Abstract: According to one embodiment, a test element includes a base, a pair of optical element units, an optical waveguide unit, a detection unit and a holding unit. The base has transparency. The pair of optical element units are arranged away from each other on a major surface of the base. The optical waveguide unit is provided on the major surface of the base. The detection unit is provided on a major surface of the optical waveguide unit of between the optical element units. The major surface of the optical waveguide unit is an opposite side which touches the base. The holding unit is in a frame shape, and one end of the holding unit being is provided to protrude from a major surface of the detection unit. The detection unit includes a color former and a film-formed body holding the color former.

Abstract: According to one embodiment, a glucose sensor chip includes an optical waveguide layer on a main surface of a substrate, the optical waveguide layer including a pair of gratings which are separated each other, a sensing film on a surface of a portion of the optical waveguide layer between the pair of the gratings, the sensing film being constituted with a membrane polymer, a cross-linking polymer and a low-molecular compound, the sensing film including a first enzyme which oxidizes or reduces a color forming dye and a glucose, and a second enzyme which reacts with a product of the first enzyme and generates a material which produces the color forming dye.

Abstract: This method of analyzing a biological component includes steps of arranging an extraction medium holding part configured to be capable of holding a prescribed quantity of extraction medium for holding an extract extracted from a subject on the skin of the subject, transferring the extraction medium stored in a liquid storing part storing substantially the same quantity of the extraction medium as the prescribed quantity to the extraction medium holding part, transferring at least part of the extraction medium holding the extracted extract to a reaction part, and analyzing a result of detecting the extract.

Abstract: An optical glucose sensor chip includes a substrate, a pair of optical elements formed on a surface of the substrate for introducing light into the substrate and for emitting the light from the substrate, and a glucose sensing membrane formed on the surface of the substrate at a position between the optical elements. The sensing membrane includes a color reagent substrate, a first enzyme which oxidizes or reduces glucose, a second enzyme that generates a material which makes the color reagent substrate exhibit color by a reaction with a product obtained by oxidation or reduction of glucose, a nonionic cellulose derivative, and an ionic polymer into which a buffer is incorporated. At least one of the first and second enzymes is coated with the ionic polymer, and the color reagent substrate. The first and second enzymes, the buffer and the ionic polymer are supported by the nonionic cellulose derivative.

Abstract: A cathode substrate according to the present invention comprises a cathode electrode layer (12), insulator layer (14) and gate electrode layer (15) formed sequentially on a substrate to be processed (11). The insulator layer includes a hole (14a) formed therethrough. A gate aperture (16) is formed through the gate electrode layer. An emitter (E) is then provided at the bottom of the hole (14a). In this case, the gate aperture comprises a plurality of openings (16a), the total area of which is smaller than the area of top opening of the hole in the insulator layer. The openings are arranged densely at a position opposite to the emitter and just above the hole of the insulator layer.

Abstract: A color reaction detecting device includes: a support configured to support a sensor chip, the sensor chip including a thin film which causes a color reaction by a substance released from an object under inspection; a light source configured to introduce light into the sensor chip supported by the support; a photodetector configured to sense light emitted from the sensor chip; a temperature sensor configured to measure temperature; and a control unit. The control unit computes an amount of color reaction in the sensor chip using a result of the sensing by the photodetector and a result of the measurement by the temperature sensor.

Abstract: An optical glucose sensor chip includes a substrate, a pair of optical elements formed on a surface of the substrate for introducing light into the substrate and for emitting the light from the substrate, and a glucose sensing membrane formed on the surface of the substrate at a position between the optical elements. The sensing membrane includes a color reagent substrate, a first enzyme which oxidizes or reduces glucose, a second enzyme that generates a material which makes the color reagent substrate exhibit color by a reaction with a product obtained by oxidation or reduction of glucose, a nonionic cellulose derivative, and an ionic polymer into which a buffer is incorporated. At least one of the first and second enzymes is coated with the ionic polymer, and the color reagent substrate. The first and second enzymes, the buffer and the ionic polymer are supported by the nonionic cellulose derivative.

Abstract: In forming a carbon nanotube on the surface of a substrate surface by the plasma CVD method in accordance with the prior art, since the substrate is heated by plasma, it is difficult to suitably control the temperature of substrate and thus impossible to form the carbon nanotube at a low temperature. According to the present invention there is provided a method for forming a carbon nanotube comprising steps of introducing a carbon included feedstock gas into a vacuum chamber; generating plasma so that a substrate is not exposed to plasma during a vapor phase growth of the carbon nanotube on a substrate surface; heating the substrate to a predetermined temperature by using a heater; and promoting the growth of the carbon nanotube on the substrate surface with it being contacted by the feedstock gas decomposed by plasma.

