Welcome to Lijun Cheng Lab

• This repository houses the Lijun Lab website, which is shared among members through Github and hosted by Dr.Lijun Cheng.
• Lab members should keep their own pages current, as well as contribute to the lab news feed and update research themes and study systems as appropriate.

Lijun Cheng Ph.D

01/2018 - present, Assistant Professor, Department of Biomedical Informatics, College of Medicine, Ohio State University (OSU)

• Introduction on OSU webpage
• Contact: 1800 Cannon Drive, Columbus, OH 43210, United State
• Email: lijun.cheng@osumc.edu
• The full journal publication list NCBI MyBibliography
• All papers list on google scholar

AREA OF EXPERTISE

Artificial intelligence in drug discovery and development

• The aim of “precision medicine” is to devise individualized treatment strategies and therapies. Artificial Intelligence (AI) methods play important roles in predicting the efficacy of drugs from clinical study data, based on patient characteristics. Dr. Cheng focuses on AI mathematical methods development that efficiently identify the characteristics relevant to molecular mechanisms of drug resistance, disease progression and an optimal drug recommendation in the disease treatment. Dr.Cheng's work has substantially advanced our understanding of the molecular mechanisms of cancers, neurodegenerative diseases, and other disorders by using AI technology and strategy. With respect to cancer specifically, her research adapts patient genomic feature data to study molecularly characterized tumors as an alternative to traditional histologic identification. The novel AI computational technology will enable to improve drug selection and courses of treatment for different types of cancer patients depending on their specific genetic and genomics variations.

Molecular mechanisms of drug resistance, and efficacy therapeutics to overcome

• Dr.Cheng developed a series of resources and methods to facilitate data mining of drug resistance mechanism and new drug combination from various data sources.
• Dr. Cheng’s pioneering work led to 52 publications in renowned journals, such as Nature genetics(Impact factor:26.7), Advanced Science (Impact factor:16.8, Co-first authors), Molecular Cancer (Impact factor: 25.55), Cancer Research(Impact factor: 12.8, Co-first authors), Oncogene (Impact factor: 9.86), Clinical Pharmacology Therapy (Impact factor: 6.544, Co-first), Cancers (Impact factor: 6.16, co-first author ), Journal of Clinical Immunology( Impact factor:6.780), Journal of biological chemistry (Impact factor: 4.238 ), as well as AI professional journals, such as IEEE Transaction on neural network and learning systems (impact factor: 12.85, Co-first). Neurocomputing (impact factor: 4.38, Co-first), Plos computational biology (impact factor:4.92, Co-first).

Breakthrough

• PDAC_Immune platform optimal target cell prediction to increasing immune therapy activity in pancreatic cancer. Zhang, Zhuangzhuang#, Lijun Cheng#, Jie Li#, Qi Qiao, Anju Karki, Derek B. Allison, Nuha Shaker et al. "Targeting Plk1 sensitizes pancreatic cancer to immune checkpoint therapy." Cancer Research 82, no. 19 (2022):3532-3548. (#Co-first authors, High Impact Factor of 12.8 ) (This study illustrates the molecular mechanism of how how cold effect changes to hot effect to immune PDL1 inhibitor during pancreatic cancer progression. Plk1 inhibitor resistance will cause immune checkpoint gene activated. Combination drug treatment PDL1 inhibitor and plk1 inhibitor can overcome the ‘rewiring’ to stop pancreatic cancer patients'progression)
• XDeath shinyapps cloud for therapeutic target identification. Zhuangzhuang Zhang#, Lijun Cheng #, Qiongsi Zhang, Yifan Kong, Daheng He, Kunyu Li, Matthew Rea, Jianling Wang, Ruixin Wang, Jinghui Liu, Zhiguo Li, Chongli Yuan, Enze Liu, Yvonne N. Fondufe-Mittendorf, Lang Li, Chi Wang and Xiaoqi Liu*. Co-targeting Plk1 and DNMT3a in advanced prostate cancer. Advanced Science. 2021 Jul;8(13):e2101458. doi: 10.1002/advs.202101458. (#Co-first authors, High Impact Factor of 16.8 ) (This study illustrates the PLK1 signaling pathway switching mechanism with DNMT3A signaling pathway. Drug combination inhibition both on DNMT3A and PLK1 can overcome the ‘rewiring’ to stop prostate cancer patients'progression)
• Zhuangzhuang Zhang, Lijun Cheng , Jie Li, Elia Farah, Nadia M Atallah, Pete E Pascuzzi, Sanjay Gupta, Xiaoqi Liu. Inhibition of the Wnt/β-catenin pathway overcomes resistance to enzalutamide in castration-resistant prostate cancer. Cancer research. 2018, 78 (12): 3147-3162. ( High Impact Factor of 12.8 . This study illustrates the Wnt/ β-catenin pathway switching mechanism with AR signaling pathways and seek new drug combination to overcome the Wnt pathway activated after enzalutamide resistance.)
• Jinghui Liu, Daheng He, Lijun Cheng , Changkun Huang, Yanquan Zhang, Xiongjian Rao, Yifan Kong, Chaohao Li, Zhuangzhuang Zhang, Jinpeng Liu, Karrie Jones, Dana Napier, Eun Y Lee, Chi Wang, Xiaoqi Liu. p300/CBP inhibition enhances the efficacy of programmed death-ligand 1 blockade treatment in prostate cancer. Oncogene. 2020, 39:3939-3951. ( High Impact Factor of 9.86 , this study illustrates the cell death immunology pathway switching mechanism with AR signaling pathways and seek new drug combination to overcome the new pathway activate.)

