Development of sensors for direct detection of organophosphates. Part I: immobilization, characterization and stabilization of acetylcholinesterase and organophosphate hydrolase on silica supports

Biosensors for organophosphates in solution may be constructed by monitoring the activity of acetylcholinesterase (AChE) or organophosphate hydrolase (OPH) immobilized to a variety of microsensor platforms. The area available for enzyme immobilization is small (<1 mm 2) for microsensors. In order...

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Published in:	Biosensors & bioelectronics Vol. 14; no. 8; pp. 703 - 713
Main Authors:	Singh, A.K, Flounders, A.W, Volponi, J.V, Ashley, C.S, Wally, K, Schoeniger, J.S
Format:	Journal Article
Language:	English
Published:	Lausanne Elsevier B.V 01-12-1999 Elsevier Science
Subjects:	Acetylcholinesterase AChE Aldehydes Amines Biological and medical sciences Biosensing Techniques - methods Biosensors Biotechnology Catalyst activity Catalyst supports Electronic medical equipment EnFET Enzyme Enzyme immobilization Enzyme Stability Enzymes, Immobilized Evaluation Studies as Topic FET Field effect transistors Fundamental and applied biological sciences. Psychology Gels Immobilization ISFET Methods. Procedures. Technologies Microscopy, Electron, Scanning Microspheres OPH Organophosphate Organophosphate hydrolase Organophosphorus Compounds - analysis Particle Size pHFET Phosphates Phosphoric Monoester Hydrolases Porosity Sensor Silicon Dioxide Sol-gels Sol–gel Various methods and equipments ISFET AChE Enzyme OPH Immobilization Acetylcholinesterase pHFET EnFET Organophosphate FET Organophosphate hydrolase Sol–gel Sensor Stability Microsensor Esterases Silica Carboxylic ester hydrolases Phosphoric triester hydrolases Enzymatic activity Sol gel process Biosensor Hydrolases Organophosphorus compounds Aryldialkylphosphatase Immobilized enzyme
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Summary:	Biosensors for organophosphates in solution may be constructed by monitoring the activity of acetylcholinesterase (AChE) or organophosphate hydrolase (OPH) immobilized to a variety of microsensor platforms. The area available for enzyme immobilization is small (<1 mm 2) for microsensors. In order to construct microsensors with increased surface area for enzyme immobilization, we used a sol–gel process to create highly porous and stable silica matrices. Surface porosity of sol–gel coated surfaces was characterized using scanning electron microscopy; pore structure was found to be very similar to that of commercially available porous silica supports. Based upon this analysis, porous and non-porous silica beads were used as model substrates of sol–gel coated and uncoated sensor surfaces. Two different covalent chemistries were used to immobilize AChE and OPH to these porous and non-porous silica beads. The first chemistry used amine-silanization of silica followed by enzyme attachment using the homobifunctional linker glutaraldehyde. The second chemistry used sulfhydryl-silanization followed by enzyme attachment using the heterobifunctional linker N-γ-maleimidobutyryloxy succinimide ester (GMBS). Surfaces were characterized in terms of total enzyme immobilized, total and specific enzyme activity, and long term stability of enzyme activity. Amine derivitization followed by glutaraldehyde linking yielded supports with greater amounts of immobilized enzyme and activity. Use of porous supports not only yielded greater amounts of immobilized enzyme and activity, but also significantly improved long term stability of enzyme activity. Enzyme was also immobilized to sol–gel coated glass slides. The mass of immobilized enzyme increased linearly with thickness of coating. However, immobilized enzyme activity saturated at a porous silica thickness of approximately 800 nm.
Bibliography:	ObjectType-Article-2 SourceType-Scholarly Journals-1 ObjectType-Feature-1 content type line 23 ObjectType-Article-1 ObjectType-Feature-2
ISSN:	0956-5663 1873-4235
DOI:	10.1016/S0956-5663(99)00044-5