Physical adsorption of immunoglobulin G on gold studied by scanning tunnelling microscopy

Covalent coupling of immunoglobulin G to self-assembled monolayers as a method for immobilizing the interfacial-recognition layer of a surface plasmon resonance immunosensor

Protocols have been developed for the random and site-directed covalent coupling of immunoglobulin G [anti-hIgG] [IgG] to silver surfaces modified with a self-assembled monolayer [SAM] of thioctic acid, mercaptopropionic acid [MPA], L-cysteine or 4-aminothiophenol [PATP]. A surface plasmon resonance [SPR] immunosensor fabricated with a more ordered and hydrophilic IgG-SAM-silver interfacial layer, demonstrates an increased ability for performing sensitive and selective assay of human immunoglobulin G [hIgG] compared with a device fabricated with a physically-adsorbed IgG-silver interfacial-layer due to reduced levels of non-specific binding. Detection limits [DL] for hIgG from serum down to 6 micrograms/ml (40 nM) and assay sensitivities up to 0.24 ng hIgG/mm2/nM are reported.

A scanning tunnelling microscopic study of site-specifically immobilized immunoglobulin G on gold

A convenient and efficient method for the site-specific incorporation of foreign cysteine residues at the C-termini of immunoglobulin G (IgG) using carboxypeptidase-Y-catalyzed transpeptidation is explored as a means of ensuring oriented immobilization of IgG on gold. A scanning tunnelling microscopic study of the immobilization of the modified IgG molecules on gold surfaces is reported. The results show not only that some globular features are observed to form striking surface patterns with a geometric size close to that of the fragments of IgG but also that the conformation of the bound IgG molecules appears more stable when adsorbed on gold. The effect of the immobilization method on these topographic features is discussed.