EDTA-functionalized magnetic nanoparticles: A suitable platform for the analysis of low abundance urinary proteins.
暂无分享,去创建一个
A. Leite-Moreira | B. Manadas | R. Vitorino | A. L. Daniel-da-Silva | R. Ferreira | Fábio Trindade | I. Falcão-Pires | P. Bastos | A. Daniel-da-Silva
[1] Núria Malats,et al. Large-Scale SRM Screen of Urothelial Bladder Cancer Candidate Biomarkers in Urine. , 2017, Journal of proteome research.
[2] Emmanuelle Plaisier,et al. Multiplex and accurate quantification of acute kidney injury biomarker candidates in urine using Protein Standard Absolute Quantification (PSAQ) and targeted proteomics. , 2017, Talanta.
[3] Bruno Manadas,et al. SWATH‐MS as a tool for biomarker discovery: From basic research to clinical applications , 2017, Proteomics.
[4] M. Harpole,et al. Current state of the art for enhancing urine biomarker discovery , 2016, Expert review of proteomics.
[5] B. Manadas,et al. A reference library of peripheral blood mononuclear cells for SWATH‐MS analysis , 2016, Proteomics. Clinical applications.
[6] Lisa M. Chung,et al. Development of a Targeted Urine Proteome Assay for kidney diseases , 2016, Proteomics. Clinical applications.
[7] A. Nayır,et al. Neutrophil Gelatinase-Associated Lipocalin as an Early Sign of Diabetic Kidney Injury in Children , 2015, Journal of clinical research in pediatric endocrinology.
[8] R. Vitorino,et al. Toward the definition of a peptidome signature and protease profile in chronic periodontitis , 2015, Proteomics. Clinical applications.
[9] Arturo A. Keller,et al. EDTA functionalized magnetic nanoparticle sorbents for cadmium and lead contaminated water treatment. , 2015, Water research.
[10] A. Vlahou,et al. Comparison of Depletion Strategies for the Enrichment of Low-Abundance Proteins in Urine , 2015, PloS one.
[11] Darryl B. Hardie,et al. Precise quantitation of 136 urinary proteins by LC/MRM-MS using stable isotope labeled peptides as internal standards for biomarker discovery and/or verification studies. , 2015, Methods.
[12] Haojie Lu,et al. Selective enrichment of metal-binding proteins based on magnetic core/shell microspheres functionalized with metal cations. , 2015, The Analyst.
[13] Siok Ghee Ler,et al. Highly sensitive and specific novel biomarkers for the diagnosis of transitional bladder carcinoma , 2015, Oncotarget.
[14] B. Manadas,et al. Short GeLC‐SWATH: A fast and reliable quantitative approach for proteomic screenings , 2015, Proteomics.
[15] María Martín,et al. UniProt: A hub for protein information , 2015 .
[16] R. Vitorino,et al. Magnetic chelating nanoprobes for enrichment and selective recovery of metalloproteases from human saliva. , 2015, Journal of materials chemistry. B.
[17] Harald Mischak,et al. Advances in urinary proteome analysis and applications in systems biology. , 2014, Bioanalysis.
[18] G. Candiano,et al. From hundreds to thousands: Widening the normal human Urinome , 2014, Data in brief.
[19] Yongsheng Ji,et al. Ti4+-immobilized multilayer polysaccharide coated magnetic nanoparticles for highly selective enrichment of phosphopeptides. , 2014, Journal of materials chemistry. B.
[20] T. Verbiest,et al. Selective uptake of rare earths from aqueous solutions by EDTA-functionalized magnetic and nonmagnetic nanoparticles. , 2014, ACS applied materials & interfaces.
[21] António S. Barros,et al. Pursuing type 1 diabetes mellitus and related complications through urinary proteomics. , 2014, Translational research : the journal of laboratory and clinical medicine.
[22] Christoph B. Messner,et al. A new type of metal chelate affinity chromatography using trivalent lanthanide ions for phosphopeptide enrichment. , 2013, The Analyst.
