Evaluation of a glassy carbon electrode modified by a bilayer lipid membrane with incorporated DNA

The objective of the present work was the evaluation and characterization of a glassy carbon (GC) electrode modified by a bilayer lipid membrane (BLM) with incorporated single-stranded deoxyribonucleic acid (ss DNA). Various procedures were developed and tested for the incorporation of ss DNA at the electrode modified by the lipidic membrane: 1. formation of self-assembled BLMs over ss DNA adsorbed on the electrode surface; 2. direct adsorption of ss DMA into a BLM modified GC electrode; 3. formation of a BLM with incorporated ss DNA at the electrode surface using the monolayer folding technique. Differential pulse voltammetry (i.e. oxidation of guanine and adenine residues) was used to monitor the incorporation of ss DNA at the GC electrode modified by the BLM. The results have shown that the lipid membrane enhances the stability of ss DNA during a ''medium-exchange'' of the electrode and prohibits its diffusion from the electrode surface. The third scheme was proven to be the most appropriate as both electrode modification by the BLM and DNA adsorption occur in one stage and much faster (as no BLM thinning process is required) as compared to the former two techniques; furthermore, maximized loading of DNA in BLMs is achieved which reduces by ca. 10-fold the DNA amounts that can be detected electrochemically. Conventional planar ''free-suspended'' and self-assembled metal supported BLMs were used to monitor in situ the incorporation of ss DNA in these membranes. The results have shown that the adsorption of ss DNA at lipid membranes (as a medium for DNA incorporation on an electrode surface) can occur much faster, using milder conditions and smaller amounts of DNA than by previously described techniques.