This invention relates generally to the field of nucleic acid detection. In particular, the invention provides a lab-on-chip system for analyzing a nucleic acid, which system comprises, inter alia, controllably closed space, and a target nucleic acid can be prepared and/or amplified, and hybridized to a nucleic acid probe, and the hybridization signal can be acquired if desirable, in the controllably closed space without any material exchange between the controllably closed space and the outside environment. Methods for analyzing a nucleic acid using the lab-on-chip system is also provided.

Method for immobilization of a labeled oligonucleotide on a non-modified polymer substrate, the method comprising the following steps: a) providing a mixture comprising liquid, and a labeled oligonucleotide b) applying the mixture of step a) on a non-modified polymer substrate, wherein the oligonucleotide is immobilized on the non-modified polymer substrate via physisorption conveyed by the label of the oligonucleotide and wherein the label for immobilization is covalently bound to the oligonucleotide; and microarrays achieved by this method. The invention further relates to the use of a label attached to an oligonucleotide for immobilization of the labeled oligonucleotide on a non-modified polymer substrate by physisorption. Furthermore the invention relates to the use of the microarrays achieved by the method describe herein for assays and diagnostic kits comprising such microarrays.

The present disclosure provides compositions and methods for making and using a support (e.g., a sample slide) for sample analysis. The present disclosure also provides compositions, methods, and systems for processing a sample on the support for use in nucleic acid sequence detection.

An article such as a biosensor having a nonfouling surface thereon is described. The article comprises: (a) a substrate having a surface portion; (b) a linking layer on the surface portion; (c) a polymer layer comprising brush molecules formed on the linking layer; and (d) optionally but preferably, a first member of a specific binding pair (e.g., a protein, peptide, antibody, nucleic acid, etc.) coupled to the brush molecules. The polymer layer is preferably formed by the process of surface-initiated polymerization (SIP) of monomeric units thereon. Preferably, each of the monomeric units comprises a monomer (for example, a vinyl monomer) core group having at least one protein-resistant head group coupled thereto, to thereby form the brush molecule on the surface portion. Methods of using the articles are also described.

An article including: a substrate; and at least one immobilization site on the substrate comprising at least one nucleic acid immobilization site, each site having a first layer of a tie agent in contact with the substrate, and a second layer of a dendrimer mobilizing agent in contact with the first layer. Also disclosed is a method of making and a method of using the article.

Protein arrays and their use to assay, in a parallel fashion, the protein products of highly homologous or related DNA coding sequences and described. By highly homologous or related it is meant those DNA coding sequences which share a common sequence and which differ only by one or more naturally occurring mutations such as single nucleotide polymorphisms, deletions or insertions, or those sequences which are considered to be haplotypes. Such highly homologous or related DNA coding sequences are generally naturally occurring variants of the same gene. Arrays according to the invention have two or more individual proteins deposited in a spatially defined pattern on a surface in a form whereby a property such as an activity or function of the proteins can be investigated or assayed in parallel by interrogation of the array.

The present disclosure provides methods of patterning cells on a surface of a substrate. The methods include disposing a pattern of nucleic acids on a surface of a substrate, and contacting the patterned nucleic acids under hybridization conditions with a first suspension of cells, where cells of the first suspension include cell surface-attached nucleic acids complementary to the patterned nucleic acids, and where the cell surface-attached nucleic acids hybridize to the patterned nucleic acids to pattern the cells on the surface of the substrate. Systems and kits for practicing the methods are also provided.

Apparatus and methods are disclosed for electrically active combinatorial-chemical (EACC) chips for biochemical analyte detection. An apparatus includes a substrate that has an array of regions defining multiple cells, wherein each of the cells includes a reaction cavity that contains multiple functional binding groups. A method of detecting an analyte providing the reaction cavity between a source and a drain or a pair of electrodes, applying a voltage and monitoring a parameter indicative of an analyte characteristic. A process of fabricating an EACC include bonding an analyte to the multiple functional binding groups of each reaction cavity, and forming an analyte sensing structure including the substrate.

A fluorous-modified composition, a fluorous nucleoside, nucleotide, or oligonucleotide microarray, a compositional detection process, a process of forming a fluorous nucleoside, nucleotide, or oligonucleotide microarray, and fluorous nucleoside, nucleotide, or oligonucleotide microarray processes are disclosed. The fluorous-modified composition includes a linker, a nucleoside, nucleotide, or oligonucleotide connected to the linker, and a fluorous domain connected to the linker. The fluorous-modified composition includes at least one terminal perfluoroalkyl group in the fluorous domain, a solid-phase attachment group connected to the linker, or a combination thereof. The compositional detection process includes using the fluorous microarray for compositional detection. The processes of forming a fluorous microarray include transfer blotting the fluorous-modified composition to form a fluorous microarray and the spotting of reaction mixtures containing a fluorous-modified nucleoside, nucleotide, or oligonucleotide. The fluorous microarray includes a fluorous-modified conductive surface and fluorous nucleoside, nucleotide, or oligonucleotides positioned on the fluorous-modified surface. The fluorous microarray process includes using information corresponding to a compositional detection process.

The invention describes a high-throughput method for simultaneously and selectively mixing one molecule with a plurality of other molecules. The resulting molecule-molecule complexes can then be captured on a surface, creating a microarray. This microarray can then be used to characterize and measure the molecule-molecule complexes (e.g. for reactions to other molecules).