Hydrogel materials consisting of water-swollen polymer networks exhibit a large number of specific properties highly attractive for a variety of optical biosensor applications. This properties profile embraces the aqueous swelling medium as the basis of biocompatibility, non-fouling behavior, and being not cell toxic, while providing high optical quality and transparency. The present review focuses on some of the most interesting aspects of surface-attached hydrogel films as active binding matrices in optical biosensors based on surface plasmon resonance and optical waveguide mode spectroscopy. In particular, the chemical nature, specific properties, and applications of such hydrogel surface architectures for highly sensitive affinity biosensors based on evanescent wave optics are discussed. The specific class of responsive hydrogel systems, which can change their physical state in response to externally applied stimuli, have found large interest as sophisticated materials that provide a complex behavior to hydrogel-based sensing devices.
pH-responsive surfaces, reversibly switching between superhydrophilicity and superhydrophobicity/water repellency, are developed by "grafting from" a pH-sensitive polymer onto a hierarchically micro/nano-structured substrate. We quantify the water repellency by investigating the restitution coefficient of water droplets bouncing off the surfaces. The water repellent state requires appropriate hydrophobicity of the functionalizing polymer as well as very low values of contact angle hysteresis.
The use of thermoresponsive poly(N-isopropylacrylamide)-based
hydrogel (pNIPAAm) for rapid tuning of surface plasmon resonance (SPR)
is reported. This approach is implemented by using an SPR layer architecture
with an embedded indium tin oxide microheater and pNIPAAm film on
its top. It takes advantage of rapid thermally induced swelling and
collapse of pNIPAAm that is accompanied by large refractive index
changes and leads to high thermo-optical coefficient of dn/dT = 2 × 10–2 RIU/K. We
show that this material is excellently suited for efficient control
of refractive index-sensitive SPR and that it can serve simultaneously
as a 3D binding matrix in biosensor applications (if modified with
biomolecular recognition elements for a specific capture of target
analyte). We demonstrate that this approach enables modulating of
the output signal in surface plasmon-enhanced fluorescence spectroscopy
biosensors and holds potential for simple time-multiplexing of sensing
channels for parallelized readout of fluorescence assays.
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