Toward an efficient workflow for the analysis of the human milk peptidome

There is a growing interest for investigating endogenous peptides from human biofluids which may provide yet unknown functional benefits or provide an early indication of disease states as potential biomarkers. A major technical bottleneck in the investigation of endogenous peptides from body fluids...

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Veröffentlicht in:	Analytical and bioanalytical chemistry 2019-03, Vol.411 (7), p.1351-1363
Hauptverfasser:	Dingess, Kelly A., van den Toorn, Henk W. P., Mank, Marko, Stahl, Bernd, Heck, Albert J. R.
Format:	Artikel
Sprache:	eng
Schlagworte:	Analysis Analytical Chemistry Baby foods Biochemistry Biological markers Biomarkers blood serum Body fluids Breast milk Carbohydrates Characterization and Evaluation of Materials Chemistry Chemistry and Materials Science Composition Cost analysis cost effectiveness dissociation EDTA Food Science Fragmentation Laboratory Medicine Lipids Milk Monitoring/Environmental Analysis neonates Newborn infants Peptides Precipitation (Meteorology) Proteins protocols Research Paper Retirement benefits Saccharides Saliva Sample preparation Test procedures Urine Workflow Workflow software
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container_title	Analytical and bioanalytical chemistry
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creator	Dingess, Kelly A. van den Toorn, Henk W. P. Mank, Marko Stahl, Bernd Heck, Albert J. R.
description	There is a growing interest for investigating endogenous peptides from human biofluids which may provide yet unknown functional benefits or provide an early indication of disease states as potential biomarkers. A major technical bottleneck in the investigation of endogenous peptides from body fluids, e.g., serum, urine, saliva, and milk, is that each of these fluids seems to require unique workflows for peptide extraction and analysis. Thus, protocols optimized for serum cannot be directly translated to milk. One biofluid that is readily available, but which has not been extensively explored, is human milk, whose analysis could contribute to our understanding of the immune development of the newborn infant. Due to the occurrence of highly abundant lipids, proteins, and saccharides, milk peptidomics requires dedicated sample preparation steps. The aim of this study was to develop a time and cost-efficient workflow for the analysis of the human milk peptidome, for which we compared peptide extraction methodologies and peptide fragmentation methods. A method using strong acid protein precipitation and analysis by collision-induced dissociation fragmentation was found to be superior to all other test methods, allowing us qualitative and quantitative detection of about 4000 endogenous human milk peptides in a total analysis time of just 18 h.
doi_str_mv	10.1007/s00216-018-01566-4
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subjects	Analysis Analytical Chemistry Baby foods Biochemistry Biological markers Biomarkers blood serum Body fluids Breast milk Carbohydrates Characterization and Evaluation of Materials Chemistry Chemistry and Materials Science Composition Cost analysis cost effectiveness dissociation EDTA Food Science Fragmentation Laboratory Medicine Lipids Milk Monitoring/Environmental Analysis neonates Newborn infants Peptides Precipitation (Meteorology) Proteins protocols Research Paper Retirement benefits Saccharides Saliva Sample preparation Test procedures Urine Workflow Workflow software
title	Toward an efficient workflow for the analysis of the human milk peptidome
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