Abstract: Nano-structured anodic aluminum oxide ceramic films and membranes doped with chelated metals for fluorescence enhancement. Controlled doping during production steps results in the inclusion of traces of ions in the finished materials while maintaining high control over the film structure. This approach yields products suitable for optical applications, including fluorescence enhancement.

Abstract: A nano-porous structure substrate forming assays occupying no more than one square micron. The assays are comprised of bundled cylindrical nano-pores that act as vessels that can house reagents for a single specific bioassay. A substrate of only a few square centimeters can accommodate 100,000 to 1,000,000 individual bioassays. The substrate may be doped with fluorescent enhancement centers to increase the signal to noise ratios or be surface modified with grafting compounds such as universal linkers, silane coupling agents, antigens and antibodies, or gene sequences.

Abstract: A nano-structured ceramic film with controlled pore size for the high throughput synthesis of oligonucleotides (DNA and RNA). The film can be cut into chips of predetermined size, and code printed for optical recognition in automated DNA synthesizers. The chips are easily activated under very mild conditions and silanization proceeds uniformly to allow reagents to flow unhindered through its open pores. Mono layer modifications, such as covalently bound silane coupling agents, allows for the addition of universal linkers and improved yields compared to conventional approaches.

Abstract: A method of manufacturing a nano-structured aluminum oxide film. The first step involves degreasing an aluminum plate using a degreasing solution. The next step involves electropolishing the aluminum plate after degreasing with an electropolishing solution that is free of perchloric acid and chromic acid. The next step involves pre-anodizing the aluminum plate after electropolishing with an anodization acid solution for a first predetermined time period. The next step involves anodizing the aluminum plate after electropolishing with the anodization acid solution for a second predetermined time period to form an anodized membrane on the aluminum plate. The next step involves separating the anodized membrane from the aluminum plate with a solution free of chrome. The last step involves cleaning the anodized membrane.

Abstract: A nano-structured ceramic film engineered for the study of biological samples. The films have a plurality of pores with a narrow and ordered pore-size distribution with pore diameters between 50 nm to 400 nm (±10%). The films are doping with metal compositions that provide fluorescence resonance energy transfer (FRET) capabilities with significant fluorescence signal enhancement and low noise. A hairpin DNA construct with a quencher and fluorophore is covalently linked to the surface (including inside the pores) of the ceramic film and configured to react to any target sequences in solution, resulting in separation of the quencher-fluorophore pair. The chelated metal ion FRET centers doped within the nano-structure ceramic film provider for long lasting fluorescence signals with less noise.

Abstract: Nano-structured anodic aluminum oxide ceramic films and membranes doped with chelated metals for fluorescence enhancement. Controlled doping during production steps results in the inclusion of traces of ions in the finished materials while maintaining high control over the film structure. This approach yields products suitable for optical applications, including fluorescence enhancement.