Latest funding granted in molecular mechanism and drug development

• R01 ES032026, In utero endocrine disruption causes cell type specific alterations that promote breast cancer, co-investigator
• R01 GM135234, Mitochondrial metabolism in microbial sepsis, co-investigator
• U01, An informatics bridge over the valley of death for cancer Phase I trials for drug combination therapies, co-investigator
• R01, Maternal and pediatric precision in therapeutics data, model, knowledge, and research coordination center (IU-OSU MPRINT DMKRCC), co-investigator
• P54 HD090215, Optimization of therapeutic approaches for children with relapsed sarcomas using precision medicine, co-investigator

PREVIOUS POSITIONS

• 05/2015 – 12/2017 Assistant Researcher Professor, Department of Medical and Molecular Genetics, Indiana University, Indianapolis, Indiana, U.S.
• 04/2014 – 05/2015 Postdoctoral Fellow, Department of Medical and Molecular Genetics, Indiana University, Indianapolis, IN, U.S.
• 12/2012 – 03/2014 Assistant Researcher, Shanghai Jiao Tong University, State Key Laboratory of Oncogenes and Related Genes, Shanghai Cancer Institute, P. R. China
• 07/2008 – 11/2012 Donghua University, P.R. China, and Concordia University, Canada, Joint Ph.D. , Artificial Intelligence Pattern Identification, Electrical Engineering and Computer Science

DEVELOPPED SOFTWARE

Drug response prediction in precision medicine, DRPM interactive website platform

• DRPM is for predicting an individual's response to cancer target therapy by patient gene expression profile. To drug resistance patient, DRPM will recommend optional drug treatment.
• A novel artificial intelligence modeling (layer optimal pattern matching) between cancer cells and tumors based on both gene expression profiles and drug response to seek optional experimental cells and drugs for individual patients.
• The DRPM connected the evidence from patients to the basic science experiment to generate a therapeutic hypothesis providing a strong theoretical basis.
• User evaluation and feedback, usability surveys to DRPM
• How to cite: Cheng, Lijun , Abhishek Majumdar, Daniel Stover, Shaofeng Wu, Yaoqin Lu, and Lang Li. 2020. "Computational Cancer Cell Models to Guide Precision Breast Cancer Medicine" Genes 11, no. 3: 263. https://doi.org/10.3390/genes11030263

TrilogPM platform for precision medicine– “the right treatment, for the right patient, at the right time."

• TrilogPM, a comprehensive evidence knowledgebase in precision cancer medicine. It is a Shiny web server currently for searching drug, target, and genome variation (biomarkers) in copy number variation, mutation and fusion, and cancer type and associated drug treatment. The system integrated the most famous six precision medicine database together to provide a comprehensive evidence knowledgebase in precision cancer medicine for clinical practice and clinical trial generate hypothesis.
• TrilogyPM software is freely available to biomedical researchers and educators in the non-profit sector.
• User evaluation and feedback, usability surveys to TrilogyPM

