Special Libraries, July 1978

Volume 69, Issue 7https://scholarworks.sjsu.edu/sla_sl_1978/1005/thumbnail.jp

Chemical Information Bulletin

Created as a supplement for "the regular journals of the American Chemical Society," this publication contains annotated bibliographies of chemical documentation literature as well as information about meetings, conferences, awards, scholarships, and other news from the American Chemical Society (ACS) Division of Chemical Information (CINF)

Compact Codes. 2. Bicyclic Saturated Hydrocarbons

Compact codes, recently introduced (ref. 1), have been applied to all known bicyclic saturated hydrocarbons as the first step in a systematic deriving compact codes for more complex ring systems. The codes are compared with IUPAC nomenclature for bicyclic compounds, as well as with WLN (Wiswesser Line Notation). Advantages of the compact codes are outlined, including qualified algebraic manipulations on the codes to derive codes for structurally related compound

Design and implementation of a platform for predicting pharmacological properties of molecules

Tese de mestrado, Bioinformática e Biologia Computacional, Universidade de Lisboa, Faculdade de Ciências, 2019O processo de descoberta e desenvolvimento de novos medicamentos prolonga-se por vários anos e implica o gasto de imensos recursos monetários. Como tal, vários métodos in silico são aplicados com o intuito de dimiuir os custos e tornar o processo mais eficiente. Estes métodos incluem triagem virtual, um processo pelo qual vastas coleções de compostos são examinadas para encontrar potencial terapêutico. QSAR (Quantitative Structure Activity Relationship) é uma das tecnologias utilizada em triagem virtual e em optimização de potencial farmacológico, em que a informação estrutural de ligandos conhecidos do alvo terapêutico é utilizada para prever a actividade biológica de um novo composto para com o alvo. Vários investigadores desenvolvem modelos de aprendizagem automática de QSAR para múltiplos alvos terapêuticos. Mas o seu uso está dependente do acesso aos mesmos e da facilidade em ter os modelos funcionais, o que pode ser complexo quando existem várias dependências ou quando o ambiente de desenvolvimento difere bastante do ambiente em que é usado. A aplicação ao qual este documento se refere foi desenvolvida para lidar com esta questão. Esta é uma plataforma centralizada onde investigadores podem aceder a vários modelos de QSAR, podendo testar os seus datasets para uma multitude de alvos terapêuticos. A aplicação permite usar identificadores moleculares como SMILES e InChI, e gere a sua integração em descritores moleculares para usar como input nos modelos. A plataforma pode ser acedida através de uma aplicação web com interface gráfica desenvolvida com o pacote Shiny para R e directamente através de uma REST API desenvolvida com o pacote flask-restful para Python. Toda a aplicação está modularizada através de teconologia de “contentores”, especificamente o Docker. O objectivo desta plataforma é divulgar o acesso aos modelos criados pela comunidade, condensando-os num só local e removendo a necessidade do utilizador de instalar ou parametrizar qualquer tipo de software. Fomentando assim o desenvolvimento de conhecimento e facilitando o processo de investigação.The drug discovery and design process is expensive, time-consuming and resource-intensive. Various in silico methods are used to make the process more efficient and productive. Methods such as Virtual Screening often take advantage of QSAR machine learning models to more easily pinpoint the most promising drug candidates, from large pools of compounds. QSAR, which means Quantitative Structure Activity Relationship, is a ligand-based method where structural information of known ligands of a specific target is used to predict the biological activity of another molecule against that target. They are also used to improve upon an existing molecule’s pharmacologic potential by elucidating the structural composition with desirable properties. Several researchers create and develop QSAR machine learning models for a variety of different therapeutic targets. However, their use is limited by lack of access to said models. Beyond access, there are often difficulties in using published software given the need to manage dependencies and replicating the development environment. To address this issue, the application documented here was designed and developed. In this centralized platform, researchers can access several QSAR machine learning models and test their own datasets for interaction with various therapeutic targets. The platform allows the use of widespread molecule identifiers as input, such as SMILES and InChI, handling the necessary integration into the appropriate molecular descriptors to be used in the model. The platform can be accessed through a Web Application with a full graphical user interface developed with the R package Shiny and through a REST API developed with the Flask Restful package for Python. The complete application is packaged up in container technology, specifically Docker. The main goal of this platform is to grant widespread access to the QSAR models developed by the scientific community, by concentrating them in a single location and removing the user’s need to install or set up software unfamiliar to them. This intends to incite knowledge creation and facilitate the research process

Chemical information matters: an e-Research perspective on information and data sharing in the chemical sciences

