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Relevant bibliographies by topics / NMRShiftDB

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Academic literature on the topic 'NMRShiftDB'

Author: Grafiati

Published: 3 June 2025

Last updated: 13 July 2025

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Journal articles on the topic "NMRShiftDB"

1

Steinbeck, Christoph, and Stefan Kuhn. "NMRShiftDB – compound identification and structure elucidation support through a free community-built web database." Phytochemistry 65, no. 19 (2004): 2711–17. http://dx.doi.org/10.1016/j.phytochem.2004.08.027.

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2

Kuhn, Stefan, and Nils E. Schlörer. "Facilitating quality control for spectra assignments of small organic molecules: nmrshiftdb2 - a free in-house NMR database with integrated LIMS for academic service laboratories." Magnetic Resonance in Chemistry 53, no. 8 (2015): 582–89. http://dx.doi.org/10.1002/mrc.4263.

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3

Kuhn, Stefan, Heinz Kolshorn, Christoph Steinbeck, and Nils Schlörer. "Twenty years of nmrshiftdb2: A case study of an open database for analytical chemistry." Magnetic Resonance in Chemistry, December 19, 2023. http://dx.doi.org/10.1002/mrc.5418.

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AbstractIn October 2003, 20 years ago, the open‐source and open‐content database NMRshiftDB was announced. Since then, the database, renamed as nmrshiftdb2 later, has been continuously available and is one of the longer‐running projects in the field of open data in chemistry. After 20 years, we evaluate the success of the project and present lessons learnt for similar projects.

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Ahmad, Fadel Klaib, Zainol Zurinahni, Hashimah Ahamed Nurul, Ahmad Rosma, and Hussin Wahidah. "Application of Exact String Matching Algorithms towards SMILES Representation of Chemical Structure." October 27, 2007. https://doi.org/10.5281/zenodo.1078645.

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Bioinformatics and Cheminformatics use computer as disciplines providing tools for acquisition, storage, processing, analysis, integrate data and for the development of potential applications of biological and chemical data. A chemical database is one of the databases that exclusively designed to store chemical information. NMRShiftDB is one of the main databases that used to represent the chemical structures in 2D or 3D structures. SMILES format is one of many ways to write a chemical structure in a linear format. In this study we extracted Antimicrobial Structures in SMILES format from NMRShiftDB and stored it in our Local Data Warehouse with its corresponding information. Additionally, we developed a searching tool that would response to user-s query using the JME Editor tool that allows user to draw or edit molecules and converts the drawn structure into SMILES format. We applied Quick Search algorithm to search for Antimicrobial Structures in our Local Data Ware House.

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5

Kuhn, Stefan, Nils E. Schlörer, Heinz Kolshorn, and Raphael Stoll. "From chemical shift data through prediction to assignment and NMR LIMS - multiple functionalities of nmrshiftdb2." Journal of Cheminformatics 4, S1 (2012). http://dx.doi.org/10.1186/1758-2946-4-s1-p52.

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6

Nuzillard, Jean‐Marc. "Use of carbon‐13 NMR to identify known natural products by querying a nuclear magnetic resonance database—An assessment." Magnetic Resonance in Chemistry, August 15, 2023. http://dx.doi.org/10.1002/mrc.5386.

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AbstractThe quick identification of known organic low molecular weight compounds, also known as structural dereplication, is a highly important task in the chemical profiling of natural resource extracts. To that end, a method that relies on carbon‐13 nuclear magnetic resonance (NMR) spectroscopy, elaborated in earlier works of the author's research group, requires the availability of a dedicated database that establishes relationships between chemical structures, biological and chemical taxonomy, and spectroscopy. The construction of such a database, called acd_lotus, was reported earlier, and its usefulness was illustrated by only three examples. This article presents the results of structure searches carried out starting from 58 carbon‐13 NMR data sets recorded on compounds selected in the metabolomics section of the biological magnetic resonance bank (BMRB). Two compound retrieval methods were employed. The first one involves searching in the acd_lotus database using commercial software. The second one operates through the freely accessible web interface of the nmrshiftdb2 database, which includes the compounds present in acd_lotus and many others. The two structural dereplication methods have proved to be efficient and can be used together in a complementary way.

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Conference papers on the topic "NMRShiftDB"

1

Bešlo, D., M. Molnar, D. Agić, S. Roca, and B. Lučić. "THE PREDICTION ACCURACY OF 1H AND 13C NMR CHEMICAL SHIFTS OF COUMARIN DERIVATIVES BY CHEMO/BIOINFORMATICS METHODS." In 1st INTERNATIONAL Conference on Chemo and BioInformatics. Institute for Information Technologies, University of Kragujevac, 2021. http://dx.doi.org/10.46793/iccbi21.422b.

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In plant biochemistry and physiology, coumarins are known as antioxidants, enzyme inhibitors and precursors of toxic substances. Nuclear magnetic resonance (NMR) spectra are primary sources of molecular structural data. NMR provides detailed information about the local environment of the atom which can be used to determine the atomic connectivity, stereochemistry, and molecular conformation. For many years the molecular structure has been determined by NMR spectroscopy and chemical shifts are determined manually with the help of computer programs. However, recent progress in computational chemistry and chemo/bioinformatics opened the possibility for the prediction of chemical shifts (especially those of 1H and 13C nuclei) of new chemicals. We analyzed the accuracy of three available chemoinformatics methods developed for the prediction of 1H and 13C chemical shifts based on deep neural networks CASCADE [1], an older prediction method based on classical neural networks NMRshiftDB [2,3], and group-contribution method in ChemDraw [4]. The mean absolute errors (MAEs) in the prediction of NMR shifts of four newly synthesized coumarins [5] by CASCADE, NMRshiftDB and ChemDraw are (respectively) 0.39, 0.65 and 0.32 ppm for 1H, and 1.5, 6.5 and 2.3 ppm for 13C atoms, shoving relatively big differences between these prediction methods.

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