Development of chemically modified glass surfaces for nucleic acid, protein and small molecule microarrays

Microarrays have become a widely used tool to investigate the living cell at different levels. DNA microarrays enable the expression analysis of thousand of genes simultaneously, while protein arrays investigate the properties and interactions of proteins with other proteins and with non-proteinaceo...

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Veröffentlicht in:	Molecular diversity 2003, Vol.7 (1), p.25-36
Hauptverfasser:	Hackler, Jr, László, Dormán, György, Kele, Zoltán, Urge, László, Darvas, Ferenc, Puskás, László G
Format:	Artikel
Sprache:	eng
Schlagworte:	Deoxyribonucleic acid DNA Equipment Design Glass Mass spectrometry Oligonucleotide Array Sequence Analysis - methods Protein Array Analysis - methods
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container_end_page	36
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container_title	Molecular diversity
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creator	Hackler, Jr, László Dormán, György Kele, Zoltán Urge, László Darvas, Ferenc Puskás, László G
description	Microarrays have become a widely used tool to investigate the living cell at different levels. DNA microarrays enable the expression analysis of thousand of genes simultaneously, while protein arrays investigate the properties and interactions of proteins with other proteins and with non-proteinaceous molecules. One crucial step in producing such microarrays is the permanent immobilization of samples on a solid surface. Our goal was to develop diverse linker systems capable of anchoring different biological samples, especially DNA and drug-like small molecules. We developed 6 different chemical surfaces having a 3-D-like linker system for biomolecule immobilization, and compared them to previously described immobilization strategies. The attachment chemistry utilizes the amino reactive properties of acrylic and epoxy functions. The capacity of the support was increased by creating a branching structure holding the reactive functions. The method of anchoring was investigated through a model reaction. From HPLC and mass spectrometry measurements we concluded that the covalent binding of DNA occurs through nucleobases. The tested systems offer the capability to permanently immobilize several biomolecular species in an array format.
doi_str_mv	10.1023/B:MODI.0000006534.36417.06
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subjects	Deoxyribonucleic acid DNA Equipment Design Glass Mass spectrometry Oligonucleotide Array Sequence Analysis - methods Protein Array Analysis - methods
title	Development of chemically modified glass surfaces for nucleic acid, protein and small molecule microarrays
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