and Deng, Hong-Wen, additional

Published
2023
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27. An autoencoder-based deep learning method for genotype imputation

Author

Song, Meng, primary, Greenbaum, Jonathan, additional, Luttrell, Joseph, additional, Zhou, Weihua, additional, Wu, Chong, additional, Luo, Zhe, additional, Qiu, Chuan, additional, Zhao, Lan Juan, additional, Su, Kuan-Jui, additional, Tian, Qing, additional, Shen, Hui, additional, Hong, Huixiao, additional, Gong, Ping, additional, Shi, Xinghua, additional, Deng, Hong-Wen, additional, and Zhang, Chaoyang, additional

Published
2022
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31. Enhanced Identification of Novel Potential Variants for Appendicular Lean Mass by Leveraging Pleiotropy With Bone Mineral Density

Author

Peng, Cheng, primary, Liu, Feng, additional, Su, Kuan-Jui, additional, Lin, Xu, additional, Song, Yu-Qian, additional, Shen, Jie, additional, Hu, Shi-Di, additional, Chen, Qiao-Cong, additional, Yuan, Hui-Hui, additional, Li, Wen-Xi, additional, Zeng, Chun-Ping, additional, Deng, Hong-Wen, additional, and Lou, Hui-Ling, additional

Published
2021
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32. Identification and Functional Characterization of Metabolites for Bone Mass in Peri- and Postmenopausal Chinese Women

Author

Gong, Rui, primary, Xiao, Hong-Mei, additional, Zhang, Yin-Hua, additional, Zhao, Qi, additional, Su, Kuan-Jui, additional, Lin, Xu, additional, Mo, Cheng-Lin, additional, Zhang, Qiang, additional, Du, Ya-Ting, additional, Lyu, Feng-Ye, additional, Chen, Yuan-Cheng, additional, Peng, Cheng, additional, Liu, Hui-Min, additional, Hu, Shi-Di, additional, Pan, Dao-Yan, additional, Chen, Zhi, additional, Li, Zhang-Fang, additional, Zhou, Rou, additional, Wang, Xia-Fang, additional, Lu, Jun-Min, additional, Ao, Zeng-Xin, additional, Song, Yu-Qian, additional, Weng, Chan-Yan, additional, Tian, Qing, additional, Schiller, Martin R, additional, Papasian, Christopher J, additional, Brotto, Marco, additional, Shen, Hui, additional, Shen, Jie, additional, and Deng, Hong-Wen, additional

Published
2021
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35. Gut microbiota impacts bone via B.vulgatus-valeric acid-related pathways

Author

Lin, Xu, primary, Xiao, Hong-Mei, additional, Liu, Hui-Min, additional, Lv, Wan-Qiang, additional, Greenbaum, Jonathan, additional, Yuan, Si-Jie, additional, Gong, Rui, additional, Zhang, Qiang, additional, Chen, Yuan-Cheng, additional, Peng, Cheng, additional, Xu, Xue-Juan, additional, Pan, Dao-Yan, additional, Chen, Zhi, additional, Li, Zhang-Fang, additional, Zhou, Rou, additional, Wang, Xia-Fang, additional, Lu, Jun-Min, additional, Ao, Zeng-Xin, additional, Song, Yu-Qian, additional, Zhang, Yin-Hua, additional, Su, Kuan-Jui, additional, Meng, Xiang-He, additional, Ge, Chang-Li, additional, Lv, Feng-Ye, additional, Shi, Xing-Ming, additional, Zhao, Qi, additional, Guo, Bo-Yi, additional, Yi, Neng-Jun, additional, Shen, Hui, additional, Papasian, Christopher J., additional, Shen, Jie, additional, and Deng, Hong-Wen, additional

Published
2020
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37. Gene Expression and RNA Splicing Imputation Identifies Novel Candidate Genes Associated with Osteoporosis.