[23] S. Mohammed,et al. Robust phosphoproteome enrichment using monodisperse microsphere–based immobilized titanium (IV) ion affinity chromatography , 2013, Nature Protocols.
[24] Y. Zhang,et al. Ti4+‐Immobilized Magnetic Composite Microspheres for Highly Selective Enrichment of Phosphopeptides , 2013 .
[25] L. Pączek,et al. Urine proteome of autosomal dominant polycystic kidney disease patients , 2012, Clinical Proteomics.
[26] Shalini Kumari,et al. Virtual screening and evaluation of Ketol-Acid Reducto-Isomerase (KARI) as a putative drug target for Aspergillosis , 2012, Clinical Proteomics.
[27] Ludovic C. Gillet,et al. Targeted Data Extraction of the MS/MS Spectra Generated by Data-independent Acquisition: A New Concept for Consistent and Accurate Proteome Analysis* , 2012, Molecular & Cellular Proteomics.
[28] Weidong Zhou,et al. Multifunctional Core–Shell Nanoparticles: Discovery of Previously Invisible Biomarkers , 2011, Journal of the American Chemical Society.
[29] T. Ruml,et al. Purification of proteins containing zinc finger domains using immobilized metal ion affinity chromatography. , 2011, Protein expression and purification.
[30] M. Nagano,et al. Metal-binding ability of human prion protein fragment peptides analyzed by column switch HPLC. , 2011, Chemical & pharmaceutical bulletin.
[31] M. Mann,et al. Quantitative analysis of the intra- and inter-individual variability of the normal urinary proteome. , 2011, Journal of proteome research.
[32] Kristin L Cheek,et al. Depletion of abundant plasma proteins and limitations of plasma proteomics. , 2010, Journal of proteome research.
[33] D. S. Hage,et al. Immunoaffinity chromatography: an introduction to applications and recent developments. , 2010, Bioanalysis.
[34] Juri Rappsilber,et al. Improved results in proteomics by use of local and peptide-class specific false discovery rates , 2009, BMC Bioinformatics.
[35] Pornpimol Charoentong,et al. ClueGO: a Cytoscape plug-in to decipher functionally grouped gene ontology and pathway annotation networks , 2009, Bioinform..
[36] W. Alkema,et al. BioVenn – a web application for the comparison and visualization of biological lists using area-proportional Venn diagrams , 2008, BMC Genomics.
[37] Sean L Seymour,et al. Nonlinear fitting method for determining local false discovery rates from decoy database searches. , 2008, Journal of proteome research.
[38] G. Hortin,et al. Diagnostic potential for urinary proteomics. , 2007, Pharmacogenomics.
[39] M. Mann,et al. The human urinary proteome contains more than 1500 proteins, including a large proportion of membrane proteins , 2006, Genome Biology.
[40] J. Granger,et al. Albumin depletion of human plasma also removes low abundance proteins including the cytokines , 2005, Proteomics.
[41] F. Regnier,et al. Reduction of non-specific binding in Ga(III) immobilized metal affinity chromatography for phosphopeptides by using endoproteinase glu-C as the digestive enzyme. , 2005, Journal of chromatography. B, Analytical technologies in the biomedical and life sciences.
[42] P. Shannon,et al. Cytoscape: a software environment for integrated models of biomolecular interaction networks. , 2003, Genome research.
[43] E. K. Ueda,et al. Current and prospective applications of metal ion-protein binding. , 2003, Journal of chromatography. A.
[44] L. Hagel,et al. Gel‐Filtration Chromatography , 1998, Current protocols in protein science.
[45] U. K. Laemmli,et al. Cleavage of Structural Proteins during the Assembly of the Head of Bacteriophage T4 , 1970, Nature.
[46] A. Jungbauer,et al. Ion-exchange chromatography. , 2009, Methods in enzymology.
[47] F. Regnier,et al. Histidine-rich peptide selection and quantification in targeted proteomics. , 2004, Journal of proteome research.
[48] Cathy H. Wu,et al. UniProt: the Universal Protein knowledgebase , 2004, Nucleic Acids Res..