Free‐solution electrophoretic separations of DNA–drag‐tag conjugates on glass microchips with no polymer network and no loss of resolution at increased electric field strength

Here, we demonstrate the potential for high‐resolution electrophoretic separations of ssDNA–protein conjugates in borosilicate glass microfluidic chips, with no sieving media and excellent repeatability. Using polynucleotides of two different lengths conjugated to moderately cationic protein polymer drag‐tags, we measured separation efficiency as a function of applied electric field. In excellent agreement with prior theoretical predictions of Slater et al., resolution is found to remain constant as applied field is increased up to 700 V/cm, the highest field we were able to apply. This remarkable result illustrates the fundamentally different physical limitations of free‐solution conjugate electrophoresis (FSCE)‐based DNA separations relative to matrix‐based DNA electrophoresis. ssDNA separations in “gels” have always shown rapidly declining resolution as the field strength is increased; this is especially true for ssDNA > 400 bases in length. FSCE's ability to decouple DNA peak resolution from applied electric field suggests the future possibility of ultra‐rapid FSCE sequencing on chips. We investigated sources of peak broadening for FSCE separations on borosilicate glass microchips, using six different protein polymer drag‐tags. For drag‐tags with four or more positive charges, electrostatic and adsorptive interactions with poly( N ‐hydroxyethylacrylamide)‐coated microchannel walls led to appreciable band‐broadening, while much sharper peaks were seen for bioconjugates with nearly charge‐neutral protein drag‐tags.