Reusable flow cells for sequencing which exhibit signal intensity retention over numerous use cycles, the active surface of which contains poly-azide functional moieties, methods of treating flow cells surfaces with reagents to provide such poly-azide functional moieties, and reagents therefor.

A microarray is designed to capture one or more molecules of interest at each of a plurality of sites on a substrate. The sites comprise base pads, such as polymer base pads, that promote the attachment of the molecules at the sites. The microarray may be made by one or more patterning techniques to create a layout of base pads in a desired pattern. Further, the microarrays may include features to encourage clonality at the sites.

The present application describes compartmentalized arrays of printed linker molecules with physical barriers on the surface, the physical barriers forming one or more compartments surrounding and separating at least a portion of the plurality of distinct regions. The present application also describes a method of fabrication and uses of the compartmentalized arrays.

A method for generating, within a conduit, discrete volumes of one or more fluids that are immiscible with a second fluid. The discrete volumes can be used for biochemical or molecular biology procedures involving small volumes, for example, microliter-sized volumes, nanoliter-sized volumes, or smaller. The discrete volumes are separated from one another by a liquid that is immiscible with the fluid(s) of the discrete volumes, for example, aqueous immiscible-fluid-discrete volumes separated by an oil.

The present invention relates to a method of designing DNA probe chip for room-temperature hybridization in order to solve the solvent evaporation problem occurring when carrying out said hybridization at a high temperature of 40 C.50 C. or higher, wherein the method is designed to allow genotyping through hybridizing at a room temperature of 20 C.30 C. The method of designing DNA probe chip comprises designing DNA probe to start at 10+5 position that is between 10 position which is overlapped 10 sequences with primer and +5 position which is 5 sequences far from the 3-terminal of primer, based on 0 position which is 3-terminal of primer.

De novo synthesized large libraries of nucleic acids are provided herein with low error rates. Further, devices for the manufacturing of high-quality building blocks, such as oligonucleotides, are described herein. Longer nucleic acids can be synthesized in parallel using microfluidic assemblies. Further, methods herein allow for the fast construction of large libraries of long, high-quality genes. Devices for the manufacturing of large libraries of long and high-quality nucleic acids are further described herein.

Provided are methods for performing patterned chemistry and arrays prepared thereby.

A nanoparticle screening chip and a method using said chip allowing for determining physical properties of nanoparticles, wherein the screening chip comprises a substrate having a working surface divided into a plurality of areas, wherein (1) each of these areas presents different surface properties defined by surface energy component (d,b,a), the total free energy .sub.TOT of the surface of each area being defined as follows: .sub.TOT=.sub.LW+2(.sub.+.sub.).sup.0.5, wherein the components are: .sub.LW=dispersive component=d, .sub.+=electron acceptor component=b, .sub.=electron donor component=a; and (2) each of these areas comprises a plurality of subareas, each subarea comprising an array of sub-micrometric holes or elongated grooves with a different aperture size (S1, S2, S3, . . . ).

There is disclosed an electrode array device having an adsorbed porous reaction layer for improved synthesis quality. The array comprises a plurality of electrodes on a substrate, wherein the electrodes are electronically connected to a computer control system. The array has an adsorbed porous reaction layer on the plurality of electrodes, wherein the adsorbed porous reaction layer comprises a chemical species having at least one hydroxyl group. In the preferred embodiment, the reaction layer is sucrose. A method for preparing an electrode array for improved synthesis quality is disclosed. The method comprises a cleaning method and a method of attachment of a reaction layer. The cleaning method comprises a plasma cleaning method and a chemical cleaning method. The reaction layer is attached after cleaning by exposing the microarray to a solution containing the chemical species having at least one hydroxyl group.

A method including (a) providing an amplification reagent including an array of sites, and a solution having different target nucleic acids; and (b) reacting the amplification reagent to produce amplification sites each having a clonal population of amplicons from a target nucleic acid from the solution. The reacting can include simultaneously transporting the nucleic acids to the sites at an average transport rate, and amplifying the nucleic acids that transport to the sites at an average amplification rate, wherein the average amplification rate exceeds the average transport rate. The reacting can include producing a first amplicon from a nucleic acid that transports to each of the sites, and producing subsequent amplicons from the nucleic acid or from the first amplicon, wherein the average rate at which the subsequent amplicons are generated exceeds the average rate at which the first amplicon is generated.