Abstract: A cathode substrate according to the present invention comprises a cathode electrode layer(12), insulator layer(14) and gate electrode layer(15) formed sequentially on a substrate to be processed (11). The insulator layer includes a hole (14a) formed there through. A gate aperture (16) is formed through the gate electrode layer. An emitter (E) is then provided at the bottom of the hole (14a). In this case, the gate aperture comprises a plurality of openings (16a), the total area of which is smaller than the area of top opening of the hole in the insulator layer. The openings are arranged densely at a position opposite to the emitter and just above the hole of the insulator layer.

Abstract: A porous SOG film is formed by preparing an organic silane solution containing an organic silane, water and an alcohol, subjecting the organic silane to acid hydrolysis or alkali hydrolysis and then heat-treating the resulting reaction system in the presence of a surfactant to thus form a porous SiO2 film to use for an interlayer insulating film. Alternatively, a porous SOG film is formed by repeating the foregoing step at least one time; or by forming a hydrophobic film on the porous SiO2 film prepared by the foregoing step by the CVD or sputtering technique to thus cap the surface of the porous film; or repeating the porous film-forming and capping steps at least one time. Moreover, after the preparation of the foregoing porous SiO2 film, it is subjected to either of the oxygen plasma-treatment, electron beam-irradiation treatment and UV light-irradiation treatment to remove the unreacted OH groups remaining on the porous film and to thus form a porous SOG film.

Abstract: A method for preparing a graphite nanofiber is herein provided, which comprises a raw gases are supplied on the surface of a substrate provided thereon with a catalyst layer for the growth of graphite nanofibers according to the CVD technique, wherein the method is characterized by forming a catalyst layer having a desired thickness and then forming, on the catalyst layer of the substrate, a graphite nanofiber whose overall thickness is controlled and which comprises a graphite nanofiber layer and a non-fibrous layer. The resulting graphite nanofibers can be used in an emitter or a field emission display element. The thickness of the catalyst layer formed on a substrate is controlled by the method and this in turn permits the control of the thickness of the non-fibrous layer formed on the catalyst layer and the control of the thickness of the graphite nanofibers likewise formed on the catalyst layer.

Abstract: A graphite nanofiber material herein provided has a cylindrical structure in which graphene sheets each having an ice-cream cone-like shape whose tip is cut off are put in layers through catalytic metal particles; or a structure in which small pieces of graphene sheets having a shape adapted for the facial shape of a catalytic metal particle are put on top of each other through the catalytic metal particles. The catalytic metal comprises Fe, Co or an alloy including at least one of these metals. The material can be used for producing an electron-emitting source, a display element, which is designed in such a manner that only a desired portion of a luminous body emits light, a negative electrode carbonaceous material for batteries and a lithium ion secondary battery. The electron-emitting source (a cold cathode ray source) has a high electron emission density and an ability of emitting electrons at a low electric field, which have never or less been attained by the carbon nanotube.

Abstract: A porous SOG film is formed by preparing an organic silane solution containing an organic silane, water and an alcohol, subjecting the organic silane to acid hydrolysis or alkali hydrolysis and then heat-treating the resulting reaction system in the presence of a surfactant to thus form a porous SiO2 film to use for an interlayer insulating film. Alternatively, a porous SOG film is formed by repeating the foregoing step at least one time; or by forming a hydrophobic film on the porous SiO2 film prepared by the foregoing step by the CVD or sputtering technique to thus cap the surface of the porous film; or repeating the porous film-forming and capping steps at least one time. Moreover, after the preparation of the foregoing porous SiO2 film, it is subjected to either of the oxygen plasma-treatment, electron beam-irradiation treatment and UV light-irradiation treatment to remove the unreacted OH groups remaining on the porous film and to thus form a porous SOG film.

Abstract: A graphite nanofiber material herein provided has a cylindrical structure in which graphene sheets each having an ice-cream cone-like shape whose tip is cut off are put in layers through catalytic metal particles; or a structure in which small pieces of graphene sheets having a shape adapted for the facial shape of a catalytic metal particle are put on top of each other through the catalytic metal particles. The catalytic metal comprises Fe, Co or an alloy including at least one of these metals. The material can be used for producing an electron-emitting source, a display element, which is designed in such a manner that only a desired portion of a luminous body emits light, a negative electrode carbonaceous material for batteries and a lithium ion secondary battery. The electron-emitting source (a cold cathode ray source) has a high electron emission density and an ability of emitting electrons at a low electric field, which have never or less been attained by the carbon nanotube.