PDAC_Immune

• How to turn cold tumors into hot tumors by regulating immune checkpoint expression.
• Although targeting Plk1 to treat pancreatic cancer (PDAC) has been attempted in clinical trials, the results were not promising, and the mechanisms of resistance to Plk1 inhibition is poorly understood. In addition, the role of Plk1 in PDAC progression requires further elucidation.
• Our latest results show combination immunotherapy and inhibition of the cell cycle can improve immunotherapy effective.
• PDACImmune is developed to disclose the relationship between cell/gene expression variation and survival time in PDAC progression. The key cell/gene variation along with survival time can be identified and searched. The Kaplan Meier Curve is used to estimate the survival function in different cell type.
• How to cite: Zhang, Zhuangzhuang&, Lijun Cheng&, Jie Li&, Qi Qiao, Anju Karki, Derek B. Allison, Nuha Shaker et al. "Targeting Plk1 sensitizes pancreatic cancer to immune checkpoint therapy." Cancer Research 82, no. 19 (2022):3532-3548. & co-first author.

SCNrank platform, for therapeutic targets identification in cancer by a large screening CRISPR-Cas9 guidance

• A novel artificial intelligence modeling (graph pattern matching and ranking algorithm) with a Shiny web server for potential cancer target identification, target molecular mechanism, and visualization.
• The potential identified therapiutic targets and target molecular mechanism translation have been connected to clinical trails successfully in ten cancer types, colon adenocarcinoma, esophageal carcinoma, head and neck squamous cell carcinoma, kidney renal clear cell carcinoma, kidney renal papillary cell carcinoma, liver hepatocellular carcinoma, lung adenocarcinoma, lung squamous cell carcinoma, pancreatic adenocarcinoma, thyroid carcinoma.
• The SCNrank system is datamining on big data to seek cancer potential targets, including expression profiles from tumor tissue, adjacent normal tissue, and cell-line; protein-protein interaction network (PPI); and CRISPR-Cas9 gene knock-out from cancer cell data. By gene functions variations of cancer cell lines from genome scale CRISPR-Cas9, SCNrank matches its functions with tumors to guide precision cancer medicine.
• User evaluation and feedback, usability surveys to SCNrank
• How to cite: Enze Liu, Zhuang Zhuang Zhang, Xiaolin Cheng, Xiaoqi Liu & Cheng, Lijun* . SCNrank: spectral clustering for network-based ranking to reveal potential drug targets and its application in pancreatic ductal adenocarcinoma. BMC Med Genomics 13 (Suppl 5), 50 (2020). https://doi.org/10.1186/s12920-020-0681-6

XDeath shinyapps cloud for therapeutic target identification to induce property cell death in cancer.

• XDeath is to identify the most significant therapeutic targets to induce cell death regulately. At the same time, the XDeath model is for the mechanism interpreting of disease progression and drug resistance.
• Using a deep neural network model, XDeath, is used to precisely identify therapeutic targets that are associated with cancer initiation and/or progression. The unique method could detect molecular targeting of distinct deregulated active signaling elements that might contribute to their sustained growth, survival, and treatment resistance, therefore, is of immense therapeutic interest. These novel target identification approaches should improve the efficacy of current therapeutic treatments against highly aggressive, metastatic, recurrent, and lethal cancers. Twenty-nine pathways of cell death with eight cell death modes, apoptosis, autophagy, autosis, immunogenic (T cell, B cell), necroptosis, the broad-spectrum protein kinase C (PKC) ferroptosis, and proliferation (survival) are observed systematically. Molecular mechanisms of crosstalk during cancer progresses dynamically from the early stage to the advanced stage and is investigated in two independent datasets. Current platform, as prostate cancer for example, we demonstrated how these survival pathways crosstalk switches and caused prostate cancer progression. The optimal therapeutic targets are identified to stop progression, where TCGA: 550 patients for modelling construction, and GEO serial ID GSE21032: 177 patients for validation.
• User evaluation and feedback, usability surveys to XDeath
• How to cite: Zhuangzhuang Zhang&, Lijun Cheng&, Qiongsi Zhang, Yifan Kong, Daheng He, Kunyu Li, Matthew Rea, Jianling Wang, Ruixin Wang, Jinghui Liu, Zhiguo Li, Chongli Yuan, Enze Liu, Yvonne N. Fondufe-Mittendorf, Lang Li, Tao Han, Chi Wang, and Xiaoqi Liu*. Co-Targeting Plk1 and DNMT3a in Advanced Prostate Cancer. Advance Science. 2021, 8, 2101458.& co-first author.

