Your search keyword '"Marius Olah"' showing total 11 results

1. Rapid ADME Filters for Lead Discovery

Author

Tudor I. Oprea, Giuliano Berellini, Scott Boyer, Kim Fejgin, Marius Olah, and Paolo Benedetti

Subjects

MIF-based ADME models, Rule of five (Ro5) as ADME filter, Molecular interaction fields (MIFs), Chemistry, Chemistry (all), Molecular interaction fields, Pharmacology, VolSurf, Clinical pharmacokinetics and toxicological datasets, Rapid ADME filters for lead discovery, Chemical Engineering (all), Lead (geology), Biochemical engineering, ADME

Published

2005

2. Descriptor collision and confusion: Toward the design of descriptors to mask chemical structures

Author

Tudor I. Oprea, Cristian Bologa, Marius Olah, Tharun Kumar Allu, and Michael A. Kappler

Subjects

Models, Molecular, Reverse engineering, Quantitative structure–activity relationship, Databases, Factual, Computer science, Chemistry, Pharmaceutical, Quantitative Structure-Activity Relationship, computer.software_genre, Set (abstract data type), Drug Discovery, medicine, Computer Simulation, Relevance (information retrieval), Physical and Theoretical Chemistry, Confusion, Molecular Structure, Series (mathematics), business.industry, Fingerprint (computing), Pattern recognition, Collision, Computer Science Applications, Models, Chemical, Artificial intelligence, Data mining, medicine.symptom, business, computer

Abstract

We examined "descriptor collision" for several chemical fingerprint systems (MDL 320, Daylight, SMDL), and for a 2D-based descriptor set. For large databases (ChemNavigator and WOMBAT), the smallest collision rate remains around 5%. We systematically increase the "descriptor collision" rate (here termed "descriptor confusion"), in order to design a set of "descriptors to mask chemical structures", DMCS. If effective, a DMCS system would not allow third parties to determine the original chemical structures used to derive the DMCS set (i.e., reverse engineering). Using SMDL keys, the "confusion" rate is increased to 45.6% by eliminating those keys that have a low frequency of occurrence in WOMBAT structures. We applied an automated PLS engine, WB-PLS [Olah et al., J. Comput. Aided Mol. Des., 18 (2004) 437], to 1277 series of structures from 948 targets in WOMBAT, in order to validate the biological relevance of the SMDL descriptors as a potential DMCS set. The "reduced set" of SMDL descriptors has a small loss of modeling power (around 20%) compared to the initial descriptor set, while the collision rate is significantly increased. These results indicate that the development of an effective DMCS is possible. If well documented, DMCS systems would encourage private sector data release (e.g., related to water solubility) and directly benefit public sector science.

Published

2005

3. WOMBAT: World of Molecular Bioactivity

Author

Maria Mracec, Mircea Mracec, Zeno Simon, Tudor I. Oprea, Alina Bora, Marius Olah, Nicoleta G. Hădărugă, Magdalena Banda, Ramona Rad, Ionela Olah, and Liliana Ostopovici

Subjects

Wombat, biology, Computer science, biology.animal, Zoology

Published

2005

4. Strategies for Compound Selection

Author

Marius Olah, Tudor I. Oprea, and Cristian Bologa

Subjects

Models, Molecular, Virtual screening, Databases, Factual, Property (programming), Computer science, Receptors, Drug, In silico, Drug Evaluation, Preclinical, Molecular Conformation, Sampling (statistics), computer.software_genre, Structure-Activity Relationship, Pharmaceutical Preparations, Similarity (network science), Drug Discovery, Cluster Analysis, Computer Simulation, Data mining, Cluster analysis, Throughput (business), computer, Medical Informatics, Selection (genetic algorithm)

Abstract

In-house pharmaceutical collections are no longer sufficient for sampling chemical spaces. As novel bioactive chemotypes are successfully identified by virtual and high -throughput screening, the ability to rapidly sift through large numbers of chemicals prior to acquisition or experiment is required. Strategies for compound selection include some of the following steps: 1.) database assembly ('in silico' inventory); 2a.) structural integrity verification (keep unique structures only); 2b.) limited exploration of alternative chemical representations for the uniques (stereoisomers, tautomers, ionization states); 3.) property and structural filtering (remove unwanted structures); 4.) 3D-structure generation (for virtual screening or 3D-based similarity); 5a.) clustering or statistical design for selection; 5b.) similarity-based selection (if bioactives are known); 5c.) receptor-based selection (if target binding site is known); 6.) add a random subset to the final list.

