Abstract: At a present tongue, a vertical rib is provided between a first elastic piece and a second elastic piece of a cover. When a guide bar is displaced toward a vehicle rear side, and the guide bar abuts the first elastic piece and the second elastic piece, the guide bar abuts the vertical rib. Due thereto, imparting of load to the first elastic piece and the second elastic piece by the guide bar can be suppressed, and elastic deformation of the first elastic piece and the second elastic piece can be suppressed.

Abstract: The purpose of the present invention is to produce a chimeric antigen receptor (CAR) specific to glypican-1 (GPC-1) and to treat squamous cell carcinoma with genetically modified cells capable of expressing the CAR. The present invention provides: a chimeric antigen receptor for use in the treatment and/or prevention of squamous cell carcinoma, said chimeric antigen receptor comprising an extracellular domain capable of binding to GPC-1, a transmembrane domain and one or multiple intracellular domains, wherein at least one of the intracellular domains is an intracellular domain containing a primary cytosolic signaling sequence or an intracellular domain containing both a primary cytosolic signaling sequence and a secondary cytosolic signaling sequence; a genetically modified cell capable of expressing the chimeric antigen receptor; and a cell preparation containing the cell.

Abstract: At a present tongue, four suppressing portions are provided between both abutment portions of a tongue main body. In a state in which transverse direction both side portions of a webbing are nipped between a pressing portion of a clamp member and the both abutment portions, a transverse direction central side portion of the webbing is nipped between the pressing portion of the clamp portion and the respective suppressing portions. Due thereto, one of the transverse direction central side portion of the webbing and the transverse direction both side portions of the webbing is pulled by another, and sliding toward the side of the another can be suppressed.

Abstract: A transparent conductive film includes: a transparent substrate film; an antistripping layer with a thickness of 1.5 nm to 8 nm formed on one main surface of the substrate film; an optical adjustment layer with a thickness of 10 nm to 25 nm formed on the antistripping layer; and a transparent conductor layer with a pattern formed on the optical adjustment layer. The transmission Y value measured from a side of the transparent conductor layer is 88.0 or more and the reflection color difference ?E between a pattern portion and a non-pattern portion is 7.0 or less.

Abstract: There is provided a transparent conductive film which has a transparent conductive layer having low specific resistance and has excellent scratch resistance. A transparent conductive film of the present invention includes: a transparent film substrate; at least three undercoat layers; and a transparent conductive layer in this order. The at least three undercoat layers include: a first undercoat layer formed by a wet coating method; a second undercoat layer that is a metal oxide layer having an oxygen deficient; and a third undercoat layer that is an SiO2 film from a side of the film substrate. The third undercoat layer has a density of 2.0 g/cm3 or more and 2.8 g/cm3 or less. The transparent conductive layer has specific resistance of 1.1×10?4 ?·cm or more and 3.8×10?4 ?·cm or less.

Abstract: A transparent conductive film 1 includes a transparent substrate 2; a first optical adjustment layer 4 disposed on one side in the thickness direction of the transparent substrate 2 and made of a resin layer; an inorganic substance layer 5 disposed on one side in the thickness direction of the first optical adjustment layer 4 so as to make contact with the first optical adjustment layer 4; and a transparent conductive layer 6 disposed on one side in the thickness direction of the inorganic substance layer 5. The inorganic substance layer 5 has a thickness of 10 nm or less, and the surface of the one side in the thickness direction of the transparent conductive layer 6 has a surface roughness of 1.40 nm or less.

Abstract: A transparent conductive film includes: a transparent film substrate; an optical adjustment layer; and a transparent conductive layer, in which the optical adjustment layer and the transparent conductive layer are laminated on a main surface of the transparent film substrate in this order; The optical adjustment layer includes a dry-type optical adjustment layer including an inorganic oxide. The transparent conductive layer includes a metal oxide including indium. The transparent conductive layer is crystalline and has an X-ray diffraction peak respectively at least on a (400) plane and a (440) plane. When the (400) plane has an X-ray diffraction peak intensity of I400 and the (440) plane has an X-ray diffraction peak intensity of I440, a ratio I440/I400 of the X-ray diffraction peak intensity is in a range from 1.0 to 2.2.