XDeathDB-- an intertact website on shinyapps cloud for programmed cell death and crosstalk search engine

• XDeathDB creates a comprehensive search engine of molecular mechanisms of cell death and cell death interactions at the key therapeutic targets, cell death hallmark genes and pathway relevant to regulation of cell death.
• XDeathDB includes 12 cell death modes and 498 pathways in cell cycle, immunology, autophagy, ferroptosis, appoptosis, necrosis, DNA damage, mitochondria, pyroptosis, lysozomal cell death, mitotic cell death, autosis, autophagy, which refer to latest nature literature molecular mechanisms of cell death.
• With XDeathDB platform, users can search specific interactions from vast interdependent sub-networks that occur in the realm of cell death, including any genes, any pathways and 12 cell death modes.
• XDeathDB is a dynamic interactive system. Users can upload gene-expression profiles linked with phenotypes and create their own networks using their own genes of interest. In addition, users can import dynamic networks from a txt file directly and export dynamic networks to a txt file for further analysis.
• XDeathDB implemented dynamic network construction method in a modular way and allow users to freely select and combine these modules to obtain their own network construction.
• User evaluation and feedback, usability surveys to XDeathDB
• How to cite: Gadepalli, V.S., Kim, H., Liu, Y. et al. XDeathDB: a visualization platform for cell death molecular interactions. Cell Death Dis 12, 1156 (2021). https://doi.org/10.1038/s41419-021-04397-x

DGCyTOF package --- Deep learning visualization for single cell subtype identification

• Mass cytometry, or CyTOF (Fluidigm), is a novel platform for high-dimensional phenotypic and functional analysis of single cells.
• CyTOF is a variation of flow cytometry in which antibodies are labeled with heavy metal ion tags rather than fluorochromes.
• A new tool Deep learning with Graphical clustering, called DGCyTOF, is developped to identify new cell population by CyTOF big data analysis.
• How to cite: Lijun Cheng, Pratik Karkhanis, Birkan Gokbag, and Lang Li. DGCyTOF: deep learning with graphic cluster visualization to predict cell types of single cell mass cytometry data. Plos Computational Biology, 2022, 18(4): e1008885. https://doi.org/10.1371/journal.pcbi.1008885

Bi-EB package --- biclustering method based on empirical bayesian

• Bi-EB tool detects the patterns shared from both integrated omics data and between species [1].
• A fast empirical Bayesian biclustering (Bi-EB) algorithm is developed to detect the patterns shared from both integrated omics data and between species.
• The genome molecular features shared between cell lines and tumors give us insight into discovering potential drug targets for cancer patients.
• Our previous studies demonstrate that these important drug targets in breast cancer, ESR1, PGR, HER2, EGFR, and AR have a high similarity in mRNA and protein variation in both tumors and cell lines [2-3].
• Based on the evidence, we developed a biclustering method based on empirical bayesian (Bi-EB), to detect the local pattern of integrated omics data both in cancer cells and tumors. We adopt a data driven statistics strategy by using Expected-Maximum (EM) algorithm to extract the foreground bicluster pattern from its background noise data in an iterative search. Our novel Bi-EB statistical model has better chance to detect co-current patterns of gene and protein expression variation than the existing biclustering algorithms and seek the drug targets’ co-regulated modules of mRNA and protein.
• How to cite:
• [1] Aida Yazdanparast, Lang Li*, Chi Zhang, Lijun Cheng*. Bi-EB: Empirical Bayesian Biclustering for Multi-Omics Data Integration Pattern Identification among Species. Genes 2022, 13, 1982. https://doi.org/10.3390/genes13111982
• [2] Jiang GL, Zhang SJ, Yazdanparast A, Li M, Vikram Pawar A, Liu YL, Inavolu SM, Cheng LJ. Comprehensive comparison of molecular portraits between cell lines and tumors in breast cancer. BMC genomics, 2016, 17(7), 281-301.
• [3] Aida Yazdanparast, Lang Li, Milan Radovich, Lijun Cheng*. Signal translational efficiency between mRNA expression and antibody-based protein expression for breast cancer and its subtypes from cell lines to tissue. International Journal of Computational Biology and Drug Design , 2018, 11 (1-2), 67-89.

