Biomedical Hypothesis Generation by Text Mining and Gene Prioritization

被引：1

作者：

Petric, Ingrid ^{[1
,2
]}

Ligeti, Balazs ^{[3
]}

Gyorffy, Balazs ^{[4
]}

Pongor, Sandor ^{[2
,3
]}

机构：

[1] Univ Nova Gor, Ctr Syst & Informat Technol, SI-5000 Nova Gorica, Slovenia

[2] Int Ctr Genet Engn & Biotechnol, Prot Struct & Bioinformat Grp, I-34012 Trieste, Italy

[3] Pazmany Peter Catholic Univ, Fac Informat Technol, H-1083 Budapest, Hungary

[4] Hungarian Acad Sci, Res Lab Pediat & Nephrol, H-1083 Budapest, Hungary

来源：

PROTEIN AND PEPTIDE LETTERS | 2014年 / 21卷 / 08期

关键词：

Biomedical hypothesis generation; disease gene prediction; gene prioritization; ovarian cancer; text mining; EPITHELIAL OVARIAN-CANCER; INDEPENDENT PROGNOSTIC-FACTOR; LITERATURE-BASED DISCOVERY; CYCLIN-E EXPRESSION; CA-125; HALF-LIFE; BREAST-CANCER; PROTEIN EXPRESSION; CLINICAL-RELEVANCE; MICROARRAY DATA; POOR-PROGNOSIS;

D O I：

暂无

中图分类号：

Q5 [生物化学]; Q7 [分子生物学];

学科分类号：

071010 ; 081704 ;

摘要：

Text mining methods can facilitate the generation of biomedical hypotheses by suggesting novel associations between diseases and genes. Previously, we developed a rare-term model called RaJoLink (Petric et al, J. Biomed. Inform. 42(2): 219-227, 2009) in which hypotheses are formulated on the basis of terms rarely associated with a target domain. Since many current medical hypotheses are formulated in terms of molecular entities and molecular mechanisms, here we extend the methodology to proteins and genes, using a standardized vocabulary as well as a gene/protein network model. The proposed enhanced RaJoLink rare-term model combines text mining and gene prioritization approaches. Its utility is illustrated by finding known as well as potential gene-disease associations in ovarian cancer using MEDLINE abstracts and the STRING database.

引用

页码：847 / 857

页数：11

共 50 条

[31] Frontiers of biomedical text mining: current progress
Zweigenbaum, Pierre
Demner-Fushman, Dina
Yu, Hong
Cohen, Kevin B.
[J]. BRIEFINGS IN BIOINFORMATICS, 2007, 8 (05) : 358 - 375
[32] Adversarial Constraint Evaluation on Biomedical Text Mining
Wang, Yashen
Zhang, Huanhuan
[J]. KNOWLEDGE SCIENCE, ENGINEERING AND MANAGEMENT, PT III, 2021, 12817 : 249 - 261
[33] Biomedical Text Mining: Experience and Practical Approach
Ryu, Keun Ho
[J]. 3RD INTERNATIONAL CONFERENCE ON APPLIED COMPUTING AND INFORMATION TECHNOLOGY (ACIT 2015) 2ND INTERNATIONAL CONFERENCE ON COMPUTATIONAL SCIENCE AND INTELLIGENCE (CSI 2015), 2015, : 1 - 1
[34] Tools for Text Mining over Biomedical Literature
Rinaldi, Fabio
Schneider, Gerold
Kaljurand, Kaarel
Hess, Michael
[J]. ECAI 2006, PROCEEDINGS, 2006, 141 : 825 - +
[35] Gene Prioritization of Resistant Rice Gene against Xanthomas oryzae pv. oryzae by Using Text Mining Technologies
Xia, Jingbo
Zhang, Xing
Yuan, Daojun
Chen, Lingling
Webster, Jonathan
Fang, Alex Chengyu
[J]. BIOMED RESEARCH INTERNATIONAL, 2013, 2013
[36] Text Mining and Generation (TMG)
[J]. CEUR Workshop Proceedings, 2023, 3438
[37] Text Mining for Automatic Lexical Analysis of Layman Text of Biomedical Argument
Defilippi, D.
Pivetti, S.
Giacomini, M.
[J]. WORLD CONGRESS ON MEDICAL PHYSICS AND BIOMEDICAL ENGINEERING, VOL 25, PT 12, 2009, 25 (12): : 281 - 284
[38] A text mining approach to detect mentions of protein glycosylation in biomedical text
Shukla, Daksha
Jayaraman, Valadi K.
[J]. BIOINFORMATION, 2012, 8 (16) : 758 - 762
[39] Text Mining for Interpreting Gene
Prabavathy, K.
Sumathi, P.
[J]. TRENDS IN COMPUTER SCIENCE, ENGINEERING AND INFORMATION TECHNOLOGY, 2011, 204 : 647 - +
[40] MedMiner: An Internet text-mining tool for biomedical information, with application to gene expression profiling
Tanabe, L
Scherf, U
Smith, LH
Lee, JK
Hunter, L
Weinstein, JN
[J]. BIOTECHNIQUES, 1999, 27 (06) : 1210 - +

← 1 2 3 4 5 →