Abstract: An examination support method that supports an electrocardiogram examination of a subject using a garment on which medical equipment including cardiography equipment and a plurality of electrodes are loaded, the examination support method including: a first apparatus selecting a garment to be put on the subject from the garments of a plurality of sizes on a basis of size information on the subject; and a second apparatus connecting by wire or wirelessly with the medical equipment loaded on the garment that the subject has put on and reading out measurement data measured during a period in which the subject puts on the garment.

Abstract: The present invention provides a method for detecting an interaction, which method can solve not only the problem of false negatives but also the problem of false positives.

Abstract: A method for analyzing biomolecular interactions, which method can be carried out without performing affinity selection using an immobilized bait, is provided. mRNA portions of assignment molecules that interacted with each other are linked together by annealing via a DNA linker for linking mRNA portions of assignment molecules together, the DNA linker comprising, at the 5?-end, an mRNA-complementary region complementary to a sequence at the 5?-end of each mRNA portion, and, at the 3?-end, a self-complementary region complementary between molecules of the DNA linker, the DNA linker being phosphorylated at the 5?-end.

Abstract: The present invention provides a method for detecting an interaction, which method can solve not only the problem of false negatives but also the problem of false positives.

Abstract: A method for analyzing biomolecular interactions, which method can be carried out without performing affinity selection using an immobilized bait, is provided. mRNA portions of assignment molecules that interacted with each other are linked together by annealing via a DNA linker for linking mRNA portions of assignment molecules together, the DNA linker comprising, at the 5?-end, an mRNA-complementary region complementary to a sequence at the 5?-end of each mRNA portion, and, at the 3?-end, a self-complementary region complementary between molecules of the DNA linker, the DNA linker being phosphorylated at the 5?-end.

Abstract: A method is provided for manufacturing a semiconductor device, wherein a p-type region and/or n-type pattern is formed on a surface of a semiconductor substrate, including ejecting at least one of etching paste, masking paste, doping paste, and electrode paste from an ejecting orifice of a nozzle toward the surface of the semiconductor substrate to form beads formed of the paste between the semiconductor substrate and the ejecting orifice and moving the semiconductor substrate relative to the nozzle thereby the paste is applied to the surface of the semiconductor substrate in a stripe shape.

Abstract: An organic El element includes an organic compound layer including at least an emissive layer interposed between a pair of electrodes, wherein the emissive layer includes a naphthacene derivative and an amount of a naphthacene precursor compound present in the emissive layer is 5.0 parts by weight or less with respect to 100 parts by weight of the naphthacene derivative.

Abstract: A donor substrate including a support; a light-to-heat conversion layer and a transfer prevention layer formed on the support; and a transferring material layer formed on a top surface of the light-to-heat conversion layer and the transfer prevention layer; where a transfer region and an antitransfer region are formed by combinations of the light-to-heat conversion layer and the transfer prevention layer, and the transferring material layer is formed on the whole surface of the transfer region and at least one part of the antitransfer region. A patterning method enables large-scale and high-accuracy fine patterning at low cost without causing deterioration of characteristics of thin films, which constitute devices such as organic light emitting devices, and a method for producing a device.

Abstract: A light emitting device material precursor represented by the Formula (1): (wherein R1 to R6 each may be the same or different and is selected from the group consisting of hydrogen, alkyl groups, cycloalkyl groups, alkenyl groups, cycloalkenyl groups, alkoxy groups, alkylthio groups, arylether groups, aryl thioether groups, aryl groups and heteroaryl groups, with the proviso that at least one of R1 to R6 has a fused aromatic hydrocarbon having two or more rings).

Abstract: The present invention is directed to a method for producing a device, comprising the steps of: applying, on a donor substrate, a precursor material which is solvent-soluble during application and is capable of being converted to a device-constituting material after the application; converting the precursor material to a device-constituting material; and transferring the material on the donor substrate onto a device substrate. According to the present invention, it is possible to produce an organic device that offers performance as high as that of an organic device produced by vapor deposition, and the present invention is particularly suitable for producing large-sized devices.

Abstract: Provided is a patterning method, wherein a donor substrate, in which a light-to-heat conversion layer and a division pattern are formed on a substrate and a transferring material exists within said division pattern, is opposed to a device substrate and said transferring material is transferred on the device substrate by irradiating the light-to-heat conversion layer with light so that at least a part of said transferring material and at least apart of said division pattern are simultaneously heated. The patterning method enables large size and highly accurate fine patterning without degrading characteristics of thin films such as organic EL materials.

Abstract: A highly fine organic electroluminescent device is provided. A method for manufacturing the organic electroluminescent device is provided for patterning a very fine light emitting layer, and a deposition mask is provided to be used in the patterning. For deposition of the light emitting layer, a mask member is provided with apertures (effective apertures) for forming the light emitting layer to be used for light emitting pixel and apertures (dummy apertures) not to be used for forming the light emitting pixel around an area (effective aperture area) separated by the outer edge of a group of the apertures. The light emitting layer is deposited by using the deposition mask.