DSCN_package--- Double-target Selection guided by CRISPR screening and Network

• Double target selection guided by CRISPR screening and network model
• DSCN is a tool that takes multi-omics data and prioritize target combinations that facilitate the development of novel treatment plan of complex diseases such as cancers. DSCN is derived from the previous work 'SCNrank', which takes the same input and prioritize single targets.
• How to cite:
• Enze Liu,Xue Wu,Lei Wang,Yang Huo,Huanmei Wu,Lang Li, Lijun Cheng. DSCN: Double-target selection guided by CRISPR screening and network,PLoS Computational Biology, 2022, 18(8): e1009421. https://doi.org/10.1371/journal.pcbi.1009421

STUDENTS

• Involvement in graduate/professional exams, theses, and dissertations and undergraduate research
• Undergraduate Students: 180 students per year from year 1998 to year 2008; 21 students in year 2017; 18 students in year 2018;27 students in year 2019;21 students in year 2020;
• Masters Students: Pooja Chandra, Sai Mounika Inavolu, Varshini Vasudevaraja, Aniruddha Vikram Pawar
• Doctoral students: Enze Liu, Aida Yazdanparast, Yimin Liu
• Post-doctoral fellow: Abhishek Majumdar, Tao Han

CONTRIBUTIONS TO SCIENCE

Dr. Cheng’s complete list of published work can be accessed in MyBibliography and google scholar (Dr.Cheng has published 52 peer reviewed journal papers and 16 proceedings papers and 4 books. She obtained 5 authorized patents and 8 software copyrights. )

• The full journal publication list can be found in NCBI MyBibliography Lijun

• All papers list on google scholar by the link

AREA OF EXPERTISE PAPER

Dr.Cheng contribution to science mainly exists in three aspects (list typical 4 papers):

1. Artificial intelligence (AI) graph neural network learning models for pattern recognition tasks

Dr.Cheng has developed several graph neural network and learning models and applying them in primary open-angle glaucoma identification by dynamic images analysis, therapeutic target identification from membrane protein interaction networks , and predictive biomarkers identification to chemotherapy response in sarcoma patients. Influence of findings: these AI methods led to a new theory system in machine learning and make these identification task speed fast and accuracy improvement sharply in big data mining. All these finding is published on top tie artificial neural network and learning journals. 1.) IEEE Transaction on neural network and learning systems (impact factor, 11.683). 2.) Neurocomputing (impact factor, 4.38), 3) BMC Medicine Genomics (impact factor, 3.17).

• [1] Yongsheng Ding*, Lijun Cheng, Witold Pedrycz, and Kuangrong Hao, Global nonlinear kernel prediction for large dataset with a particle swarm optimized interval support vector regression, IEEE Transaction on neural network and learning systems, 2015, 26(10):2521-2534. (Co-first authors)
• [2] Enze Liu,Xue Wu,Lei Wang,Yang Huo,Huanmei Wu,Lang Li, Lijun Cheng. DSCN: Double-target selection guided by CRISPR screening and network,PLoS Computational Biology, 2022, 18(8): e1009421. https://doi.org/10.1371/journal.pcbi.1009421
• [3] Lijun Cheng, Yongsheng Ding*, Hao Kuangrong, and Yifan Hu. An ensemble kernel classifier with immune clonal selection algorithm for automatic discriminant of primary open-angle glaucoma. Neurocomputing. 2012; 83(15):1-11.
• [4] Lijun Cheng, Pratik Karkhanis, Birkan Gokbag, and Lang Li. DGCyTOF: deep learning with graphic cluster visualization to predict cell types of single cell mass cytometry data. Plos Computational Biology, 2022, 18(4): e1008885. https://doi.org/10.1371/journal.pcbi.1008885

2. Optimal drug-combination identification

Dr.Cheng developed system biology models to identify effective drug combination treatment for these patients with resistance and metastasis by signaling pathway rewiring mechanism. Her calculational model system got extensive validation and application in different collaborative universities, such as Indiana University and Kentucky University in United State. These studies published on the top tie cancer journals, such as the Cancer Research (impact factor 12.8), Oncogene (impact factor, 8.6), Cancer (impact factor, 5.742), the Journal of Biological Chemistry (impact factor 4.238). The selected paper associated to the research lists as the following:

