The Cambridge Structural Database

Groom, Colin R.; Bruno, Ian J.; Lightfoot, Matthew P.; Ward, Suzanna C.

doi:10.1107/s2052520616003954

Cited by 7,462 publications

(4,913 citation statements)

References 45 publications

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“…For all analyses we used CSD v.5.36 (November 2014; Allen, 2002; Groom et al , 2016) as the data source, and ConQuest v.1.15 was used for querying and retrieving data (Bruno et al , 2002). Apart from the normal pre-publication validation and refereeing processes, all data entering the CSD were carefully evaluated for chemical sense and for the internal consistency of coordinates, geometry, unit-cell parameters and space group.…”

Section: Methodsmentioning

confidence: 99%

“…Following the initial publication of bond-valence parameters based on inorganic crystal structures (Brese & O’Keeffe, 1991; Brown & Altermatt, 1985), numerous studies have discussed the bond-valence model in the context of small-molecule crystal structures in the Cambridge Structural Database (CSD; Allen, 2002; Groom et al , 2016) as well as in the Inorganic Crystal Structure Database (ICSD; Bergerhoff & Brandenburg, 2004). Some notable results based on CSD data include bond-valence parameters for copper (Shields et al , 2000), lanthanides (Trzesowska et al , 2004, 2006), cadmium (Palenik, 2006), antimony (Palenik et al , 2005) and ammonium (García-Rodríguez et al , 2000).…”

Section: Introductionmentioning

confidence: 99%

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Data mining of iron(II) and iron(III) bond-valence parameters, and their relevance for macromolecular crystallography

Zheng

Langner

Shields

et al. 2017

Acta Cryst Sect D Struct Biol

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The bond-valence model is a reliable way to validate assumed oxidation states based on structural data. It has successfully been employed for analyzing metal-binding sites in macromolecule structures. However, inconsistent results for heme-based structures suggest that some widely used bond-valence R0 parameters may need to be adjusted in certain cases. Given the large number of experimental crystal structures gathered since these initial parameters were determined and the similarity of binding sites in organic compounds and macromolecules, the Cambridge Structural Database (CSD) is a valuable resource for refining metal–organic bond-valence parameters. R0 bond-valence parameters for iron(II), iron(III) and other metals have been optimized based on an automated processing of all CSD crystal structures. Almost all R0 bond-valence parameters were reproduced, except for iron–nitrogen bonds, for which distinct R0 parameters were defined for two observed subpopulations, corresponding to low-spin and high-spin states, of iron in both oxidation states. The significance of this data-driven method for parameter discovery, and how the spin state affects the interpretation of heme-containing proteins and iron-binding sites in macromolecular structures, are discussed.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Data mining of iron(II) and iron(III) bond-valence parameters, and their relevance for macromolecular crystallography

Zheng

Langner

Shields

et al. 2017

Acta Cryst Sect D Struct Biol

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“…However, there have also been published reports on the coordination of metal cations with the carbonyl-or sulfonyl-oxygen of saccharin [5]; although the latter is less basic and is rarely involved in bonding. A comparatively rare (N,O)-bidentate bridging coordination mode, that is reported for one of the complexes in this study, has been found in only three examples in the literature [7,8,9].…”

Section: Introductionmentioning

confidence: 89%

Unusual saccharin-N,O (carbonyl) coordination in mixed-ligand copper(II) complexes: Synthesis, X-ray crystallography and biological activity

Mokhtaruddin

Yusof

Ravoof

et al. 2017

Journal of Molecular Structure

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Three tridentate Schiff bases containing N and S donor atoms were synthesised via the condensation reaction between S-2-methylbenzyldithiocarbazate with 2-acetyl-4-methylpyridine (S2APH); 4-methyl-3-thiosemicarbazide with 2-acetylpyridine (MT2APH) and 4-ethyl-3-thiosemicarbazide with 2-acetylpyridine (ET2APH). Three new, binuclear and mixed-ligand copper(II) complexes with the general formula, [Cu(sac)(L)] 2 (sac = saccharinate anion; L = anion of the Schiff base) were then synthesized, and subsequently characterized by IR and UV/Vis spectroscopy as well as by molar conductivity and magnetic susceptibility measurements. The Schiff bases were also spectroscopically characterised using NMR and MS to further confirm their structures. The spectroscopic data indicated that the Schiff bases behaved as a tridentate NNS donor ligands coordinating via the pyridylnitrogen, azomethine-nitrogen and thiolate-sulphur atoms. Magnetic data indicated a square pyramidal environment for the complexes and the conductivity values showed that the complexes were essentially non-electrolytes in DMSO. The X-ray crystallographic analysis

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“…74 SMILES strings are a non-unique representation which encode the molecular graph into a string of ASCII characters. SMILES strings for 56 of the Huang & Massa molecules were obtained from the Cambridge Structure Database Python API, 75 and the rest were generated by hand using a combination of the Optical Structure Recognition Application, 76 the www.molview.org molecule builder, and the Open Babel package 77 , which can convert .mol files to SMILES. Since Coulomb matrices require atomic coordinates, 3D coordinates for the molecules were generated using 2D→3D structure generation routines in the RDKit 53 and Open Babel 77 python packages.…”

Section: Data Gatheringmentioning

confidence: 99%

Applying Machine Learning Techniques to Predict the Properties of Energetic Materials

Elton¹,

Boukouvalas²,

Butrico³

et al. 2018

Preprint

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We present a proof of concept that machine learning techniques can be used to predict the properties of CNOHF energetic molecules from their molecular structures. We focus on a small but diverse dataset consisting of 109 molecular structures spread across ten compound classes. Up until now, candidate molecules for energetic materials have been screened using predictions from expensive quantum simulations and thermochemical codes. We present a comprehensive comparison of machine learning models and several molecular featurization methods -sum over bonds, custom descriptors, Coulomb matrices, Bag of Bonds, and fingerprints. The best featurization was sum over bonds (bond counting), and the best model was kernel ridge regression. Despite having a small data set, we obtain acceptable errors and Pearson correlations for the prediction of detonation pressure, detonation velocity, explosive energy, heat of formation, density, and other properties out of sample. By including another dataset with ≈ 300 additional molecules in our training we show how the error can be pushed lower, although the convergence with number of molecules is slow. Our work paves the way for future applications of machine learning in this domain, including automated lead generation and interpreting machine learning models to obtain novel chemical insights.

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The Cambridge Structural Database

Cited by 7,462 publications

References 45 publications

Data mining of iron(II) and iron(III) bond-valence parameters, and their relevance for macromolecular crystallography

Data mining of iron(II) and iron(III) bond-valence parameters, and their relevance for macromolecular crystallography

Unusual saccharin-N,O (carbonyl) coordination in mixed-ligand copper(II) complexes: Synthesis, X-ray crystallography and biological activity

Applying Machine Learning Techniques to Predict the Properties of Energetic Materials

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