Published

2004

5. An automated PLS search for biologically relevant QSAR descriptors

Author

Tudor I. Oprea, Marius Olah, and Cristian Bologa

Subjects

Quantitative structure–activity relationship, Databases, Factual, Series (mathematics), Information Storage and Retrieval, Quantitative Structure-Activity Relationship, Individual level, computer.software_genre, Computer Science Applications, Automation, Redundancy (information theory), Fingerprint, Drug Discovery, Data mining, Physical and Theoretical Chemistry, computer, Mathematics, Block (data storage)

Abstract

An automated PLS engine, WB-PLS, was applied to 1632 QSAR series with at least 25 compounds per series extracted from WOMBAT (WOrld of Molecular BioAcTivity). WB-PLS extracts a single Y variable per series, as well as pre-computed X variables from a table. The table contained 2D descriptors, the drug-like MDL 320 keys as implemented in the Mesa A&C Fingerprint module, and in-house generated topological-pharmacophore SMARTS counts and fingerprints. Each descriptor type was treated as a block, with or without scaling. Cross-validation, variable importance on projections (VIP) above 0.8 and q 2⩾0.3 were applied for model significance. Among cross-validation methods, leave-one-in-seven-out (CV7) is a better measure of model significance, compared to leave-one-out (measuring redundancy) and leave-half-out (too restrictive). SMARTS counts overlap with 2D descriptors (having a more quantitative nature), whereas MDL keys overlap with in-house fingerprints (both are more qualitative). The SMARTS counts is the most effective descriptor system, when compared to the other three. At the individual level, size-related descriptors and topological indices (in the 2D property space), and branched SMARTS, aromatic and ring atom types and halogens are found to be most relevant according to the VIP criterion.

Published

2004

6. MTD-PLS: A PLS-Based Variant of the MTD Method. A 3D-QSAR Analysis of Receptor Affinities for a Series of Halogenated Dibenzoxin and Biphenyl Derivatives

Author

Ludovic Kurunczi, Zeno Simon, Marius Olah, and Tudor I. Oprea

Subjects

Steric effects, Quantitative structure–activity relationship, Binding Sites, Maximum Tolerated Dose, Hydrocarbons, Halogenated, Stereochemistry, Chemistry, Aryl, Substituent, Bioengineering, General Medicine, Dioxins, Ligands, Affinities, Dibenzofuran, Structure-Activity Relationship, symbols.namesake, chemistry.chemical_compound, Drug Discovery, Partial least squares regression, symbols, Molecular Medicine, Least-Squares Analysis, van der Waals force

Abstract

MTD-PLS, the Partial Least Squares (PLS) variant of the Minimum Topological Difference (MTD) method is described. In MTD-PLS, molecules are characterised not only by the occupancy or nonoccupancy of the hypermolecular vertices (as in classical MTD), but also by additional descriptors for each vertex: fragmental van der Waals volumes, fragmental hydrophobicities, partial atomic charges, etc. This method was applied to a series of 73 polyhalogenated derivatives of dibenzo-p-dioxine, dibenzofuran and biphenyl (induction of aryl hydrocarbon hydrolase and affinities to rat cytosolic receptor), previously studied by MTD. The separation of steric, hydrophobic, and electrostatic effects was achieved retranslating from the latent variable space into a linear combination of the initial structural variables. The MTD-PLS method yields more detailed results compared to classical MTD, indicating the importance of electrostatic effects at some substituent positions.