Abstract: A transparent electroconductive film with a protective film includes: a transparent electroconductive film including a film substrate, an optical adjustment layer formed on one main surface of the film substrate, and a transparent conductive layer formed on the optical adjustment layer; and a protective film bonded to a main surface of the film substrate on a side opposite to the transparent conductive layer, wherein the transparent electroconductive film and the protective film are thermally shrinkable in at least one direction in a main surface, and the absolute value of the maximum thermal shrinkage ratio (%) of the transparent electroconductive film in a main surface is smaller than the absolute value of the maximum thermal shrinkage ratio (%) of the protective film in a main surface, and the difference between the absolute values is 0.05% to 0.6%.

Abstract: There is provided a transparent conductive film achieving low resistance characteristics of a transparent conductive layer. The present invention provides a transparent conductive film including: a polymer film substrate; and a transparent conductive layer formed on at least one surface of the polymer film substrate, wherein the transparent conductive film includes an inorganic undercoat layer formed by means of a vacuum film-forming method between the polymer film substrate and the transparent conductive layer, and an existing atomic amount of carbon atoms in the transparent conductive layer is 3×1020 atoms/cm3 or less.

Abstract: Provided is a transparent conductive film having excellent moist-heat resistance and capable of maintaining a low specific resistance value. The present invention relates to a transparent conductive film including: a transparent film substrate; at least three undercoat layers; and a crystalline transparent conductive layer in this order, wherein: the at least three undercoat layers include: a first undercoat layer formed by a wet coating method; a second undercoat layer that is a metal oxide layer having an oxygen deficient; and a third undercoat layer that is a metal oxide layer having a stoichiometric composition from a side of the film substrate; the transparent conductive layer has a surface roughness Ra of 0.1 nm or more and 1.6 nm or less; and the transparent conductive film has specific resistance of 1.1×10?4 ?·cm or more and 3.8×10?4 ?·cm or less.

Abstract: A transparent conductive film 1 includes, in this order, a transparent substrate 2, a first optical adjustment layer 4, an inorganic layer 5, and a transparent conductive layer 6. The first optical adjustment layer 4 has refraction nC lower than refraction nA of the transparent substrate 2, and thickness TC of 10 nm or more and 35 nm or less. The inorganic layer 5 has refraction nD that is lower than the absolute value |nC×1.13| of a value obtained by multiplying the refraction nC of the first optical adjustment layer 4 by 1.13.

Abstract: There is provided a transparent conductive film which has a transparent conductive layer having low specific resistance and has excellent scratch resistance. A transparent conductive film of the present invention includes: a transparent film substrate; at least three undercoat layers; and a transparent conductive layer in this order. The at least three undercoat layers include: a first undercoat layer formed by a wet coating method; a second undercoat layer that is a metal oxide layer having an oxygen deficient; and a third undercoat layer that is an SiO2 film from a side of the film substrate. The third undercoat layer has a density of 2.0 g/cm3 or more and 2.8 g/cm3 or less. The transparent conductive layer has specific resistance of 1.1×10?4 ?·cm or more and 3.8×10?4 ?·cm or less.

Abstract: There is provided a transparent conductive film achieving low resistance characteristics of a transparent conductive layer. The present invention provides a transparent conductive film including: a polymer film substrate; and a transparent conductive layer formed on at least one surface of the polymer film substrate by means of a sputtering method using a sputtering gas including argon, wherein an existing atomic amount of argon atoms in the transparent conductive layer is 0.24 atomic % or less; an existing atomic amount of hydrogen atoms in the transparent conductive layer is 13×1020 atoms/cm3 or less; and the transparent conductive layer has a specific resistance of 1.1×10?4 ?·cm or more and 2.8×10—4 ?·cm or less.

