| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 599045 | Colloids and Surfaces B: Biointerfaces | 2016 | 8 Pages |
•Succinic anhydride gives a reliable surface modification for silicon-based biosensing.•High surface density of immobilized active biomolecules has been achieved.•Biomolecules functionality was investigated through an ELISA-like bioassay.•Exposed carboxylic groups were activated through an optimized EDC/NHS protocol.•Signal to noise ratio has been maximized for biosensing applications.
A well-organized immobilization of bio-receptors is a crucial goal in biosensing, especially to achieve high reproducibility, sensitivity and specificity. These requirements are usually attained with a controlled chemical/biochemical functionalization that creates a stable layer on a sensor surface. In this work, a chemical modification protocol for silicon-based surfaces to be applied in biosensing devices is presented. An anhydrous silanization step through 3-aminopropylsilane (APTES), followed by a further derivatization with succinic anhydride (SA), is optimized to generate an ordered flat layer of carboxylic groups. The properties of APTES/SA modified surface were compared with a functionalization in which glutaraldehyde (GA) is used as crosslinker instead of SA, in order to have a comparison with an established and largely applied procedure. Moreover, a functionalization based on the controlled deposition of a plasma polymerized acrylic acid (PPAA) thin film was used as a reference for carboxylic reactivity. Advantages and drawbacks of the considered methods are highlighted, through physico-chemical characterizations (OCA, XPS, and AFM) and by means of a functional Protein G/Antibody immunoassay. These analyses reveal that the most homogeneous, reproducible and active surface is achieved by using the optimized APTES/SA coupling.
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