Surface functionalization for self-referencing surface plasmon resonance (SPR) biosensors by multi-step self-assembly

Abstract

Recently, a novel SPR sensor with on-chip referencing has been realized. In this sensor, one-half of the gold sensing surface is covered with a high refractive index overlayer of tantalum pentoxide (Ta 2O 5). When polychromatic beam illuminates the sensing surface, surface plasmon resonance in the areas with and without the overlayer occur at different wavelengths. Therefore, the reflected light exhibits two dips associated with SPRs in those two areas. When functionalized properly, one of the areas can be used as a specific sensing channel for detection of specific bio-interactions and the other can act as a reference channel for compensation for background refractive index fluctuations. In this paper we present a new functionalization approach for these mixed architecture chips. The gold side of the chip is functionalized with a mixed self-assembled monolayer of polyethylene oxide (PEO) and biotin terminated (BAT) thiols whereas the Ta 2O 5 side is coated with PEO terminated silanes. The PEO terminated thiols and silanes serve as a protein resistant background, while the biotin terminated thiols are used to bind streptavidin, which in turn immobilizes biotinylated antibodies. Hence, the gold side of the chip is used for the binding and detection of target analytes and the Ta 2O 5 side functions as a reference channel that monitors bulk refractive index changes and temperature drift. We have studied human chorionic gonadotropin (hCG) as a model system, currently detecting down to 5 ng/ml. In addition, we demonstrate the power of the on-chip reference channel for compensating for refractive index changes and eliminating false alarms.