Application of self-assembly techniques in the design of biocompatible protein microarray surfaces.

This review focuses on the application of novel technologies for generating biocompatible surfaces for high-throughput screening (HTS) of proteins. Various methods of coupling and spotting proteins on self-assembled monolayer (SAM) surfaces will be described along with the protein chip challenges pertaining to spot homogeneity, morphology, biocompatibility and reproducibility.

Antibody detection in human serum using a versatile protein chip platform constructed by applying nanoscale self-assembled architectures on gold.

We report a novel high-throughput (HTP) protein chip platform, constructed on gold using self-assembly techniques, for conducting high quality antigen-antibody interactions. Biotinylated monolayers were used to immobilize a streptavidin surface with high packing density. This biocompatible platform was then used for detection of serum IgM antibodies. Serum samples of patients suspected to suffer from Lyme borreliosis were used to validate the protein chip platform using biotinylated peptide AAOspC8 molecules as the test probes. Various experimental parameters such as the effect of concentration of probes, targets, temperature of incubation, and their effect on the resulting signal-to-noise ratio are described in detail. Highly specific protein interaction data with a high signal-to-noise ratio were obtained with serum sample solutions as low as 1 microL/spot (1/10 diluted).