Low-voltage efficient electroosmotic pumps with ultrathin silica nanoporous membrane.

In this work, an efficient electroosmotic pump (EOP) based on the ultrathin silica nanoporous membrane (u-SNM), which can drive the motion of fluid under the operating voltage as low as 0.2 V, has been fabricated. Thanks to the ultrathin thickness of u-SNM (∼75 nm), the effective electric field strength across u-SNM could be as high as 8.27 × 105 V m-1 in 0.4 M KCl when 1.0 V of voltage was applied. The maximum normalized electroosmotic flow (EOF) rate was as high as 172.90 mL/min/cm2 /V, which was larger than most of other nanoporous membrane based EOPs. In addition to the ultrathin thickness, the high porosity of this membrane (with a pore density of 4 × 1012 cm-2 , corresponding to a porosity of 16.7%) also contribute to such a high EOF rate. Moreover, the EOF rate was found to be proportional to both the applied voltage and the electrolyte concentration. Because of small electrokinetic radius of u-SNM arising from its ultrasmall pore size (ca. 2.3 nm in diameter), the EOF rate increased with increasing the electrolyte concentration and reached the maximum at a concentration of 0.4 M. This dependence was rationalized by the variations of both zeta potential and electrokinetic radius with the electrolyte concentration.

Highly Efficient Desalting by Silica Isoporous Membrane-Based Microfluidic Chip for Electrospray Ionization Mass Spectrometry.

Nonvolatile buffers and inorganic salts used for isolation and stabilization of biological samples are essential to be cleaned up prior to mass spectrometry (MS) analysis because of their deleterious effects such as ion suppression and instrumental pollution. In this work, a centimeter-scale continuous silica isoporous membrane (SIM) was prepared and integrated into a facile microfluidic chip for the desalting of protein samples based on dialysis principle. Thanks to the uniform pore size (∼2.3 nm in diameter), ultrasmall thickness (90 nm) and high pore density (4.0 × 1012 pores cm-2, corresponding to a porosity of 16.7%) of SIM, the device achieved ∼99% desalting efficiency for the sample with 154 mM NaCl (isotonic saline) at a flow rate of 1 µL min-1, while protein loss was only 5%. High-quality electrospray ionization (ESI)-MS spectra of cytochrome c dissolved in isotonic saline was obtained after the desalting treatment. In addition, the SIM-based microfluidic device was successfully online-coupled with microchip ESI-MS for real-time desalting and characterization of proteins.

pH-Controlled Drug Release by Diffusion through Silica Nanochannel Membranes.

We report in this work the fabrication of a flow-through silica nanochannel membrane (SNM) for controlled drug release applications. The ultrathin SNM consists of parallel nanochannels with a uniform diameter of ∼2.3 nm and a density of 4 × 1012 cm-2, which provide simultaneously high permeability and size selectivity toward small molecules. The track-etched porous polyethylene terephthalate film premodified with silane on its surface was used to support the ultrathin SNM via irreversible covalent bond formation, thus offering mechanical strength, flexibility, and stability to the ultrathin SNM for continuous and long-term use. Alkylamines were subsequently grafted onto the SNM surface to modulate the "on" and "off" state of nanochannels by medium pH for controlled drug release. Thiamphenicol glycinate hydrochloride (TPG), an intestinal drug, was studied as a model to permeate through an ultrathin SNM in both simulated gastric fluid (pH = 1.2) and simulated intestinal fluid (pH = 7.5). The release in the latter case was 178 times faster than that in the former. Moreover, a nearly zero-order constant release of TPG via single-file diffusion was achieved up to 24 h, demonstrating the feasibility of sustained and continuous release of small-molecule drugs in a pH-controlled manner.