• [1] Pankita H Pandya*, Lijun Cheng*, M Reza Saadatzadeh, Khadijeh Bijangi-Vishehsaraei, Shan Tang, Anthony L Sinn, Melissa A Trowbridge, Kathryn L Coy, Barbara J Bailey, Courtney N Young, Jixin Ding, Erika A Dobrota, Savannah Dyer, Adily Elmi, Quinton Thompson, Farinaz Barghi, Jeremiah Shultz, Eric A Albright, Harlan E Shannon, Mary E Murray, Mark S Marshall, Michael J Ferguson, Todd E Bertrand, L Daniel Wurtz, Sandeep Batra, Lang Li, Jamie L Renbarger, Karen E Pollok. Systems biology approach identifies prognostic signatures of poor overall survival and guides the prioritization of novel BET-CHK1 combination therapy for osteosarcoma. Cancers 2020, 12(9): 2426. (Co-first authors). (This study illustrates the MYC signaling pathway switching mechanism with RAD21 signaling pathway and seek BET-CHK1 combination drug treatment to overcome the ‘rewiring’)
• [2] Yifan Kong, Lijun Cheng, Fengyi Mao, Zhuangzhuang Zhang, Yanquan Zhang, Elia Farah, Jacob Bosler, Yunfeng Bai, Nihal Ahmad, Shihuan Kuang, Lang Li and Xiaoqi Liu. Inhibition of cholesterol biosynthesis overcomes enzalutamide resistance in castration-resistant prostate cancer (CRPC). The Journal of Biological Chemistry, 293:14328-14341. (This study illustrates the cholesterol signaling pathway switching mechanism with AR signaling pathway and seek combination drug treatment to overcome the temporal ‘rewiring’.)
• [3] Zhuangzhuang Zhang, Lijun Cheng, Jie Li, Elia Farah, Nadia M Atallah, Pete E Pascuzzi, Sanjay Gupta, Xiaoqi Liu. Inhibition of the Wnt/β-catenin pathway overcomes resistance to enzalutamide in castration-resistant prostate cancer. Cancer research. 2018, 78 (12): 3147-3162. (This study illustrates the Wnt/ β-catenin pathway switching mechanism with AR signaling pathways and seek new drug combination to overcome the Wnt pathway activate.)
• [4] Zhang, Zhuangzhuang#, Lijun Cheng#, Jie Li#, Qi Qiao, Anju Karki, Derek B. Allison, Nuha Shaker et al. "Targeting Plk1 sensitizes pancreatic cancer to immune checkpoint therapy." Cancer Research 82, no. 19 (2022):3532-3548. (#Co-first authors, High Impact Factor of 12.8 ) (This study illustrates the PLK1 inhibitor resistance mechanism, which caused immune checkpoint gene activated. Combination drug treatment PDL1 inhibitor and plk1 inhibitor can overcome the ‘rewiring’ to stop pancreatic cancer patients'progression)

3. Optimal therapeutic targets identification

Dr.Cheng has developed several system biology optimization methods for therapeutic targets identification and associated effective drug recommendation for cancer. Systematic network analysis on cancer patients has multiple potential biological and clinical applications. A better understanding of the effects of gene/protein interaction may lead to the identification of cancer genes and correlated pathways, which, in turn, may offer better targets for drug development in cancer treatment. An optimizing subnetwork searching of drug targets algorithms is developed for drug targets selection, such as IODNE for triple negative breast cancer and SCNrank for pancreatic ductal adenocarcinoma. Associated study results are published on the top tie biomedicial journals, the Journal of the American Medical Informatics Association (impact factor, 4.112), BMC Medicine Genomics (impact factor, 3.17) and Genes (impact factor, 2.984).

• [1] Sai Mounika Inavolu, Milan Radovich, Varshini Vasudevaraja, Kinnebrew, Garrett Hess, Shijun Zhang, Jamie Renbarger, and Lijun Cheng*, IODNE: An Integrated Optimization method for identifying the Deregulated sub-NEtwork for precision medicine in cancer, CPT: Pharmacometrics & Systems Pharmacology, 2017, 6(3):168-176.
• [2] Enze Liu, Zhuang Zhuang Zhang, Xiaolin Cheng, Xiaoqi Liu, and Lijun Cheng*, SCNrank: spectral clustering for network-based ranking to reveal potential drug-targets and its application in pancreatic ductal adenocarcinoma. BMC Med Genomics. 2020,13(Suppl 5):50.
• [3] Lijun Cheng, Bryan P. Schneider and Lang Li*, A Bioinformatics approach for the precision medicine off-label drug usage among triple negative breast cancer patients, the Journal of the American Medical Informatics Association, 2016, pii: ocw004.
• [4] Lijun Cheng, Abhishek Majumdar, Daniel Stover, Shaofeng Wu, Yaoqin Lu, Lang Li. Computational cancer cell models to guide precision breast cancer medicine. Genes (Basel). 2020, 11(3):263.