about
The Size of the Human Proteome: The Width and Depth[Identification of cytochromes P450 in the human liver microsomes by mass spectrometry].Highly sensitive protein detection by combination of atomic force microscopy fishing with charge generation and mass spectrometry analysis.Affinity-based proteomic profiling: problems and achievements.Development of mass spectrometry selected reaction monitoring method for quantitation and pharmacokinetic study of stepharine in rabbit plasma.Dataset of target mass spectromic proteome profiling for human chromosome 18.Exome-based proteogenomics of HEK-293 human cell line: Coding genomic variants identified at the level of shotgun proteome.State of the Art of Chromosome 18-Centric HPP in 2016: Transcriptome and Proteome Profiling of Liver Tissue and HepG2 Cells.Methionine to isothreonine conversion as a source of false discovery identifications of genetically encoded variants in proteogenomics.Chromosome 18 transcriptoproteome of liver tissue and HepG2 cells and targeted proteome mapping in depleted plasma: update 2013.Targeted Quantitative Screening of Chromosome 18 Encoded Proteome in Plasma Samples of Astronaut Candidates.Human urinary renalase lacks the N-terminal signal peptide crucial for accommodation of its FAD cofactor.Highly sensitive protein detection by biospecific AFM-based fishing with pulsed electrical stimulation.Constitutive and activation-dependent phosphorylation of lymphocyte phosphatase-associated phosphoprotein (LPAP).A semi-virtual two dimensional gel electrophoresis: IF-ESI LC-MS/MS.The effects of endogenous non-peptide molecule isatin and hydrogen peroxide on proteomic profiling of rat brain amyloid-β binding proteins: relevance to Alzheimer's disease?Why Are the Correlations between mRNA and Protein Levels so Low among the 275 Predicted Protein-Coding Genes on Human Chromosome 18?Isatin-binding proteins of rat and mouse brain: proteomic identification and optical biosensor validation.Isatin binding proteins in rat brain: in situ imaging, quantitative characterization of specific [3H]isatin binding, and proteomic profiling.Variety and Dynamics of Proteoforms in the Human Proteome: Aspects of Markers for Hepatocellular Carcinoma.Chemical modifications of amyloid-β(1-42) have a significant impact on the repertoire of brain amyloid-β(1-42) binding proteins.Quantitative assessment of betamethasone dual-acting formulation in urine of patients with rheumatoid arthritis and ankylosing spondylitis after single-dose intramuscular administration and its application to long-term pharmacokinetic study.Identification of Peptide AEDG in the Polypeptide Complex of the Pineal Gland.Effect of affinity sorbent on proteomic profiling of isatin-binding proteins of mouse brain.Amyloid-binding proteins: affinity-based separation, proteomic identification, and optical biosensor validation.A multicentric study to evaluate the use of relative retention times in targeted proteomics.Brochosomins and other novel proteins from brochosomes of leafhoppers (Insecta, Hemiptera, Cicadellidae).Renalase Secreted by Human Kidney HEK293T Cells Lacks its N-Terminal Peptide: Implications for Putative Mechanisms of Renalase Action.FractionOptimizer: a method for optimal peptide fractionation in bottom-up proteomics.[A plain method of prediction of visibility of peptides in mass spectrometry with electrospray ionization].Proteomic Analysis of Cerebral Cortex Extracts from Sus scrofa with Induced Hemorrhagic Stroke.[Next-Generation Techniques for Discovering Human Monoclonal Antibodies].Serum Immunoproteomics Combined With Pathological Reassessment of Surgical Specimens Identifies TCP-1ζ Autoantibody as a Potential Biomarker in Thyroid Neoplasia.Proteomics of mouse liver microsomes: performance of different protein separation workflows for LC-MS/MS.Next Steps on in Silico 2DE Analyses of Chromosome 18 ProteoformsIncreased Sensitivity of Mass-spectrometry by alkaline 2D-LC: It is Way to Deep Cover of Human Proteome in Gene-centric ModeProteomic profiling data of HEK293 proteins bound to human recombinant renalases-1 and -2Chromosome 18 Transcriptome Profiling and Targeted Proteome Mapping in Depleted Plasma, Liver Tissue and HepG2 Cells[Mitochondrial ATP-dependent potassium channel. 1. The structure of the channel, the mechanisms of its functioning and regulation][Methods of quantitative proteomics]
P50
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P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
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հետազոտող
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name
Arthur Kopylov
@ast
Arthur Kopylov
@en
Arthur Kopylov
@es
Arthur Kopylov
@nl
Artur Tigranowitsch Kopylow
@de
Артур Тигранович Копылов
@ru
type
label
Arthur Kopylov
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Arthur Kopylov
@en
Arthur Kopylov
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Arthur Kopylov
@nl
Artur Tigranowitsch Kopylow
@de
Артур Тигранович Копылов
@ru
altLabel
Arthur T. Kopylov
@en
Artur Kopylow
@de
prefLabel
Arthur Kopylov
@ast
Arthur Kopylov
@en
Arthur Kopylov
@es
Arthur Kopylov
@nl
Artur Tigranowitsch Kopylow
@de
Артур Тигранович Копылов
@ru
P108
P1053
E-3288-2012
P106
P108
P1153
22980421100
P21
P31
P3829
P3835
arthur-t-kopylov
P496
0000-0002-7199-372X