Lubricin (PRG-4) anti-fouling coating for surface-enhanced Raman spectroscopy biosensing: towards a hierarchical separation system for analysis of biofluids.

Surface-enhanced Raman Spectroscopy (SERS) is a powerful optical sensing technique that amplifies the signal generated by Raman scattering by many orders of magnitude. Although the extreme sensitivity of SERS enables an extremely low limit of detection, even down to single molecule levels, it is also a primary limitation of the technique due to its tendency to equally amplify 'noise' generated by non-specifically adsorbed molecules at (or near) SERS-active interfaces. Eliminating interference noise is thus critically important to SERS biosensing and typically involves onerous extraction/purification/washing procedures and/or heavy dilution of biofluid samples. Consequently, direct analysis within biofluid samples or in vivo environments is practically impossible. In this study, an anti-fouling coating of recombinant human Lubricin (LUB) was self-assembled onto AuNP-modified glass slides via a simple drop-casting method. A series of Raman spectra were collected using rhodamine 6G (R6G) as a model analyte, which was spiked into NaCl solution or unprocessed whole blood. Likewise, we demonstrate the same sensing system for the quantitative detection of L-cysteine spiked in undiluted milk. It was demonstrated for the first time that LUB coating can mitigate the deleterious effect of fouling in a SERS sensor without compromising the detection of a target analyte, even in a highly fouling, complex medium like whole blood or milk. This feat is achieved through a molecular sieving property of LUB that separates small analytes from large fouling species directly at the sensing interface resulting in SERS spectra with low background (i.e., noise) levels and excellent analyte spectral fidelity. These findings indicate the great potential for using LUB coatings together with an analyte-selective layer to form a hierarchical separation system for SERS sensing of relevant analytes directly in complex biological media, aquaculture, food matrix or environmental samples.

Lubricin (PRG4) Antiadhesive Coatings Mitigate Electrochemical Impedance Instabilities in Polypyrrole Bionic Electrodes Exposed to Fouling Fluids.

Surface fouling is a major problem faced by bionic implants (e.g., cochlear implants, pacemakers), where the adsorption of unwanted biomolecules has a detrimental effect on interfacial charge transfer processes, which severely impairs their capacity to sense and transmit electrical signals with high fidelity. Polypyrrole (PPy) is a conductive polymer whose naturally high impedance, ionic and electric conductivity, mechanical "softness", and biocompatibility make it a leading candidate for next-generation neural electrode interfaces. However, PPy (and related conductive polymer) surfaces are susceptible to surface fouling upon exposure to biological fluids (e.g., blood, perilymph, saliva), which compromises performance and shortens its expected working lifespan. Here, we report the ability of lubricin (LUB) coatings, a rapidly self-assembling, biological antiadhesive glycoprotein, to mitigate the harmful electrochemical effects caused by the surface fouling of electrochemically grown PPy films. LUB, a biological antiadhesive glycoprotein, undergoes rapid self-assembly and adheres strongly to most interfaces, including PPy, resulting in an easy-to-apply and highly efficacious coating. The LUB-coated PPy electrodes are electrochemically characterized, and its antifouling properties are assessed against concentrated solutions of bovine serum albumin (BSA) and following long-term exposure to artificial perilymph (AP). Periodic impedance measurement conducted over 6 days in AP solution demonstrates the high stability and capacity of the LUB coatings to maintain stable impedance values under real-world mimicking conditions.