Mapping of different databases depends on the technical content and architecture of the datasets. For better mapping and integration easy access to the metadata are preferred.
- Information Resources in Toxicology!
- Information Resources in Toxicology - 4th Edition?
- Information Resources in Toxicology. (eBook, ) [dipastejamar.gq].
- What is Kobo Super Points?.
- Good Luck and Tight Lines: A Sure-Fire Guide to Floridas Inshore Fishing.
- Habitat Gardening for Houston and Southeast Texas?
- Information resources in toxicology.
The content accessibility provided by the different databases vary: the majority of databases are open platform enabling searching of scientific data, some facilitate data downloading in different formats. Access to some databases is restricted e. Looking to the future and potential use of in silico resources, the integration of databases with in silico tools for predicting the properties or activities of compounds could be useful for early decision making in drug discovery and chemical risk assessment. The computational tools should not be limited to only chemistry or biology but should be able to link chemistry with activity, toxicity and the underlying mechanistic information.
In other words, the tools should integrate information on dosimetry, human exposure in silico and in vitro toxicity screening data to provide a better chemical safety risk assessment. In future development of databases key attributes to consider include data quality, accessibility, ease of downloading the data, chemical space coverage, and range of bioactiviy. The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Aksoy, B. Database The EBI enzyme portal. Nucleic Acids Res.
Alexander-Dann, B. Developments in toxicogenomics: understanding and predicting compound-induced toxicity from gene expression data. Omics 14, — Alonso-Lopez, D. APID interactomes: providing proteome-based interactomes with controlled quality for multiple species and derived networks. Anderle, P.
- Information Resources in Toxicology.
- REJOICE: A Celebration of Life Daily Meditations.
- Antérieurement, Maintenant, et Plus Tard – Then, Now, and Later: A Collection of Verse!
- Environmental Health & Toxicology Resources for the Public and Professionals | NNLM!
Gene expression databases and data mining. Biotechniques Suppl. Ayvaz, S. Toward a complete dataset of drug—drug interaction information from publicly available sources.
Internet resources - Toxicology - Subject & Study Guides at AIT Library
Barrett, T. Bastian, F.
- Financial Stability in the Aftermath of the Great Recession.
- Passing the Risk Management Professional (PMI-RMP)® Certification Exam the First Time!.
- These Ties!
- Toxicology: Internet resources;
- Chemical Information Sources/Chemical Safety Searches.
Berlin; Heidelberg: Springer, — Google Scholar. Bauer-Mehren, A. Pathway databases and tools for their exploitation: benefits, current limitations and challenges. Beger, R. Discriminant function analyses of liver-specific carcinogens. Belinky, F. PathCards: multi-source consolidation of human biological pathways.
Database bav Benigni, R. New perspectives in toxicological information management, and the role of ISSTOX databases in assessing chemical mutagenicity and carcinogenicity. Mutagenesis 28, — Benson, D. Bhattacharyya, S. Singapore: Springer. Bianco, A. Database tools in genetic diseases research.
Information Resources in Toxicology.
Genomics , 75— Bitsch, A. RepDose and FeDTex: Two databases focusing on systemic toxicity: first examples from analyses of repeated dose toxicity and reprotoxicity studies. Block, P. Bower, D. Breuer, K. InnateDB: systems biology of innate immunity and beyond—recent updates and continuing curation. Brown, A. A standard database for drug repositioning. Data 4, Butkiewicz, M. High-throughput screening assay datasets from the pubchem database.
Chem Inform Cases, M. The eTOX data-sharing project to advance in silico drug-induced toxicity prediction. Cerami, E. Pathway commons, a web resource for biological pathway data. Cha, Y. Drug repurposing from the perspective of pharmaceutical companies. Chatr-Aryamontri, A. Chen, B. Leveraging big data to transform target selection and drug discovery.
Chen, J. ChemDB update—full-text search and virtual chemical space.
Information resources in toxicology 
Bioinformatics 23, — Chen, M. FDA-approved drug labeling for the study of drug-induced liver injury. Drug Discov.
Today 16, — Chen, X. CLiBE: a database of computed ligand binding energy for ligand—receptor complexes. Drug—target interaction prediction: databases, web servers and computational models. Bioinformatics 17, — Cheng, T. Large-scale prediction of drug-target interaction: a data-centric review.
AAPS J. Corsello, S. The Drug Repurposing Hub: a next-generation drug library and information resource. Croft, D. Reactome: a database of reactions, pathways and biological processes. Cronin, M. Cambridge: The Royal Society of Chemistry. The in chemico- in silico interface: challenges for integrating experimental and computational chemistry to identify toxicity. Dai, S. Davis, A. The Comparative Toxicogenomics Database: update Dong, J. Douguet, D.