Recently, a number of organisations have called for open access to scientific information and especially to the data obtained from publicly funded research, among which the Royal Society report and the European Commission press release are particularly notable. It has long been accepted that building research on the foundations laid by other scientists is both effective and efficient. Regrettably, some disciplines, chemistry being one, have been slow to recognise the value of sharing and have thus been reluctant to curate their data and information in preparation for exchanging it. The very significant increases in both the volume and the complexity of the datasets produced has encouraged the expansion of e-Research, and stimulated the development of methodologies for managing, organising, and analysing "big data". We review the evolution of cheminformatics, the amalgam of chemistry, computer science, and information technology, and assess the wider e-Science and e-Research perspective. Chemical information does matter, as do matters of communicating data and collaborating with data. For chemistry, unique identifiers, structure representations, and property descriptors are essential to the activities of sharing and exchange. Open science entails the sharing of more than mere facts: for example, the publication of negative outcomes can facilitate better understanding of which synthetic routes to choose, an aspiration of the Dial-a-Molecule Grand Challenge. The protagonists of open notebook science go even further and exchange their thoughts and plans. We consider the concepts of preservation, curation, provenance, discovery, and access in the context of the research lifecycle, and then focus on the role of metadata, particularly the ontologies on which the emerging chemical Semantic Web will depend. Among our conclusions, we present our choice of the "grand challenges" for the preservation and sharing of chemical information