Abstract: An integrated mask including a plurality of deposition masks, each deposition mask having an array of deposition apertures formed in accordance with a deposition pattern; and a base plate having a plurality of openings on which the deposition masks are arranged is provided. The deposition mass are retained to the base plate by engaging unit in a disengageable manner, and alignment marks used for positioning the deposition masks on the base plate are formed on the base plate. In addition a method and apparatus for fabricating the integrated mask, a method and apparatus for manufacturing an organic EL device using the integrated mask, and an organic EL device are provided.

Abstract: A highly fine organic electroluminescent device is provided. A method for manufacturing the organic electroluminescent device is provided for patterning a very fine light emitting layer, and a deposition mask is provided to be used in the patterning. For deposition of the light emitting layer, a mask member is provided with apertures (effective apertures) for forming the light emitting layer to be used for light emitting pixel and apertures (dummy apertures) not to be used for forming the light emitting pixel around an area (effective aperture area) separated by the outer edge of a group of the apertures. The light emitting layer is deposited by using the deposition mask.

Abstract: A method for producing an organic electroluminescent device, which is provided with first electrodes formed on a substrate, a thin film layer formed on the first electrode containing at least an emitting layer composed of an organic compound and a plurality of second electrodes formed on the thin film layer, and has a plurality of luminescent regions on said substrate, comprising the steps of forming spacers having a height at least partially exceeding the thickness of said thin film layer on the substrate, and vapor-depositing a deposit for patterning while the shadow mask having reinforcing lines formed across its apertures is kept in contact with said spacers. Highly precise fine patterning can be effected under wide vapor deposition conditions without degrading the properties of organic electroluminescent elements, and high stability can be achieved by a relatively simple process without limiting the structure of the electroluminescent device.

Abstract: A display device having a polyimide insulating layer is disclosed. The display device has a first electrode formed on a substrate, the polyimide insulating layer formed on the first electrode in such a way that the first electrode is partially exposed, and a second electrode facing the first electrode, wherein the polyimide insulating layer is a positive-type photosensitive polyimide.

Abstract: A method for producing an organic electroluminescent device, which is provided with first electrodes formed on a substrate, a thin film layer formed on the first electrode containing at least an emitting layer composed of an organic compound and a plurality of second electrodes formed on the thin film layer, and has a plurality of luminescent regions on said substrate, comprising the steps of forming spacers having a height at least partially exceeding the thickness of said thin film layer on the substrate, and vapor-depositing a deposit for patterning while the shadow mask having reinforcing lines formed across its apertures is kept in contact with said spacers.

Abstract: A method for producing an organic electroluminescent device, which is provided with first electrodes formed on a substrate, a thin film layer formed on the first electrode containing at least an emitting layer composed of an organic compound and a plurality of second electrodes formed on the thin film layer, and has a plurality of luminescent regions on said substrate, comprising the steps of forming spacers having a height at least partially exceeding the thickness of said thin film layer on the substrate, and vapor-depositing a deposit for patterning while the shadow mask having reinforcing lines formed across its apertures is kept in contact with said spacers. Highly precise fine patterning can be effected under wide vapor deposition conditions without degrading the properties of organic electroluminescent elements, and high stability can be achieved by a relatively simple process without limiting the structure of the electroluminescent device.

Abstract: A method for producing an organic electroluminescent device, the organic electroluminescent device comprising a first electrode formed on a substrate, a thin film layer on the first electrodes, the thin film layer comprising at least an emitting layer comprising an organic compound, a second electrode formed on the thin film layer, and a plurality of luminescent regions on the substrate, wherein the method for producing the organic electroluminescent device comprises forming spacers having a height exceeding a thickness of the thin film layer on the substrate and vapor-depositing a deposit while a mask portion of a shadow mask is kept in contact with the spacers, the shadow mask comprising apertures having reinforcing lines. Highly precise fine patterning can be effected under wide vapor deposition conditions without degrading the properties of organic electroluminescent elements, and high stability can be achieved by the method without limiting the structure of the electroluminescent device.

Abstract: A method for producing an organic electroluminescent device, which is provided with first electrodes formed on a substrate, a thin film layer formed on the first electrode containing at least an emitting layer composed of an organic compound and a plurality of second electrodes formed on the thin film layer, and has a plurality of luminescent regions on said substrate, comprising the steps of forming spacers having a height at least partially exceeding the thickness of said thin film layer on the substrate, and vapor-depositing a deposit for patterning while the shadow mask having reinforcing lines formed across its apertures is kept in contact with said spacers.