ChemSpider Mobile was an app developed by Molecular Materials Informatics Inc1 on behalf of the Royal Society of Chemistry to allow users to explore the benefits of ChemSpider on mobile devices. Since its launch we have made improvements to ChemSpider.com, including responsive design elements to allow it to work better on smart phones and tablets2 and upgrades to the ChemSpider web services3 that power it. As a result of these developments we felt it was timely to review the community’s need for the app and have taken the decision to discontinue support for the services that power the app from 31st October. We would like to thank everyone who used and provided feedback on the app to aid its development and encourage you to switch to using ChemSpider.com for future mobile use.
Archive for the ‘News’ Category
The Chemical Validation and Standardization Platform (CVSP)1 was developed during the Open PHACTS IMI project2 to process chemical structure files through tested validation and standardization protocols. The aim was to provide the community with rigorous analysis of their chemical structure files to ensure that data released into the public domain via online databases was pre-validated. The online CVSP site provided a useful means to test the rulesets and allow users to validate their structure files, but the standalone website was taken offline in November 2018. As a legacy, the codebase and ruleset has been evolved and applied to the ChemSpider deposition system at deposit.chemspider.com3 and the community discussions around appropriate standardisation of chemical structure files continue. The original code is also available from GitHub.4
- The Chemical Validation and Standardization Platform (CVSP): large-scale automated validation of chemical structure datasets, J. Cheminf., 2015, 7:30, https://doi.org/10.1186/s13321-015-0072-8
Royal Society of Chemistry Renews Partnership with ACD/Labs to Continue Providing Industry-Leading Data to Worldwide Research Community
ACD/Labs algorithms will continue to equip ChemSpider with physicochemical property values and chemical nomenclature following ten year milestone.
Toronto, CANADA (July 26, 2018)—ACD/Labs, an informatics company that develops and commercializes solutions in support of R&D, today announced the continued collaboration with ChemSpider, a leading chemical database owned by the Royal Society of Chemistry, to continue furnishing predicted physicochemical properties and chemical nomenclature to the ever-expanding platform. For over ten years, scientists have accessed this publically-available free resource to gather information on chemical compounds in preparation of research or experimentation.
As the industry standard for physicochemical prediction software, ACD/Labs was chosen to generate property information including logP, logD (at various pHs), Lipinski rule-of-5 values, and boiling point, and to provide Name-to-structure (and vice-versa) capabilities. The renewal of the partnership further reflects the success of the platform and its continued importance as one of the most robust online chemical structure databases for the scientific community. As the platform advances, ChemSpider will continue to use ACD/Labs algorithms to provide quality insights to researchers.
“We set out with the mission of empowering researchers with a comprehensive view of chemical data to inform R&D initiatives,” said Richard Kidd, Publisher, Royal Society of Chemistry. “By working with ACD/Labs and utilizing its property information, we’ve been able to meet our users’ need for knowledge, which is reflected in our rapid growth since the Royal Society of Chemistry acquired ChemSpider ten years ago. To-date, property information populated by ACD/Labs’ algorithms has been among the most accessed on ChemSpider, and remains a key driver in our service.”
While ChemSpider has doubled the size of its database, it has remained committed to maintaining high quality data from selective sources. As the platform continues to grow, ChemSpider will use ACD/Percepta prediction algorithms and ACD/Name tools in a batch-wise fashion to populate the database and enhance publicly available chemical intelligence.
“Enabling the dissemination of chemical knowledge and providing solutions to accelerate R&D are among our top priorities at ACD/Labs,” said Gabriela Cimpan, Senior Director Sales, Europe, ACD/Labs. “ChemSpider is empowering knowledge throughout the chemical community and we feel privileged to be able to support learning worldwide.”
For more information on ACD/Percepta, visit https://www.acdlabs.com/percepta
For more information on ACD/Labs Chemical Nomenclature tools, visit https://www.acdlabs.com/name
For more information on ChemSpider, visit http://www.chemspider.com
About Advanced Chemistry Development, Inc.
ACD/Labs is a leading provider of scientific informatics technologies to R&D organizations that rely on analytical data and molecular information for decision-making, problem-solving, and product lifecycle control. Our software automates and accelerates molecular characterization, product development, and knowledge management. We integrate with existing informatics systems and undertake custom projects including enterprise-level automation.
ACD/Labs solutions are used globally in a variety of industries including pharma/biotech, chemicals, consumer goods, agrochemicals, petrochemicals, and academic/government institutions. We provide worldwide sales and support, and more than 20 years of experience and success helping organizations accelerate R&D and leverage corporate intelligence. For more information, please visit www.acdlabs.com. Follow us on Twitter @ACDLabs.
About the Royal Society of Chemistry
The Royal Society of Chemistry is the world’s leading chemistry community, advancing excellence in the chemical sciences. With over 50,000 members and a knowledge business that spans the globe, we are the UK’s professional body for chemical scientists; a not-for-profit organisation with 175 years of history and an international vision for the future. We promote, support and celebrate chemistry. We work to shape the future of the chemical sciences – for the benefit of science and humanity.