Author

Yong Liu, Hui Shen, Greenbaum, Jonathan, Anqi Liu, Kuan-Jui Su, Li-Shu Zhang, Lei Zhang, Qing Tian, Hong-Gang Hu, Jin-Sheng He, Hong-Wen Deng, Liu, Yong, Shen, Hui, Liu, Anqi, Su, Kuan-Jui, Zhang, Li-Shu, Zhang, Lei, Tian, Qing, Hu, Hong-Gang, and He, Jin-Sheng

Subjects
BONE density, RNA splicing, GENE expression, ADIPOSE tissues, OVARIAN reserve, GENES, GENETIC regulation, OSTEOPOROSIS, RNA, GENE expression profiling, MOLECULAR structure, GENETIC techniques
Abstract

Context: Though genome-wide association studies (GWASs) have identified hundreds of genetic variants associated with osteoporosis related traits, such as bone mineral density (BMD) and fracture, it remains a challenge to interpret their biological functions and underlying biological mechanisms.Objective: Integrate diverse expression quantitative trait loci and splicing quantitative trait loci data with several powerful GWAS datasets to identify novel candidate genes associated with osteoporosis.Design, Setting, and Participants: Here, we conducted a transcriptome-wide association study (TWAS) for total body BMD (TB-BMD) (n = 66 628 for discovery and 7697 for validation) and fracture (53 184 fracture cases and 373 611 controls for discovery and 37 857 cases and 227 116 controls for validation), respectively. We also conducted multi-SNP-based summarized mendelian randomization analysis to further validate our findings.Results: In total, we detected 88 genes significantly associated with TB-BMD or fracture through expression or ribonucleic acid splicing. Summarized mendelian randomization analysis revealed that 78 of the significant genes may have potential causal effects on TB-BMD or fracture in at least 1 specific tissue. Among them, 64 genes have been reported in previous GWASs or TWASs for osteoporosis, such as ING3, CPED1, and WNT16, as well as 14 novel genes, such as DBF4B, GRN, TMUB2, and UNC93B1.Conclusions: Overall, our findings provide novel insights into the pathogenesis mechanisms of osteoporosis and highlight the power of a TWAS to identify and prioritize potential causal genes. [ABSTRACT FROM AUTHOR]

Published
2020
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40. An atlas of genetic effects on the monocyte methylome across European and African populations.

Author

Zhang W, Zhang X, Qiu C, Zhang Z, Su KJ, Luo Z, Liu M, Zhao B, Wu L, Tian Q, Shen H, Wu C, and Deng HW

Abstract

Elucidating the genetic architecture of DNA methylation is crucial for decoding complex disease etiology. However, current epigenomic studies are often limited by incomplete methylation coverage and heterogeneous tissue samples. Here, we present the first comprehensive, multi-ancestry human methylome atlas of purified human monocytes, generated through integrated whole-genome bisulfite sequencing and whole-genome sequencing from 298 European Americans (EA) and 160 African Americans (AA). By analyzing over 25 million methylation sites, we identified 1,383,250 and 1,721,167 methylation quantitative trait loci (meQTLs) in cis- regions for EA and AA populations, respectively, revealing both shared (880,108 sites) and population-specific regulatory patterns. Furthermore, we developed population-specific DNAm imputation models, enabling methylome-wide association studies (MWAS) for 1,976,046 and 2,657,581 methylation sites in EA and AA, respectively. These models were validated through multi-ancestry analysis of 41 complex traits from the Million Veteran Program. The identified meQTLs, MWAS models, and data resources are freely available at www.gcbhub.org and https://osf.io/gct57/ .

Published
2024
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41. Multi-View Integrative Approach For Imputing Short-Chain Fatty Acids and Identifying Key factors predicting Blood SCFA.

Author

Liu A, Tian B, Qiu C, Su KJ, Jiang L, Zhao C, Song M, Liu Y, Qu G, Zhou Z, Zhang X, Gnanesh SSM, Thumbigere-Math V, Luo Z, Tian Q, Zhang LS, Wu C, Ding Z, Shen H, and Deng HW

Abstract

Short-chain fatty acids (SCFAs) are the main metabolites produced by bacterial fermentation of dietary fiber within gastrointestinal tract. SCFAs produced by gut microbiotas (GMs) are absorbed by host, reach bloodstream, and are distributed to different organs, thus influencing host physiology. However, due to the limited budget or the poor sensitivity of instruments, most studies on GMs have incomplete blood SCFA data, limiting our understanding of the metabolic processes within the host. To address this gap, we developed an innovative multi-task multi-view integrative approach (M 2 AE, Multi-task Multi-View Attentive Encoders), to impute blood SCFA levels using gut metagenomic sequencing (MGS) data, while taking into account the intricate interplay among the gut microbiome, dietary features, and host characteristics, as well as the nuanced nature of SCFA dynamics within the body. Here, each view represents a distinct type of data input (i.e., gut microbiome compositions, dietary features, or host characteristics). Our method jointly explores both view-specific representations and cross-view correlations for effective predictions of SCFAs. We applied M 2 AE to two in-house datasets, which both include MGS and blood SCFAs profiles, host characteristics, and dietary features from 964 subjects and 171 subjects, respectively. Results from both of two datasets demonstrated that M 2 AE outperforms traditional regression-based and neural-network based approaches in imputing blood SCFAs. Furthermore, a series of gut bacterial species (e.g., Bacteroides thetaiotaomicron and Clostridium asparagiforme ), host characteristics (e.g., race, gender), as well as dietary features (e.g., intake of fruits, pickles) were shown to contribute greatly to imputation of blood SCFAs. These findings demonstrated that GMs, dietary features and host characteristics might contribute to the complex biological processes involved in blood SCFA productions. These might pave the way for a deeper and more nuanced comprehension of how these factors impact human health.