Abstract: An organic EL device includes: a first substrate having electrical conductivity; an organic layer formed on the first substrate; a second substrate having translucency; and an electrode layer formed on the second substrate. The electrode layer on the first substrate and the organic layer on the second substrate contact each other. The organic layer is not formed in the peripheral portion of the second substrate. In the region where the organic layer is not formed, a portion of the electrode layer is provided to extend, and the first substrate is not present to face the extended electrode layer, and the portion of the electrode layer is exposed to form an electrode portion. Thus, the electrode portion can be formed by a simple procedure in which, for example, the first substrate is removed, and the organic EL device can be efficiently manufactured.

Abstract: A luminescent element includes a first electrode layer, a functional layer including an emitting layer and being disposed on the first electrode layer, a conductive layer permitting transmission of light and being disposed on the functional layer, and a first patterned electrode and a second patterned electrode each having an opening and being disposed on the conductive layer to be separated from each other. The conductive layer extends from a first area in which the first patterned electrode is disposed on the conductive layer to a second area in which the second patterned electrode is disposed on the conductive layer.

Abstract: A conveyance receiver for a honeycomb formed body is a conveyance receiver where a pillar, clayey honeycomb formed body extruded from a die is placed with its central axis set horizontally and moves on a conveyance path to convey the honeycomb formed body to a next process, and the conveyance receiver includes a concaved surface concaved to both end faces parallel to a surface perpendicular to the central axis of the honeycomb formed body to be placed, and that is a surface in contact with a side surface of the honeycomb formed body to be conveyed; and a receiver main body constituted of a plurality of members, and coupling means that couples the members to one another, and the receiver main body at least has a first member at the one end face side and a second member at the other end face side as the members.

Abstract: A transparent conductive film 1 includes a transparent substrate 2; a first optical adjustment layer 4 disposed on one side in the thickness direction of the transparent substrate 2 and made of a resin layer; an inorganic substance layer 5 disposed on one side in the thickness direction of the first optical adjustment layer 4 so as to make contact with the first optical adjustment layer 4; and a transparent conductive layer 6 disposed on one side in the thickness direction of the inorganic substance layer 5. The inorganic substance layer 5 has a thickness of 10 nm or less, and the surface of the one side in the thickness direction of the transparent conductive layer 6 has a surface roughness of 1.40 nm or less.

Abstract: An organic EL device includes a metal layer which is provided with a nano-order-sized unevenness on one surface and plural organic layers which include a light emitting layer provided on the one surface side of the metal layer, and a height of each unevenness at respective interfaces in the organic layer is made smaller than an unevenness provided on the metal layer. According to the above configuration, the unevenness on one surface of the metal layer changes a surface plasmon to a propagation light and a light loss can be suppressed, and moreover, each unevenness of respective interfaces of the respective organic layers is made smaller than the unevenness on the surface of the metal layer, so that a short circuit inside the device can be suppressed.

Abstract: A conveyance receiver for a honeycomb formed body is a conveyance receiver where a pillar, clayey honeycomb formed body extruded from a die is placed with its central axis set horizontally and moves on a conveyance path to convey the honeycomb formed body to a next process, and the conveyance receiver includes a concaved surface concaved to both end faces parallel to a surface perpendicular to the central axis of the honeycomb formed body to be placed, and that is a surface in contact with a side surface of the honeycomb formed body to be conveyed; and a receiver main body constituted of a plurality of members, and coupling means that couples the members to one another, and the receiver main body at least has a first member at the one end face side and a second member at the other end face side as the members.

Abstract: An organic EL device includes a first substrate including a cathode layer (a first electrode layer), an organic layer formed on the cathode layer, an anode layer (a second electrode layer) formed on the organic layer, and a second substrate joined to the anode layer by an adhesive layer. The anode layer is provided so as to extend to an outer peripheral side of a region where the organic layer is present, the second substrate and the adhesive layer are not present in a portion which faces a region at an outer peripheral side of the extended anode layer, and the cathode layer and the extended anode layer are exposed from the second substrate to constitute a cathode taking-out portion and an anode taking-out portion, respectively.