Written by Aileen Day.
We are pleased to announce that we have just imported 1047 CIFs to ChemSpider of crystal structures that were previously reported in RSC papers (and are available as ESI for those) to ChemSpider for the relevant compounds, and linked those back to the original articles and to the CCDC’s webCSD, e.g. example compound with RSC article CIF (see the CIF infobox). Since each CIF that is uploaded into ChemSpider must be associated with a ChemSpider compound, the difficult part of this task was working out a 2D molecular structure (in .mol file format) for each 3D crystal structure (in .cif file format) – which is particularly difficult because CIFs only contain information about each atomic position and not how the atoms are bonded to each other in the crystal or whether they are charged or not.
Ultimately we would like this CIF to mol conversion (and the whole upload) to be performed programmatically without human intervention. However, there is no reliable way to do that currently – although programs such as OpenBabel can be used to extract mols from each CIF, the reliability of this conversion isn’t 100%.
So as one of our student intern projects at the University of Southampton this summer (in parallel with another student intern project at Southampton University to share thesis data in ChemSpider) we used OpenBabel (version 2.3.2, run from the command line with the options -i cif inputfilename.txt -o mol -m –unique -d –AddPolarH) to extract mols for all the CIFs in the RSC archive (over 43,000 files as of June 2013) and enlisted Julija Kezina (shown below) to review the results of these conversions to ensure that only good structure and CIF pairs would be deposited to ChemSpider, and to better understand the problems in the conversion process with a view to fixing them. One problem that became immediately apparent was that because the 2D structure obtained was just a projection of the 3D structure along the a cell axis, which is not always the orientation which shows the molecule most clearly, even if they did have the write chemical connections between the atoms, so all mol structures were run through OpenEye’s cleaning algorithm before being reviewed.
Julija compared each structure in the output mol files with those in the original CIF files to judge whether the conversion was accurate or not. In addition, as an extra check, all of the output mol structures were submitted to ChemSpider validation and standardisation platform to filter out molecules with structural problems (e.g. stereochemistry, valence or congestion issues).
Overall, approximately 30% of the CIF to mol conversions that Julija checked were good, with the right connectivity of atoms and ions (although approximately 30% of these needed the atomic positions to be repositioned to clean or tidy up the structure, either manually or using ChemDraw’s cleaning functionality). The 1047 of these mols which contain only a single molecule (without solvent molecules or cocrystals etc.) are those which have been deposited into ChemSpider with their corresponding CIFs.
The journals which had the highest successful conversion percentage were Molecular BioSystems (57%), MedChemComm (51%), Organic and Biomolecular Chemistry (44%) and Green Chemistry (44%) – the journals which in general are about small organic molecules.
Julija was working in the National Crystallography Service’s office at the University of Southampton, under the co-supervision of Professor Simon Coles, and we are grateful to them for their help and advice about the finer points of the CIF file format.
Unsuccessful CIF to mol conversions
Running and evaluating OpenBabel on such a large and varied set of structures has given us a useful opportunity to identify and categorise the most common problems encountered. Here we share these and give examples that would enable the identification of some easy fixes in the pipeline that might benefit the whole community and be used as test cases when doing so. We will report these bugs to the OpenBabel forum and because OpenBabel is open source, hope to resolve at least some of these issues in the future through collaboration with its other developers.
The following OpenBabel bugs look like they might be most straightforward to fix:
Many of the problems were caused by idiosynchronies or errors in the input CIFs, but these on the whole weren’t handled well by OpenBabel (e.g. by writing an error message and terminating the program) but rather, in the majority of cases went into an infinite loop and the program hung. Because of this, and because the OpenBabel conversions were part of a longer script, all OpenBabel jobs had to be run with an arbitary timeout so that if still running after this timeout they were killed, which may have discarded some valid but long-running OpenBabel jobs. We will investigate whether there is a validation program that can be automatically performed on CIFs to filter out ones with these problems (similar to the CCDC’s EnCIFer but which can be run programmatically), but it would be relatively straightforward to make OpenBabel more reliable by being able to exit nicely when it encounters these problems so that pre-validation wasn’t necessary. These problems are listed in the table below:
The following OpenBabel bugs were the most frequent in occurence, but will be difficult to fix. They arise from the problem that the CIF format does not record charges on atoms/ions or the types of bong between them so OpenBabel needs to work them out which is hard to do correctly.