Published
2024
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42. omicsMIC: a comprehensive benchmarking platform for robust comparison of imputation methods in mass spectrometry-based omics data.

Author

Lin W, Ji J, Su KJ, Qiu C, Tian Q, Zhao LJ, Luo Z, Wu C, Shen H, and Deng H

Abstract

Mass spectrometry is a powerful and widely used tool for generating proteomics, lipidomics and metabolomics profiles, which is pivotal for elucidating biological processes and identifying biomarkers. However, missing values in mass spectrometry-based omics data may pose a critical challenge for the comprehensive identification of biomarkers and elucidation of the biological processes underlying human complex disorders. To alleviate this issue, various imputation methods for mass spectrometry-based omics data have been developed. However, a comprehensive comparison of these imputation methods is still lacking, and researchers are frequently confronted with a multitude of options without a clear rationale for method selection. To address this pressing need, we developed omicsMIC (mass spectrometry-based omics with Missing values Imputation methods Comparison platform), an interactive platform that provides researchers with a versatile framework to evaluate the performance of 28 diverse imputation methods. omicsMIC offers a nuanced perspective, acknowledging the inherent heterogeneity in biological data and the unique attributes of each dataset. Our platform empowers researchers to make data-driven decisions in imputation method selection based on real-time visualizations of the outcomes associated with different imputation strategies. The comprehensive benchmarking and versatility of omicsMIC make it a valuable tool for the scientific community engaged in mass spectrometry-based omics research. omicsMIC is freely available at https://github.com/WQLin8/omicsMIC., Competing Interests: None declared., (© The Author(s) 2024. Published by Oxford University Press on behalf of NAR Genomics and Bioinformatics.)

Published
2024
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43. A Staged Approach using Machine Learning and Uncertainty Quantification to Predict the Risk of Hip Fracture.

Author

Shaik A, Larsen K, Lane NE, Zhao C, Su KJ, Keyak JH, Tian Q, Sha Q, Shen H, Deng HW, and Zhou W

Abstract

Hip fractures present a significant healthcare challenge, especially within aging populations, where they are often caused by falls. These fractures lead to substantial morbidity and mortality, emphasizing the need for timely surgical intervention. Despite advancements in medical care, hip fractures impose a significant burden on individuals and healthcare systems. This paper focuses on the prediction of hip fracture risk in older and middle-aged adults, where falls and compromised bone quality are predominant factors. We propose a novel staged model that combines advanced imaging and clinical data to improve predictive performance. By using convolutional neural networks (CNNs) to extract features from hip DXA images, along with clinical variables, shape measurements, and texture features, our method provides a comprehensive framework for assessing fracture risk. The study cohort included 547 patients, with 94 experiencing hip fracture. A staged machine learning-based model was developed using two ensemble models: Ensemble 1 (clinical variables only) and Ensemble 2 (clinical variables and DXA imaging features). This staged approach used uncertainty quantification from Ensemble 1 to decide if DXA features are necessary for further prediction. Ensemble 2 exhibited the highest performance, achieving an Area Under the Curve (AUC) of 0.9541, an accuracy of 0.9195, a sensitivity of 0.8078, and a specificity of 0.9427. The staged model also performed well, with an AUC of 0.8486, an accuracy of 0.8611, a sensitivity of 0.5578, and a specificity of 0.9249, outperforming Ensemble 1, which had an AUC of 0.5549, an accuracy of 0.7239, a sensitivity of 0.1956, and a specificity of 0.8343. Furthermore, the staged model suggested that 54.49% of patients did not require DXA scanning. It effectively balanced accuracy and specificity, offering a robust solution when DXA data acquisition is not always feasible. Statistical tests confirmed significant differences between the models, highlighting the advantages of the advanced modeling strategies. Our staged approach offers a cost-effective holistic view of patients' health. It could identify individuals at risk with a high accuracy but reduce the unnecessary DXA scanning. Our approach has great promise to guide interventions to prevent hip fractures with reduced cost and radiation., Competing Interests: Conflict of Interest Disclosure Statement All authors declare that there are no conflicts of interest.