Published

2001

7. ChemInform Abstract: MTD-PLS: A PLS-Based Variant of the MTD Method. Part 2. Mapping Ligand-Receptor Interactions. Enzymatic Acetic Esters Hydrolysis

Author

Tudor I. Oprea, Ludovic Kurunczi, Marius Olah, Zeno Simon, and Cristian Bologa

Subjects

chemistry.chemical_classification, Hydrolysis, Enzyme, chemistry, Stereochemistry, General Medicine, Receptor, Ligand (biochemistry)

Published

2010

8. High-Throughput Flow Cytometry

Author

Marius Olah, Anna Waller, Susan M. Young, Sean M. Biggs, Larry A. Sklar, Bruce S. Edwards, Cristian Bologa, Peter C. Simons, Eric R. Prossnitz, and Tudor I. Oprea

Subjects

Cell physiology, Business process discovery, Molecular interactions, Virtual screening, Disk formatting, medicine.diagnostic_test, Computer science, medicine, Computational biology, Throughput (business), Overall efficiency, Flow cytometry

Abstract

This article describes the creation of a discovery team in an academic environment. The team is specifically structured to perform four integrated activities: characterizing membrane protein, formatting the materials for analysis of cell physiology and molecular interactions, performing screens of small-molecule activity on a novel high-throughput flow cytometric instrument platform, and integrating virtual screening with activity screening. These activities improve the overall efficiency of the discovery process. Keywords: discovery team; virtual screening; cell physiology; molecular interactions

Published

2010

9. WOMBAT and WOMBAT-PK: Bioactivity Databases for Lead and Drug Discovery

Author

Marius Olah, Liliana Ostopovici, Nicoleta G. Hădărugă, Tudor I. Oprea, Maria Mractc, Daniel I. Hădărugă, Ramona Rad, Adriana Fuliaş, Alina Bora, and Ramona Moldovan

Subjects

Wombat, Biochemistry, Drug discovery, Hormone receptor, biology.animal, Pharmacology, Biology, Receptor subtype

Published

2008

10. Bioactivity Databases

Author

Tudor I. Oprea and Marius Olah

Subjects

Biological data, Software documentation, Beilstein database, Database, Computer science, computer.software_genre, chemistry.chemical_compound, Identification (information), Index (publishing), chemistry, Cheminformatics, Chemogenomics, computer, Chemical database

Abstract

The current drug discovery paradigm allocates a short period of time (3–12 months) for the process of lead identification. Thus, medicinal chemists have a rather short amount of time to familiarize themselves with prior art i.e., background information related to the biological target and to chemotypes relevant on the intended, or related targets. Gathering such background information is enabled by chemical databases such as Chemical Abstracts via SciFinder, Beilstein and Spresi, by medicinal chemistry related patent databases such as the MDL Drug Data Report, (MDDR), the World Drug Index, (WDI), Current Patents Fast Alert, and by collections of bioactive compounds such as Comprehensive Medicinal Chemistry, and the Physician Desk Reference, (PDR). As pharmaceutical drug discovery relies on chemogenomics, the average end-user has learned to expect database systems with built-in search engines that seamlessly mine chemical and biological data within an information-rich, integrated resource. The integration process itself requires hierarchical classification schemes, such that knowledge related to target-focused chemical libraries and biological target families can be mined simultaneously. Such tools being under development, we address bioactivity databases in general with focus on bioinformatics and cheminformatics resources. Technical details are omitted for clarity. Readers are encouraged to consult the general references, as well as software documentation. The first section, “Databases and Management Systems”, introduces databases in general. The second part, “Bioactivity Databases: Some Design Guidelines” provides guiding principles for designing and maintaining bioactivity databases. The third section “Biological and Bioactivity Information Databases Examples”, provides a brief overview of currently available bioactivity databases.

Published

2007

11. Chemical Database Preparation for Compound Acquisition or Virtual Screening

Author

Cristian Bologa, Tudor I. Oprea, and Marius Olah

Subjects

Virtual screening, Chemotype, Computer science, Structure–activity relationship, Biological activity, Computational biology, Chemical database, Molecular conformation

Abstract

Virtual and high-throughput screening are time-saving techniques that have been successfully applied to identify novel chemotypes in biologically active molecules. Both methods require the ability to aptly handle large numbers of chemicals prior to an experiment or acquisition. We describe a step-by-step preparation procedure for handling large collections of existing or virtual compounds prior to virtual screening or acquisition.

Published

2006