Text-basierte Ähnlichkeitssuche zur Treffer- und Leitstruktur-Identifizierung

This work investigated the applicability of global pairwise sequence alignment to the detection of functional analogues in virtual screening. This variant of sequence comparison was developed for the identification of homologue proteins based on amino acid or nucleotide sequences. Because of the significant differences between biopolymers and small molecules several aspects of this approach for sequence comparison had to be adapted. All proposed concepts were implemented as the ‘Pharmacophore Alignment Search Tool’ (PhAST) and evaluated in retrospective experiments on the COBRA dataset in version 6.1. The aim to identify functional analogues raised the necessity for identification and classification of functional properties in molecular structures. This was realized by fragment-based atom-typing, where one out of nine functional properties was assigned to each non-hydrogen atom in a structure. These properties were pre-assigned to atoms in the fragments. Whenever a fragment matched a substructure in a molecule, the assigned properties were transferred from fragment atoms to structure atoms. Each functional property was represented by exactly one symbol. Unlike amino acid or nucleotide sequences, small drug-like molecules contain branches and cycles. This was a major obstacle in the application of sequence alignment to virtual screening, since this technique can only be applied to linear sequences of symbols. The best linearization technique was shown to be Minimum Volume Embedding. To the best of knowledge, this work represents the first application of dimensionality reduction to graph linearization. Sequence alignment relies on a scoring system that rates symbol equivalences (matches) and differences (mismatches) based on functional properties that correspond to rated symbols. Existing scoring schemes are applicable only to amino acids and nucleotides. In this work, scoring schemes for functional properties in drug-like molecules were developed based on property frequencies and isofunctionality judged from chemical experience, pairwise sequence alignments, pairwise kernel-based assignments and stochastic optimization. The scoring system based on property frequencies and isofunctionality proved to be the most powerful (measured in enrichment capability). All developed scoring systems performed superior compared to simple scoring approaches that rate matches and mismatches uniformly. The frameworks proposed for score calculations can be used to guide modifications to the atom-typing in promising directions. The scoring system was further modified to allow for emphasis on particular symbols in a sequence. It was proven that the application of weights to symbols that correspond to key interaction points important to receptor-ligand-interaction significantly improves screening capabilities of PhAST. It was demonstrated that the systematic application of weights to all sequence positions in retrospective experiments can be used for pharmacophore elucidation. A scoring system based on structural instead of functional similarity was investigated and found to be suitable for similarity searches in shape-constrained datasets. Three methods for similarity assessment based on alignments were evaluated: Sequence identity, alignment score and significance. PhAST achieved significantly higher enrichment with alignment scores compared to sequence identity. p-values as significance estimates were calculated in a combination of Marcov Chain Monte Carlo Simulation and Importance Sampling. p-values were adapted to library size in a Bonferroni correction, yielding E-values. A significance threshold of an E-value of 1*10-5 was proposed for the application in prospective screenings. PhAST was compared to state-of-the-art methods for virtual screening. The unweighted version was shown to exhibit comparable enrichment capabilities. Compound rankings obtained with PhAST were proven to be complementary to those of other methods. The application to three-dimensional instead of two-dimensional molecular representations resulted in altered compound rankings without increased enrichment. PhAST was employed in two prospective applications. A screening for non-nucleoside analogue inhibitors of bacterial thymidin kinase yielded a hit with a distinct structural framework but only weak activity. The search for drugs not member of the NSAID (non-steroidal anti-inflammatory drug) class as modulators of gamma-secretase resulted in a potent modulator with clear structural distiction from the reference compound. The calculation of significance estimates, emphasizing on key interactions, the pharmacophore elucidation capabilities and the unique compound rannkings set PhAST apart from other screening techniques.In dieser Arbeit wurde die Anwendbarkeit von paarweisem globalen Sequenzalignment auf das Problem des Molekülsvergleichs im virtuellen Screening untersucht, einem Teilgebiet der computerbasierten Wirkstoffentwicklung. Sequenzalignment wurde zur Identifizierung homologer Proteine entwickelt. Bisher wurde es nur angewendet auf Sequenzen aus Aminosäuren oder Nukleotiden. Aufgrund der Unterschiede zwischen Biopolymeren und wirkstoffartigen Molekülen wurde dieser Ansatz zum Sequenzvergleich modifiziert und auf die konkrete Problemstellung angepasst. Alle vorgestellten und untersuchten Methoden wurden implementiert unter dem Namen ‚Pharmacophore Alignment Search Tool’ (PhAST). Zielsetzung bei der Entwicklung von PhAST war es, die funktionelle Ähnlichkeit zwischen Molekülen zu berechnen. Dafür war es notwendig, einen Ansatz zu implementieren, der den Atomen eines Moleküls funktionelle Eigenschaften zuweist. Dies wurde realisiert durch eine auf Fragmenten basierende Atomtypisierung. Den Atomen einer Sammlung vordefinierter Fragmente wurden nach bestem Wissen und Gewissen Eigenschaften zugewiesen. In jedem Fall, in dem eines der Fragmente als Substruktur eines Moleküls auftrat, wurden die Atomtypisierungen von dem jeweiligen Fragment auf die Atome des Moleküls übertragen. Insgesamt unterscheidet PhAST neun funktionelle Eigenschaften und deren Kombination, wobei jedem Atomtyp genau ein Symbol zugeordnet ist. Im Gegensatz zu Sequenzen von Aminosäuren und Nukleotiden sind wirkstoffartige Moleküle verzweigt, ungerichtet und enthalten Ringeschlüsse. Sequenzalignment ist aber ausschließlich auf lineare Sequenzen anwendbar. Folglich mussten Moleküle mit ihren funktionellen Eigenschaften zunächst in einer linearisierten Form gespeichert werden. Es wurde gezeigt, dass Minimum Volume Embedding die performanteste der getesteten Linearisierungsmethoden war. Nach bestem Wissen und Gewissen wurden in dieser Arbeit zum ersten mal Methoden zur Dimensionsreduktion auf das Problem der kanonischen Indizierung von Graphen angewendet. Zur Berechnung von Sequenzalignments ist ein Bewertungssystem von Equivalenzen und Unterschieden von Symbolen notwendig. Die bestehenden Systeme sind nur anwendbar auf Aminosäuren und Nukleotide. Daher wurde ein Bewertungssystem für Atomeigenschaften nach chemischer Intuition entwickelt, sowie drei automatisierte Methoden, solche Systeme zu berechnen. Das nach chemischer Intuition erstellte Bewertungsschema wurde als den anderen signifikant überlegen identifiziert. Die Flexibilität des Bewertungssystems in globalem Sequenzalignment machte es möglich, Symbole die berechneten Alignments stärker beeinflussen zu lassen, von denen bekannt war, dass sie für essentielle Wechselwirkungen in der Rezeptor-Ligand-Interaktion stehen. Es wurde gezeigt, dass diese Gewichtung die Screening Fähigkeiten von PhAST signifikant steigerte. Weiterhin konnte gezeigt werden, dass PhAST mit der systematischen Anwendung von Gewichten auf alle Sequenzpositionen in der Lage war, essentielle Wechselwirkungen für die Rezeptor-Ligand-Interaktion zu identifizieren. Bedingung hierfür war jedoch, dass ein geeigneter Datensatz mit aktiven und inaktiven Substanzen zur Verfügung stand. In dieser Arbeit wurden verschiedene Methoden evaluiert, mit denen aus Alignments Ähnlichkeiten berechnet werden können: Sequenzidentität, Alignment Score und p-Werte. Es wurde gezeigt, dass der Alignmentscore der Sequenzidentität für die Verwendung in PhAST signifikant überlegen ist. Für die Berechnung von p-Werten zur Bestimmung der Signfifikanz von Alignments musste zunächst die Verteilung von Alignment Scores für zufällige Sequenzen bestimmter Längen bestimmt werden. Dies geschah mit einer Kombination aus ‚Marcov Chain Monte Carlo Simulation’ und ‚Importance Sampling’. Die berechneten p-Werte wurden einer Bonferroni Korrektur unterzogen, und so unter Berücksichtigung der Gesamtzahl von im virtuellen Screening verglichenen Molekülen zu E-Werten. Als Ergebnis dieser Arbeit wird ein E-Wert von 1*10-5 als Grenzwert vorgeschlagen, wobei Alignments mit geringeren E-Werten als signifikant anzuerkennen sind. PhAST wurde in retrospektiven Screening mit anderen Methoden zum virtuellen Screening verglichen. Es konnte gezeigt werden, dass seine Fähigkeiten zur Identifizierung funktioneller Analoga mit denen der besten anderen Methoden vergleichbar oder ihnen sogar überlegen ist. Es konnte gezeigt werden, dass nach von PhAST berechneten Ähnlichkeiten sortierte Molekülsammlungen von den Sortierungen anderer Methoden abweichen. Im Rahmen dieser Arbeit wurde PhAST erfolgreich in zwei prospektiven Anwendungen eingesetzt. So wurde ein schwacher Inhibitor der bakteriellen Thymidinkinase identifiziert, der kein Nukleosid Analogon ist. In einem Screening nach Modulatoren der Gamma-Sekretase wurde ein potentes Molekül identifiziert, das deutliche strukturelle Unterschiede zur verwendeten Referenz aufwies

