Porous silicon optical filters for biosensing applications

Abstract

The surface of nanostructured silicon (porous silicon) was biofunctionalized by the deposition of 3-aminopropyltriethoxysilane from solution, leading to high density of amine groups covering the surface which would promote the further immobilization of biomolecules. In addition, porous silicon Bragg reflectors were developed for their use in the visible range. The optical behavior of these structures was previously designed by the use of a computational program, from which the optical constants and thickness of the individual porous silicon layers were determined. The possibility of using these structures as biosensors has been explored, based on the significant changes in the reflectance spectra before and after exposing the porous silicon optical structures to biomolecules. In particular, it is shown that there is a notable shift of the reflectance maximum associated to the Bragg reflector after immobilization of polyclonal mouse antibodies. Thus, the experimental results open the possibility of developing biosensors based on the variation of the position of the optical spectrum of porous silicon based devices.