Abstract: The present invention is directed to a device comprising (a) a substrate having a surface and (b) an ordered array of posts over the surface, wherein the posts are capable of binding a protein or small molecule ligand, and wherein the pitch between adjacent posts is less than about 100 nm. The invention is also directed to methods for identifying the presence of an analyte in a fluid and to methods for measuring relative binding specificity or affinity between an analyte in a fluid and the posts, using the device of the present invention.
Type:
Grant
Filed:
April 13, 2006
Date of Patent:
July 2, 2013
Assignee:
The Trustees of Columbia University in the City of New York
Abstract: This invention involves the nano-structured support used for separation or/and analysis, especially the chip substrate, ELISA plate substrate, planar chromatography strip and chromatography gel. Besides, it involves the functionalized nano-structured support of high sensibility for separation or/and analysis, especially the analysis-chip, ELISA plate, planar chromatography reagent strip and chromatography gel. In addition, this invention also involves the nano-structured marking system for analysis. Moreover, it concerns the test kit; especially the chip kit, ELISA kit, and planar chromatography kit. What's more, this invention involves the preparing methods and the applications of all those mentioned above, especially the chip analysis, analyses with ELISA plate, planar chromatography strip and chromatography separation.
Abstract: The present invention relates to a method of patterning molecules on a substrate using a micro-contact printing process, to a substrate produced by said method and to uses of said substrate. It also relates to a device for performing the method according to the present invention.
Type:
Grant
Filed:
June 30, 2006
Date of Patent:
September 28, 2010
Assignee:
Sony Deutschland GmbH
Inventors:
Jurina Wessels, Gregor Kron, Akio Yasuda, Daniel Schwaab, Dirk Mayer, Andreas Offenhaeusser
Abstract: The invention teaches the use of an addressable nanoscale device to create a programmable substrate useful in selectively attracting proteins, nucleating protein crystals and growing protein crystals of a size amenable to diffraction analysis. Further taught is the use of nanoscale assemblies to create charge patterns, where such charge patterns are useful in purifying, nucleating or crystallizing protein molecules. Charge extension moieties, including water, are taught. The invention provides rapid and efficient identification, purification and detection of proteins and protein-related complexes.
Abstract: The invention teaches the use of an addressable nanoscale device to create a programmable substrate useful in selectively attracting proteins, nucleating protein crystals and growing protein crystals of a size amenable to diffraction analysis. Further taught is the use of nanoscale assemblies to create charge patterns, where such charge patterns are useful in purifying, nucleating or crystallizing protein molecules. Charge extension moieties, including water, are taught. The invention provides rapid and efficient identification, purification and detection of proteins and protein-related complexes.
Abstract: Functionalized fluorescent nanocrystal compositions and methods for making and using these compositions are disclosed. The compositions are fluorescent nanocrystals coated with at least one material. The coating material has chemical compounds or ligands with functional groups or moieties with conjugated electrons and moieties for imparting solubility to coated fluorescent nanocrystals in aqueous solutions. The coating material provides for functionalized fluorescent nanocrystal compositions which are water soluble, chemically stable, and emit light with a high quantum yield and/or luminescence efficiency when excited with light. The coating material may also have chemical compounds or ligands with moieties for bonding to target molecules and cells as well as moieties for cross-linking the coating.