The application of 3D micropatterning of agarose substrate for cell culture and in situ comet assays.

We report the fabrication of a 3D micropatterned agarose substrate that enables the culture of single or multiple cells. Patterning was performed on dried agarose using deep UV irradiation leading to 6-microm-deep micropatterns of 25-70 microm in diameter. Cell adhesion was facilitated by the specific grafting of ECM (extra cellular matrix) proteins such as fibronectin into the micropatterns. We show that the pattern size induced the adhesion of one or more cells, thus allowing precise control of the cell number used in the assay, and that cells proliferated similarly as in standard culture conditions. Moreover, cell polarity appeared well preserved on this substrate, so polarized cells like hepatoma HepaRG cells might maintain their differentiation status and act as primary human hepatocytes for hepatotoxicity testing. These 3D patterned culture slides have been successfully used for in situ comet assays and there is evidence that the genotoxic effects of sub-cytotoxic concentrations of drugs could be analyzed in a large number of single HeLa cells. Coupled with the parallel-based design of the 3D micropatterning, which allows automated image analysis, these results strongly indicate that this new cell array system is suitable for high-throughput cytotoxicity and genotoxicity screening applications.

2D and 3D cell microarrays in pharmacology.

To analyze the phenotypic consequences of perturbing mammalian cells with drugs, there is an increasing need for systematic cell-based assays in an HTS format. Cell microarrays provide an attractive solution as they offer more than a simple miniaturization and mechanization of conventional microtiter plates. While standard monolayer two-dimensional culture conditions are poor mimics of the cellular environment in situ, microfabricated systems enable three-dimensional organotypic cell cultures and have the potential to provide biological insight not achievable before. This article compares different cell microarray formats and evaluates their potential use in the drug discovery process.

Photochemical patterning of biological molecules inside a glass capillary.

A simple way for photochemical patterning of biological molecules onto the inner wall of fused-silica capillary is described. The method is based on a modification of the inner capillary surface with photoactive benzophenone (BP) derivative. The UV irradiation at 365 nm of the capillary filled with a sample solution results in cross-linking of the solutes to the BP moiety via a stable covalent bond. As a proof of concept, oligonucleotides and proteins were arrayed inside the capillary using an inverted microscope as an irradiation device. We demonstrated that the capillary arrays produced in this way are functional and could be used in different bioassays including DNA hybridization, protein interaction studies, and immunoassays. Having a sensitivity comparable to the fluorophore-based assays in a planar format, the capillary array possesses several advantages including submicroliter sample volume and a short assay time. The capillary format should therefore be considered as a possible alternative to a planar format in a number of low-density array applications such as mutation detection and diagnostic immunoassays.

Determination of surface-bound-fluorophore orientation by goniometric fluorescence polarization: application to quantification of DNA-chip readouts.

We present a polarized goniofluorimeter designed to measure the observation-angle and polarization-dependent intensity emitted by a group of surface-bound fluorescent molecules. We studied two types of surface bonding: In one case, dyes were adsorbed into the surface by spin coating, and in the other, dyes were covalently immobilized to DNA strands. Fluorescent dyes consisted of Cy3 and Alexa546. The substrate was a silicon wafer bearing a silicon dioxide layer. The different samples presented a wide panel of reproducible experimental behavior. By confronting experimental behavior with theory and simulation, we can explain these differences as directly linked to the mean orientation of fluorophores with respect to the surface.