Abstract: This invention features a compound of the following formula:

Abstract: A method for forming a pattern, including the steps of preparing a cliché having a recess thereon corresponding to a position of a pattern, filling one of resist and ink within the recess of the cliché, affixing a substrate on which the pattern is to be formed on a loading plate, aligning the loading plate on the cliché, attaching the substrate on the loading plate to the cliché, and separating the substrate on the loading plate from the cliché.

Abstract: A thermo-responsive polymer is incorporated into a fuel cell (50) in order to maintain optimum hydration of the polymer electrolyte membrane. The thermo-responsive polymer (52) is situated proximate to the membrane electrode assembly (54) such that fuel or oxidant gas passes (56) through the thermo-responsive polymer to the membrane electrode assembly. The thermo-responsive polymer swells or shrinks in response to changes in the operating temperature of the membrane electrode assembly, altering the flow rate of the fuel or oxidant gas passing through the thermo-responsive polymer.

Abstract: This invention features a compound of the following formula: 1

Abstract: This invention features a method of identifying a compound useful for enhancing efficacy of a therapeutic agent. The method includes incubating a compound in blood cells; separating immune cells from erythrocytic cells; and determining the ratio of the concentration of the compound in the immune cells to the concentration of the compound in the erythrocytic cells; wherein the compound comprises a transportophore and a therapeutic agent, in which the transportophore is covalently bonded to the therapeutic agent via a bond or a linker.

Abstract: A method for forming a pattern, including the steps of preparing a cliché having a recess thereon corresponding to a position of a pattern, filling one of resist and ink within the recess of the cliché, affixing a substrate on which the pattern is to be formed on a loading plate, aligning the loading plate on the cliché, attaching the substrate on the loading plate to the cliché, and separating the substrate on the loading plate from the cliché.

Abstract: A method comprises the step of representing a pair of genotypes at an SNP location, and/or clinical data, as a single number or a vector. Moreover, the method further comprises the step of applying a support vector machine to at least two of such vectors so as to optimally classify the vectors into one of the at least two subgroups. There is a particular application as a method for diagnosing a disease by representing a person or an organism as the above-type of vectors and then obtaining a cutoff hypersurface by applying a support vector machine to the vectors, wherein the cutoff surface serves to separate and classify the vectors into the at least two subgroups, the first with a disease and the second without.

Abstract: A thermo-responsive polymer is incorporated into a fuel cell (50) in order to maintain optimum hydration of the polymer electrolyte membrane. The thermo-responsive polymer (52) is situated proximate to the membrane electrode assembly (54) such that fuel or oxidant gas passes (56) through the thermo-responsive polymer to the membrane electrode assembly. The thermo-responsive polymer swells or shrinks in response to changes in the operating temperature of the membrane electrode assembly, altering the flow rate of the fuel or oxidant gas passing through the thermo-responsive polymer.

Abstract: The present invention relates to a transparent conductive thin film and a method for the preparation of the same., and more particularly to a method for the preparation of a transparent conductive thin film comprising the steps of a) preparing a sol solution of antimony-tin oxides (ATO) or indium-tin oxides (ITO), b) forming a transparent coating layer on an outer surface of a cathode ray tube using the sol solution, and c) rapidly increasing a temperature of the transparent coating layer to a predetermined temperature of 300 to 1200° C., and rapidly cooling the transparent coating layer either immediately or after maintaining the predetermined temperature for up to 20 seconds, and a transparent conductive thin film prepared by this preparation method, i.e., a transparent conductive thin film which not only has superior conductivity, high hardness, and non-reflectivity but also saves production process time and increases production process effectiveness, and a method for the preparation of the same.

Abstract: The present invention relates to a transparent conductive thin film and a method for the preparation of the same, and more particularly to a method for the preparation of a transparent conductive thin film comprising the steps of a) preparing a sol solution of antimony-tin oxides (ATO) or indium-tin oxides (ITO), b) forming a transparent coating layer on an outer surface of a cathode ray tube using the sol solution, and c) rapidly increasing a temperature of the transparent coating layer to a predetermined temperature of 300 to 1200° C., and rapidly cooling the transparent coating layer either immediately or after maintaining the predetermined temperature for up to 20 seconds, and a transparent conductive thin film prepared by this preparation method, i.e., a transparent conductive thin film which not only has superior conductivity, high hardness, and non-reflectivity but also saves production process time and increases production process effectiveness, and a method for the preparation of the same.

Abstract: A flat panel display device including a first substrate formed of a first material; a second substrate spaced apart from the first substrate and formed of a second material; and a plurality of pixelated emissive devices interposed between the first and second substrates. The second material having a relatively higher light transmittance property than the first material, and the second substrate transmitting light for the plurality of pixelated emissive devices.