Abstract: Disclosed is an isolated monoclonal antibody against a human Transforming Growth Factor-? (TGF-?) Latency Associated Protein (LAP) degradate, the isolated monoclonal antibody being capable of recognizing an integrin binding site in the human TGF-? LAP degradate.

Abstract: Disclosed is an isolated monoclonal antibody against a human TGF-? LAP degradate, the isolated monoclonal being capable of recognizing an integrin binding site in the human TGF-? LAP degradate.

Abstract: Provided is a test method for discriminating a liver injury type using as an indicator a level of lithocholic acid (hereinafter abbreviated as LCA) in a biological sample of a subject. That is, provided is a test method comprising measuring a level of LCA in a biological sample collected from a subject, and discriminating a liver injury type as hepatocellular injury type, cholestasis type, or a mixed type thereof using the measured level of LCA as an indicator.

Abstract: Provided is a test method for discriminating a liver injury type using as an indicator a level of lithocholic acid (hereinafter abbreviated as LCA) in a biological sample of a subject. That is, provided is a test method comprising measuring a level of LCA in a biological sample collected from a subject, and discriminating a liver injury type as hepatocellular injury type, cholestasis type, or a mixed type thereof using the measured level of LCA as an indicator.

Abstract: A lamp capable of efficiently dissipating heat generated in a semiconductor light-emitting element is provided. A lamp which emits light includes: a mounting board on which a semiconductor light-emitting element is mounted; a first housing thermally coupled with the mounting board; and a second housing including a power receiving unit which receives power for causing the semiconductor light-emitting element to emit light. The first housing is disposed closer to an illuminated area than the second housing is, and includes a first exposed surface exposed at least to the illuminated area.

Abstract: A lamp capable of efficiently dissipating heat generated in a semiconductor light-emitting element is provided. A lamp which emits light includes: a mounting board on which a semiconductor light-emitting element is mounted; a first housing thermally coupled with the mounting board; and a second housing including a power receiving unit which receives power for causing the semiconductor light-emitting element to emit light. The first housing is disposed closer to an illuminated area than the second housing is, and includes a first exposed surface exposed at least to the illuminated area.

Abstract: The orientation of fluorescent lamps is detected in a manufacturing method for a direct backlight unit that alternates orientations of adjacent fluorescent lamps. In a preparation step of the manufacturing method for the backlight unit of the present invention, a plurality of fluorescent lamps are prepared. In each of the fluorescent lamps, a length (a1) from a first sealed portion of a glass bulb (26) to a non-phosphor layer (32) area is shorter than a length (a2) from a second sealed portion to a non-phosphor layer (32) area (a1<a2). In a detection step, the difference between the lengths is detected with use of a sensor. In an installation step, the fluorescent lamps are arranged with use of the detection results so that the first and second ends alternate on a same side of a housing.

Abstract: The orientation of fluorescent lamps is detected in a manufacturing method for a direct backlight unit that alternates orientations of adjacent fluorescent lamps. In a preparation step of the manufacturing method for the backlight unit of the present invention, a plurality of fluorescent lamps are prepared. In each of the fluorescent lamps, a length (a1) from a first sealed portion of a glass bulb (26) to a non-phosphor layer (32) area is shorter than a length (a2) from a second sealed portion to a non-phosphor layer (32) area (a1<a2). In a detection step, the difference between the lengths is detected with use of a sensor. In an installation step, the fluorescent lamps are arranged with use of the detection results so that the first and second ends alternate on a same side of a housing.

Abstract: A fluorescent lamp includes a glass container (204) having mercury enclosed therein, and a phosphor layer (202) formed on an inner side of the glass container (204). The phosphor layer (202) includes phosphor particles (202a) and rod-shaped bodies (202b) composed of a metal oxide and spanning between the phosphor particles. The rod-shaped bodies (202b) have a thickness of, for example, 1.5 [?m] or less. Pairs of adjacent phosphor particles may be spanned by more than one rod-shaped body.

Abstract: A cold-cathode fluorescent lamp including a glass bulb, a pair of hollow electrodes, and a pair of electrically connected terminals. The hollow electrodes each include an electrode body and a lead wire. The hollow electrodes are hermetically connected to the glass bulb at both ends of the glass bulb. The pair of electrically connected terminals are thin coats that are, except for connection portions connected to lead wires, provided on an outer surface of the glass bulb at both ends of the glass bulb.

