The present paper describes a method for measuring the molecular diffusion coefficient of fluorescent molecules in microfluidic systems. The proposed static shear-driven flow method allows one to perform diffusion measurements in a fast and accurate manner. The method also allows one to work in very thin (i.e. submicron) channels, hence allowing the investigation of diffusion in highly confined spaces. In the deepest investigated channels, the obtained results were comparable to the existing literature values, but when the channel size dropped below the micrometer range, a significant decrease (more than 30%) in molecular diffusivity was observed. The reduction of the diffusivity was most significant for the largest considered molecules (ssDNA oligomers with a size ranging between 25 to 100 bases), but the decrease was also observed for smaller tracer molecules (FITC). This decrease can be attributed to the interactions of the analyte molecules with the channel walls, which can no longer be neglected when the depth of the channel reaches a critical value. The change in diffusivity seems to become more explicit as the molecular weight of the analytes increases.
The present study demonstrates that the best way to enhance DNA microarray assays, both in terms of analysis speed and in final spot intensity, is to dissolve the available molar amount of sample in the smallest possible buffer volume and to subsequently convect this solution continuously across the surface of the array. The presently proposed shear-driven flow system is pre-eminently suited for this task, as it allows to induce strongly enhanced lateral transport rates, independently of the degree of miniaturization of the hybridization chamber. This transport enhancement method, however, only increases the hybridization rate and not the final spot intensity, as neither can any of the other transport enhancement methods already proposed in literature. A series of experiments with synthetic single-stranded (ssDNA) samples and an accompanying mass balance analysis are presented to demonstrate these points.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.