There were also some problem mol files produced which either won’t be able to be fixed by OpenBabel (since they resulted from either errors or limitations of the input CIF files which cannot be fixed retrospectively) or are too difficult to fix and/or too infrequently occuring to be worth the effort:
- There were 237 cases where there were solvent molecules in the CIF (many of which have missing hydrogens, partial occupancy of the molecule or part of the molecule etc.) which give rise to spurious oxygens, fragments of molecules and radicals in the resulting mol file (see CIF: CCDC 213787 and ChemSpider record: 68005706). 148 of these cases are just water solvent molecules either with missing or detached hydrogen atoms. The poor definition of the solvent molecules is a limitation of CIF files from diffraction so it is not possible for OpenBabel to better define them in the output mol that is derived from them. However, running OpenBabel with the -r option to remove all but the largest contiguous fragment was quite successful to remove these problem solvent molecules so no further action is required to deal with this problem and this option will be used by us in the future.
- There were 81 cases where there was at least one missing hydrogen in the original CIF (or in 3 cases, all hydrogens missing) – see CCDC 259871.
- Some CIFs contain crystal structures which correspond to continuous networks rather than small molecules (e.g. polymers, MOFs, zeolites, POMs) which cannot meaningfully be captured in mol format – see CCDC 206593.
- There were a few (24) cases where the stereochemistry in the mol file obtained is incorrectly defined. However, because on the stereochemistry was well interpreted by OpenBabel and these cases were relatively few, it probably isn’t worth disturbing the apple cart to investigate these further – see CCDC 238611 and ChemSpider 9419187.
Written by Aileen Day.
This summer there have been a number of students from the University of Southampton doing internships on joint projects between the university and the Royal Society of Chemistry and ChemSpider. Three of these students have been sifting through theses from past members of Richard Whitby’s research group in order to extract the compound, spectra and reaction data in it (and linked lab note books, and archive spectra files) and share these in LabTrove, ChemSpider, and CSSP. The students – Alex Hartke, Yet Wai Lee and Josh Whittam (all 2nd year undergraduates) – are shown below together with the boxes of thesis data, lab notebooks and spectra print outs that they digitised.
Between them they digitised 7 theses, by A.Henderson, L. Sayer, D. Owen, D.Macfarlane, F. Giustiniano, G. Saluste, J. Stec, which resulted in 1035 LabTrove pages being published to the Whitby Group’s LabTrove blog.
The theses were a rich source of compound information – including compound structures, names, properties and spectra, all of which were also deposited into ChemSpider resulting in 208 new compound pages, and about 600 spectra.
For this project the students manually deposited the compound information into LabTrove and then deposited the compounds and spectra to ChemSpider. However, we are currently developing a range of ChemSpider jquery widgets which can be integrated into web-based ELNs such as LabTrove which will make it easier to enter compound information from ChemSpider into experiments, and also to publish compound and reaction data from the ELNs to ChemSpider, CSSP and ChemSpider Reactions. This will follow on from the initial proof of concept to retreive ChemSpider information and enter it into LabTrove pages.
With this long-term aim in view, the LabTrove pages that the interns stored the compound and reaction data were structured using LabTrove templates, and this structuring will make it easier for publishing widgets to understand the data and process it the correct way. In this way, the project was partly a test to ensure that the templates were suitable for storing compound data in LabTrove. As well as the ChemSpider compound and associated data template (with corresponding help page, templates were also written to store reaction data in a formatted way, since the theses were primarily focused on the synthesis of compounds. At their simplest, basic reaction data can be stored in LabTrove using the ChemSpider Reactions template (and corresponding help page, and eventually posts written in this format will be easily publishable to ChemSpider Reactions. More detailed reaction data can be stored using the ChemSpider SyntheticPages style reaction template (and corresponding help page. The initial aim was to deposit all of this reaction data into ChemSpider SyntheticPages but it became clear that it was difficult for anyone other than the researcher who conducted the reaction, or their superviser to supply the necessary level of detail for CSSP submissions, and in particular couldn’t easily be reached by retrospectively abstracting theses. As a result, only a handful of reactions were submitted to CSSP, and the majority (over 500) were stored in LabTrove for future submission to ChemSpider Reactions.
If reactions can be published easily from ELNs to ChemSpider Reactions and that is easily queryable by other researchers and their applications when performing new reactions this will be a major step towards the aims of the Dial-a-molecule (an EPSRC Grand Challenge network). An important part of the reaction data which needs to be captured is the stoichiometry table of substances used and produced in a reaction. However, these stoichiometry tables are too complicated to incorporate into a LabTrove template, so the LabTrove reaction templates will be used in conjunction with a new ChemSpider jquery widget which is currently in the process of being integrated with LabTrove (more details to follow on this blog shortly!) which will construct them. The widget performs ChemSpider lookups to retrieve compound information, and will calculate equivalents, thereby saving the researcher time when working out the amounts of reactants needed or yields of products obtained. An example of a reaction post which was initially created using the ChemSpider Reactions template and then supplemented by adding a stoichiometry table to it using the ChemSpider Edit Stoichiometry Table widget is shown here.
If you are a LabTrove user and wish to use the ChemSpider templates, their source is available via their links above, and instructions for using templates in Labtrove are documented here.