Abstract: A backlight unit has an external electrode fluorescent lamp in an housing. The external electrode fluorescent lamp includes a glass bulb having a discharge space inside, and electrodes around both ends of the glass bulb. A protective layer and a phosphor layer are formed on an internal surface of the glass bulb in this order. The glass bulb is made of soda glass, and sodium oxide precipitated from this soda glass appears on part of the internal surface of the glass bulb where the protective layer is not formed, so as to be exposed to the discharge space.

Abstract: A discharge lamp includes a glass bulb and a pair of electrodes provided at both ends of the glass bulb. At least one of the electrodes is an external electrode formed on an outer surface of the glass bulb as a thin layer whose maximum thickness is 70 ?m or less, and an end portion of the external electrode becomes smaller in thickness towards an end of the external electrode.

Abstract: A cold cathode fluorescent lamp includes a glass bulb (16), a protective film (22) formed on an inner face of the glass bulb, and a phosphor layer (24) that overlaps the protective film and that contains blue phosphor particles (26B), green phosphor particles (26) and red phosphor particles (26). The glass bulb has been formed from soda glass, and the blue phosphor particles have been coated with a metal oxide (30). Also, the protective film is made of silica (SiO2). Since the protective film has been provided in the fluorescent lamp and since the blue phosphor particles, which readily deteriorate, have been coated with the metal oxide, a good luminance maintenance rate is obtained. In addition, although the glass bulb of the fluorescent lamp is made of soda glass, since the protective film is made of silica, the fluorescent lamp obtains an initial luminance equivalent to the initial luminance of a fluorescent lamp whose glass bulb is made of borosilicate glass.

Abstract: A backlight unit has an external electrode fluorescent lamp in a housing. The external electrode fluorescent lamp includes a glass bulb having a discharge space inside, and electrodes around both ends of the glass bulb. A protective layer and a phosphor layer are formed on an internal surface of the glass bulb in this order. The glass bulb is made of soda glass, and sodium oxide precipitated from this soda glass appears on part of the internal surface of the glass bulb where the protective layer is not formed, so as to be exposed to the discharge space.

Abstract: The present invention relates to a fluorescent lamp, and in particular to a fluorescent lamp with an improved in-dark starting characteristic. A fluorescent lamp includes: a glass bulb (101) having a discharge space therein; two external electrodes (102 and 103) provided at both ends of the glass bulb; and a phosphor layer (106) provided on an inner surface of the glass bulb. The glass bulb is made of glass that contains 3% to 20% inclusive of sodium oxide. The phosphor layer includes phosphor particles (106R and 106G) containing no alumina and phosphor particles (106B) containing alumina. A metal oxide (107) is attached to surfaces of the phosphor particles containing alumina. Sodium oxide precipitated on the inner surface of the glass bulb improves the in-dark starting characteristic. The phosphor particles containing alumina are protected by the metal oxide for being susceptible to deterioration due to reaction thereof with sodium oxide.

Abstract: A discharge lamp includes a glass bulb and a pair of electrodes provided at both ends of the glass bulb. At least one of the electrodes is an external electrode formed on an outer surface of the glass bulb as a thin layer whose maximum thickness is 70 ?m or less, and an end portion of the external electrode becomes smaller in thickness towards an end of the external electrode.

Abstract: A backlight unit has an external electrode fluorescent lamp in an housing. The external electrode fluorescent lamp includes a glass bulb having a discharge space inside, and electrodes around both ends of the glass bulb. A protective layer and a phosphor layer are formed on an internal surface of the glass bulb in this order. The glass bulb is made of soda glass, and sodium oxide precipitated from this soda glass appears on part of the internal surface of the glass bulb where the protective layer is not formed, so as to be exposed to the discharge space.

Abstract: A cold-cathode fluorescent lamp including a glass bulb, a pair of hollow electrodes, and a pair of electrically connected terminals. The hollow electrodes each include an electrode body and a lead wire. The hollow electrodes are hermetically connected to the glass bulb at both ends of the glass bulb. The pair of electrically connected terminals are thin coats that are, except for connection portions connected to lead wires, provided on an outer surface of the glass bulb at both ends of the glass bulb.

Abstract: Human hepatoma-derived cell line FLC-4 (deposited with the National Institute of Bioscience and Human-Technology, the Agency of Industrial Science and Technology under Accession Number FERM BP-5165), as well as a method for large-scale production of albumin by culturing the cell line with a radial-flow type bioreactor are provided.