Innovative metal oxide-based substrates for DNA microarrays

In the present report, we propose a novel approach to synthesize DNA microarrays that employs immobilization of the nucleic acid molecules onto zinc and iron oxide surfaces through their phosphate backbone. Oxide films were prepared by the sol–gel technique and the resulting surfaces were characterized especially with respect to surface chemistry and morphological features by both X-ray photoelectron spectroscopy (XPS) and atomic force microscopy (AFM). ZnO films annealed at T ⩽ 300 °C show the most promising surface features to be employed for DNA microarray preparation, i.e. high density of binding sites (hydroxyl groups), smooth and homogeneous surfaces, high optical transmittance in the visible spectral range suitable for detection using fluorescence, and easy handling during preparation procedures. The analysis of nucleic acid retention on the oxide layers was performed by the scanning of dye-labelled DNA previously printed on the substrate using the DNA microarray robotic arm. Clearly visible spots with regular shape were revealed above the background noise indicating that anchoring of the DNA on the treated surface is efficient and does not interfere with hybridization processes. The use of suitably engineered zinc oxide film makes the immobilization strategy ideal for facile, efficient, and cost-effective manufacturing of DNA microarrays.

An innovative approach to DNA microarrays that employs immobilization of the nucleic acid molecules onto surfaces of sol–gel zinc and iron oxide thin films is presented. The performances of the realized microarrays resulted strongly dependent on surface chemistry and morphological features of ZnO and Fe2O3 layers. As an example, the picture displays the detail of a ZnO-based DNA microarray, visualized by merging the two colour images obtained after laser scanning.Figure optionsDownload as PowerPoint slide