Published
2024

44. Multi-View Variational Autoencoder for Missing Value Imputation in Untargeted Metabolomics.

Author

Zhao C, Su KJ, Wu C, Cao X, Sha Q, Li W, Luo Z, Qin T, Qiu C, Zhao LJ, Liu A, Jiang L, Zhang X, Shen H, Zhou W, and Deng HW

Abstract

Background: Missing data is a common challenge in mass spectrometry-based metabolomics, which can lead to biased and incomplete analyses. The integration of whole-genome sequencing (WGS) data with metabolomics data has emerged as a promising approach to enhance the accuracy of data imputation in metabolomics studies., Method: In this study, we propose a novel method that leverages the information from WGS data and reference metabolites to impute unknown metabolites. Our approach utilizes a multi-view variational autoencoder to jointly model the burden score, polygenetic risk score (PGS), and linkage disequilibrium (LD) pruned single nucleotide polymorphisms (SNPs) for feature extraction and missing metabolomics data imputation. By learning the latent representations of both omics data, our method can effectively impute missing metabolomics values based on genomic information., Results: We evaluate the performance of our method on empirical metabolomics datasets with missing values and demonstrate its superiority compared to conventional imputation techniques. Using 35 template metabolites derived burden scores, PGS and LD-pruned SNPs, the proposed methods achieved R 2 -scores > 0.01 for 71.55% of metabolites., Conclusion: The integration of WGS data in metabolomics imputation not only improves data completeness but also enhances downstream analyses, paving the way for more comprehensive and accurate investigations of metabolic pathways and disease associations. Our findings offer valuable insights into the potential benefits of utilizing WGS data for metabolomics data imputation and underscore the importance of leveraging multi-modal data integration in precision medicine research.

Published
2024

45. omicsMIC: a Comprehensive Benchmarking Platform for Robust Comparison of Imputation Methods in Mass Spectrometry-based Omics Data.

Author

Lin W, Ji J, Su KJ, Qiu C, Tian Q, Zhao LJ, Luo Z, Shen H, Wu C, and Deng H

Abstract

Mass spectrometry is a powerful and widely used tool for generating proteomics, lipidomics, and metabolomics profiles, which is pivotal for elucidating biological processes and identifying biomarkers. However, missing values in spectrometry-based omics data may pose a critical challenge for the comprehensive identification of biomarkers and elucidation of the biological processes underlying human complex disorders. To alleviate this issue, various imputation methods for mass spectrometry-based omics data have been developed. However, a comprehensive and systematic comparison of these imputation methods is still lacking, and researchers are frequently confronted with a multitude of options without a clear rationale for method selection. To address this pressing need, we developed omicsMIC (mass spectrometry-based omics with Missing values Imputation methods Comparison platform), an interactive platform that provides researchers with a versatile framework to simulate and evaluate the performance of 28 diverse imputation methods. omicsMIC offers a nuanced perspective, acknowledging the inherent heterogeneity in biological data and the unique attributes of each dataset. Our platform empowers researchers to make data-driven decisions in imputation method selection based on real-time visualizations of the outcomes associated with different imputation strategies. The comprehensive benchmarking and versatility of omicsMIC make it a valuable tool for the scientific community engaged in mass spectrometry-based omics research. OmicsMIC is freely available at https://github.com/WQLin8/omicsMIC., Competing Interests: Conflict of interest statement. None declared.

Published
2023
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46. Somatomotor-Visual Resting State Functional Connectivity Increases After Two Years in the UK Biobank Longitudinal Cohort.