Information retrieval and text mining technologies for chemistry

Efficient access to chemical information contained in scientific literature, patents, technical reports, or the web is a pressing need shared by researchers and patent attorneys from different chemical disciplines. Retrieval of important chemical information in most cases starts with finding relevant documents for a particular chemical compound or family. Targeted retrieval of chemical documents is closely connected to the automatic recognition of chemical entities in the text, which commonly involves the extraction of the entire list of chemicals mentioned in a document, including any associated information. In this Review, we provide a comprehensive and in-depth description of fundamental concepts, technical implementations, and current technologies for meeting these information demands. A strong focus is placed on community challenges addressing systems performance, more particularly CHEMDNER and CHEMDNER patents tasks of BioCreative IV and V, respectively. Considering the growing interest in the construction of automatically annotated chemical knowledge bases that integrate chemical information and biological data, cheminformatics approaches for mapping the extracted chemical names into chemical structures and their subsequent annotation together with text mining applications for linking chemistry with biological information are also presented. Finally, future trends and current challenges are highlighted as a roadmap proposal for research in this emerging field.A.V. and M.K. acknowledge funding from the European Community’s Horizon 2020 Program (project reference: 654021 - OpenMinted). M.K. additionally acknowledges the Encomienda MINETAD-CNIO as part of the Plan for the Advancement of Language Technology. O.R. and J.O. thank the Foundation for Applied Medical Research (FIMA), University of Navarra (Pamplona, Spain). This work was partially funded by Consellería de Cultura, Educación e Ordenación Universitaria (Xunta de Galicia), and FEDER (European Union), and the Portuguese Foundation for Science and Technology (FCT) under the scope of the strategic funding of UID/BIO/04469/2013 unit and COMPETE 2020 (POCI-01-0145-FEDER-006684). We thank Iñigo Garciá -Yoldi for useful feedback and discussions during the preparation of the manuscript.info:eu-repo/semantics/publishedVersio

Substructural Analysis Using Evolutionary Computing Techniques

Substructural analysis (SSA) was one of the very first machine learning techniques to be applied to chemoinformatics in the area of virtual screening. For this method, given a set of compounds typically defined by their fragment occurrence data (such as 2D fingerprints). The SSA computes weights for each of the fragments which outlines its contribution to the activity (or inactivity) of compounds containing that fragment. The overall probability of activity for a compound is then computed by summing up or combining the weights for the fragments present in the compound. A variety of weighting schemes based on specific relationship-bound equations are available for this purpose. This thesis identifies uplift to the effectiveness of SSA, using two evolutionary computation methods based on genetic traits, particularly the genetic algorithm (GA) and genetic programming (GP). Building on previous studies, it was possible to analyse and compare ten published SSA weighting schemes based on a simulated virtual screening experiment. The analysis showed the most effective weighting scheme to be the R4 equation which was a part of document-based weighting schemes. A second experiment was carried out to investigate the application of GA-based weighting scheme for the SSA in comparison to an experiment using the R4 weighting scheme. The GA algorithm is simple in concept focusing purely on suitable weight generation and effective in operation. The findings show that the GA-based SSA is superior to the R4-based SSA, both in terms of active compound retrieval rate and predictive performance. A third experiment investigated the genetic application via a GP-based SSA. Rigorous experiment results showed that the GP was found to be superior to the existing SSA weighting schemes. In general, however, the GP-based SSA was found to be less effective than the GA-based SSA. A final experimented is described in this thesis which sought to explore the feasibility of data fusion on both the GA and GP. It is a method producing a final ranking list from multiple sets of ranking lists, based on several fusion rules. The results indicate that data fusion is a good method to boost GA-and GP-based SSA searching. The RKP rule was considered the most effective fusion rule

April 13, 1978, Ohio University Board of Trustees Meeting Minutes

Meeting minutes document the activities of Ohio University\u27s Board of Trustees