Abstract: Mechanisms for coating surfaces of materials, the resulting coated materials, and solutions for use in material-coating processes are described. Triblock molecule components may be selected for desired properties. When applied in solution to a material, the molecules self-assemble into similarly oriented micro- or nanostructures coating the surface of the material. Various molecule properties can be tailored to produce a range of desirable surface coating properties. The surface coating may optionally be self cleaning if selected to be appropriately hydrophobic, allowing water and particulates to roll off of the surface with minimal friction.

Abstract: Mechanisms for coating surfaces of materials, the resulting coated materials, and solutions for use in material-coating processes are described. Triblock molecule components may be selected for desired properties. When applied in solution to a material, the molecules self-assemble into similarly oriented micro- or nanostructures coating the surface of the material. Various molecule properties can be tailored to produce a range of desirable surface coating properties. The surface coating may optionally be self cleaning if selected to be appropriately hydrophobic, allowing water and particulates to roll off of the surface with minimal friction.

Abstract: Mechanisms for coating surfaces of materials, the resulting coated materials, and solutions for use in material-coating processes are described. Triblock molecule components may be selected for desired properties. When applied in solution to a material, the molecules self-assemble into similarly oriented micro- or nanostructures coating the surface of the material. Various molecule properties can be tailored to produce a range of desirable surface coating properties. The surface coating may optionally be self cleaning if selected to be appropriately hydrophobic, allowing water and particulates to roll off of the surface with minimal friction.

Abstract: The present invention relates to bio-molecule resistant surfaces for use in assays, particularly in assay devices such as arrays and microfluidic devices. The biomolecule resistant surface of the present invention are prepared by coating a substrate with hydrophilic terminated alkoxysilanes having formula (A): wherein R is an alkyl group of a size that allows for sufficient hydrolysis and n is 1, 2 or 3; R1 is a hydrophilic moiety; LC is a C1 to a C10 linker chain consisting of a group selected from alkyl, aryl, alkaryl and aralkyl and m is 1, 2, or 3; R2 is a C1 to a C7 alkyl group and x is 0, 1, or 2; and m+n+x is equal to 4.

Abstract: Methods for producing nanoporous structures are provided. In the subject methods, two or more, e.g., first and second, different types of self-assembling molecules are combined with each other under conditions sufficient to produce a composite ordered structure from the two or types of molecules. A feature of two or more molecules that are combined in this first step is that a portion of the molecules include cross-linking functionalities not found in the other portion of the molecules. The resultant self-assembled composite structure is then subjected to conditions sufficient for cross-linking of the portion of the molecules that includes the cross-linking functionalities to produce a stabilized composite structure. Finally, the remaining non-cross-linked molecules of the stabilized composite structure are separated from the stabilized composite structure to produce a nanoporous structure.

Abstract: Methods for producing nanoporous structures are provided. In the subject methods, two or more, e.g., first and second, different types of self-assembling molecules are combined with each other under conditions sufficient to produce a composite ordered structure from the two or types of molecules. A feature of two or more molecules that are combined in this first step is that a portion of the molecules include cross-linking functionalities not found in the other portion of the molecules. The resultant self-assembled composite structure is then subjected to conditions sufficient for cross-linking of the portion of the molecules that includes the cross-linking functionalities to produce a stabilized composite structure. Finally, the remaining non-cross-linked molecules of the stabilized composite structure are separated from the stabilized composite structure to produce a nanoporous structure.

Abstract: Methods for producing nanoporous structures are provided. In the subject methods, two or more, e.g., first and second, different types of self-assembling molecules are combined with each other under conditions sufficient to produce a composite ordered structure from the two or types of molecules. A feature of two or more molecules that are combined in this first step is that a portion of the molecules include cross-linking functionalities not found in the other portion of the molecules. The resultant self-assembled composite structure is then subjected to conditions sufficient for cross-linking of the portion of the molecules that includes the cross-linking functionalities to produce a stabilized composite structure. Finally, the remaining non-cross-linked molecules of the stabilized composite structure are separated from the stabilized composite structure to produce a nanoporous structure.

Abstract: The present invention relates to bio-molecule resistant surfaces for use in assays, particularly in assay devices such as arrays and microfluidic devices.