Controlling microarray spot morphology with polymer liftoff arrays.

Biological arrays are hindered by the lack of uniformity in the deposition of biomaterials. Efforts aimed at improving this deposition have focused on altering the composition of the solution or the tool used to deposit the material. However, little attention has been paid to controlling material deposition by constraining the physical and chemical topography of the surface. Here we present the use of a hybrid hydrophilic/hydrophobic micropatterned surface to direct the deposition of spotted DNA on microarrays. These polymer "liftoff" arrays combine the hydrophobic surface properties of di-p-xylylene (Parylene) with photolithographically etched hydrophilic openings within the polymer. We show that the flow pattern of solutes on these substrates favors the concentration of dissolved material into the mesoscopic openings underlying the printed spot, resulting in significantly improved uniformity of deposition. Moreover, the micropatterned surface allows for increased replication of spotted materials. Finally, these polymer liftoff arrays display reduced array-to-array variation, improving the reproducibility of data acquisition. We envision that these novel substrates can be generalized to produce more uniform arrays of other patterned biomaterials.

End-functionalization of poly(3-hydroxybutyrate)via genetic engineering for solid surface modification.

A new approach to end-functionalization of poly(3-hydroxybutyrate)[PHB] is described. Using genetically engineered PHB synthase fused with a 10x-histidine units at its N-terminus, end-functionalized PHB was synthesized and used for the solid surface modification.

Micropatterning of endothelial cells by guided stimulation with angiogenic factors.

Micropatterning technology holds significant promise in the development of micro/nanomedical devices. The precise control of cell position and migration is important in several applications. For example, the optimal design of implantable devices depends on the implant material's micro-and nano-texture, which influences the response of nearby tissue, including the microvessels. Therefore, we were interested in endothelial cell positioning and colonization on specific surface domains in the size range of microvasculature. To this end, endothelial cells were seeded in microfabricated grooves and exposed to vascular endothelial growth factor (VEGF), which plays a key role in the angiogenic response. Patterned silicon wafers with grooves of 50 microm width and depth and 150 microm groove spacing were used. Each patterned region had two semicircular ports at either end, one of which was used to seed human retinal endothelial cells (HREC) and the other to house VEGF embedded in Matrigel. After 1 week, cells were fixed and analyzed by laser scanning cytometry (LSC). Our results shows that we can control HREC seeding and positioning in surface grooves and that the speed of colonization of the grooves can be manipulated by local VEGF application. We were able to quantify this effect, showing that HREC relocate inside the grooves twice as fast in response to VEGF stimulation, compared to control conditions, at a speed of 3.14 +/- 0.01 and 1.55 +/- 0.01 microm/min, respectively. Our approach could be used towards the fabrication of "designer" substrates or devices that not only allow patterned cell growth, but also permit dynamic cell repositioning.

An electrospray ionization source for integration with microfluidics.

We have demonstrated a new electrospray ionization (ESI) device incorporating a tip made from a shaped thin film, bonded to a microfluidic channel, and interfaced to a time-of-flight mass spectrometer (TOFMS). A triangular-shaped thin polymer tip was formed by lithography and etching. A microfluidic channel, 20 microm wide and 10 microm deep, was embossed in a cyclo olefin substrate using a silicon master. The triangular tip was aligned with the channel and bonded between the channel plate and a flat plate to create a microfluidic channel with a wicking tip protruding from the end. This structure aided the formation of a stable Taylor cone at the apex of the tip, forming an electrospray ionization source. This source was tested by spraying several solutions for mass spectrometric analysis. Because the components are all made by lithographic approaches with high geometrical fidelity, an integrated array system with multiple channels can be formed with the same method and ease as a single channel. We tested a multichannel system in a multiplexed manner and showed reliable operation with no significant cross contamination between closely spaced channels.