Author

Orlichenko A, Su KJ, Tian Q, Shen H, Deng HW, and Wang YP

Abstract

Purpose: Functional magnetic resonance imaging (fMRI) and functional connectivity (FC) have been used to follow aging in both children and older adults. Robust changes have been observed in children, where high connectivity among all brain regions changes to a more modular structure with maturation. In this work, we examine changes in FC in older adults after two years of aging in the UK Biobank longitudinal cohort., Approach: We process data using the Power264 atlas, then test whether FC changes in the 2,722-subject longitudinal cohort are statistically significant using a Bonferroni-corrected t-test. We also compare the ability of Power264 and UKB-provided, ICA-based FC to determine which of a longitudinal scan pair is older., Results: We find a 6.8% average increase in SMT-VIS connectivity from younger to older scan (from ρ = 0.39 to ρ = 0.42) that occurs in male, female, older subject (> 65 years old), and younger subject (< 55 years old) groups. Among all inter-network connections, this average SMT-VIS connectivity is the best predictor of relative scan age, accurately predicting which scan is older 57% of the time. Using the full FC and a training set of 2,000 subjects, one is able to predict which scan is older 82.5% of the time using either the full Power264 FC or the UKB-provided ICA-based FC., Conclusions: We conclude that SMT-VIS connectivity increases in the longitudinal cohort, while resting state FC increases generally with age in the cross-sectional cohort. However, we consider the possibility of a change in resting state scanner task between UKB longitudinal data acquisitions., Competing Interests: DISCLOSURES The authors have no conflicts of interest to report.

Published
2023

47. Identifiability in Functional Connectivity May Unintentionally Inflate Prediction Results.

Author

Orlichenko A, Qu G, Su KJ, Liu A, Shen H, Deng HW, and Wang YP

Abstract

Functional magnetic resonance (fMRI) is an invaluable tool in studying cognitive processes in vivo. Many recent studies use functional connectivity (FC), partial correlation connectivity (PC), or fMRI-derived brain networks to predict phenotypes with results that sometimes cannot be replicated. At the same time, FC can be used to identify the same subject from different scans with great accuracy. In this paper, we show a method by which one can unknowingly inflate classification results from 61% accuracy to 86% accuracy by treating longitudinal or contemporaneous scans of the same subject as independent data points. Using the UK Biobank dataset, we find one can achieve the same level of variance explained with 50 training subjects by exploiting identifiability as with 10,000 training subjects without double-dipping. We replicate this effect in four different datasets: the UK Biobank (UKB), the Philadelphia Neurodevelopmental Cohort (PNC), the Bipolar and Schizophrenia Network for Intermediate Phenotypes (BSNIP), and an OpenNeuro Fibromyalgia dataset (Fibro). The unintentional improvement ranges between 7% and 25% in the four datasets. Additionally, we find that by using dynamic functional connectivity (dFC), one can apply this method even when one is limited to a single scan per subject. One major problem is that features such as ROIs or connectivities that are reported alongside inflated results may confuse future work. This article hopes to shed light on how even minor pipeline anomalies may lead to unexpectedly superb results.

Published
2023

48. A multiethnic whole genome sequencing study to identify novel loci for bone mineral density.

Author

Greenbaum J, Su KJ, Zhang X, Liu Y, Liu A, Zhao LJ, Luo Z, Tian Q, Shen H, and Deng HW

Subjects
Female, Femur Neck physiology, Humans, Male, Polymorphism, Single Nucleotide genetics, Whole Genome Sequencing, Bone Density genetics, Genome-Wide Association Study
Abstract

At present, there have only been a few DNA sequencing-based studies to explore the genetic determinants of bone mineral density (BMD). We carried out the largest whole genome sequencing analysis to date for femoral neck and spine BMD (n = 4981), with one of the highest average sequencing depths implemented thus far at 22×, in a multiethnic sample (58% Caucasian and 42% African American) from the Louisiana Osteoporosis Study (LOS). The LOS samples were combined with summary statistics from the GEFOS consortium and several independent samples of various ethnicities to perform GWAS meta-analysis (n = 44 506). We identified 31 and 30 genomic risk loci for femoral neck and spine BMD, respectively. The findings substantiate many previously reported susceptibility loci (e.g. WNT16 and ESR1) and reveal several others that are either novel or have not been widely replicated in GWAS for BMD, including two for femoral neck (IGF2 and ZNF423) and one for spine (SIPA1). Although we were not able to uncover ethnicity specific differences in the genetic determinants of BMD, we did identify several loci which demonstrated sex-specific associations, including two for women (PDE4D and PIGN) and three for men (TRAF3IP2, NFIB and LYSMD4). Gene-based rare variant association testing detected MAML2, a regulator of the Notch signaling pathway, which has not previously been suggested, for association with spine BMD. The findings provide novel insights into the pathophysiological mechanisms of osteoporosis., (© The Author(s) 2021. Published by Oxford University Press. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published
2022
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