3-D polyacrylamide gel-based DNA microarray platforms provide a high capacity for nucleic acids immobilization and a solution-mimicking environment for hybridization. However, several technological bottlenecks still remain in these platforms, such as difficult microarray preparation and high fluorescent background, which limit their application. In this study, two new approaches have been developed to improve the convenience in microarray preparation and to reduce the background after hybridization. To control the polymerization process, solutions containing acrylamide-modified oligonucleotide, acrylamide, glycerol and ammonium persulfate are spotted onto a functionalized glass slide, and then the slide is transferred to a vacuum chamber with TEMED, so that TEMED is vaporized and diffused into the spots to induce polymerization. By applying an electric field across a hybridized microarray to remove the nonspecifically bound labeled targets, this approach can solve the problem of high fluorescent background of the gel-based microarray after hybridization. Experimental results show that our immobilization method can be used to construct high quality microarrays and exhibits good reproducibility. Moreover, the polymerization is not affected by PCR medium, so that PCR products can be used for microarray construction without being treated by commercial purification cartridges. Electrophoresis can improve the signal-to-noise significantly and has the ability to differentiate single nucleotide variation between two homozygotes and a heterozygote. Our results demonstrated that this is a reliable novel method for high-throughput mutation analysis and disease diagnosis.
This paper describes the in situ synthesis of oligonucleotide arrays on glass surfaces by using soft lithography. In this method, based on the standard phosphoramidite chemistry protocol, the coupling was achieved by the glass slide being printed with a set of polydimethylsiloxane (PDMS) microstamps, on which was spread nucleoside monomer and tetrazole mixed solution. The elastic characteristic of PDMS allowed it to make conformal contact with the glass slide in the printing coupling. With regard to the efficiency of the printing coupling, the hybridization microscope images of 20-mer oligonucleotide synthesized via the directly drip-dropped coupling and the contact coupling were compared; the fluorescence intensities of the two methods showed no significant differences. The coupling efficiency was also investigated via an end-labelled fluorescence nucleotide method and a stepwise yield of 97% was obtained. A high-quality, high spatial resolution and large-scale PDMS stamp, which was developed by integrating 168 different microstamps on one glass substrate for synthesizing oligonucleotide arrays. The stamp was modified to improve the surface wettability by plasma discharge treatments, so that microstamps could be used to fabricate oligonucleotide arrays. A motional printing head was developed to improve the contact effect of the glass slide with different microstamps. A higher boiling point solvent was used in the printing coupling to inhibit solvent volatilization and to maintain the consistency of reagents on different features of the microstamp. An effective method was used to eliminate residual reactive nucleosides on chips with small molecules containing a hydroxyl group. A specific oligonucleotide array of four probes both matched and mismatched with the target sequence was fabricated to identify the perfect match and mismatch sequences.
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