Abstract: The present disclosure relates to the pharmaceutical field. More specifically, it relates to methods for treating a tumor in a human subject in need thereof, said method comprising administering a therapeutically efficient amount of an anti-BTN3A antibody which induces the activation of V?9V?2 T cells, in combination with a therapeutically efficient amount of an anti-PD1/PDL1 treatment, wherein said subject is having relapsed or refractory tumors to anti-PD1/PDL1 treatment.

Abstract: The present invention relates to antibodies anti-sPLA2-IIA and uses thereof.

Abstract: The invention relates to an electrochemical device (1) having electrically controllable optical and/or energy transmission properties, of the type comprising two electrode coatings (4, 6) and, between them, an electrochemically active layer (6) made of an inorganic material capable of reversibly switching between two states having different optical and/or energy transmission properties by the insertion and extraction of ions. An electrolyte (8) is present between the electrochemically active layer and the second electrode coating. The material of the electrochemically active layer is a material, the insertion and extraction of the ions of which during switching between the two states correspond to a variation in the plasma wavelength ? of the material and in that the material has, at the plasma wavelength ?, a full width at half maximum ?? of the absorption spectrum equal to or less than 1 micron in the two states.

Abstract: One subject of the invention is a material comprising a substrate coated on at least one portion of at least one of its faces with a stack comprising a photocatalytic layer, the geometrical thickness of which is between 2 and 30 nm, and at least one pair of respectively high and low refractive index layers positioned underneath said photocatalytic layer so that in the or each pair, the or each high refractive index layer is closest to the substrate, said material being such that the optical thickness, for a wavelength of 350 nm, of the or each high refractive index layer, except the photocatalytic layer, is between 170 and 300 nm and the optical thickness, for a wavelength of 350 nm, of the or each low refractive index layer is between 30 and 90 nm.

Abstract: A process for manufacturing a mask having submillimetric openings, in which: for a masking layer, a solution of colloidal nanoparticles that are stabilized and dispersed in a first solvent is deposited, the particles having a given glass transition temperature Tg, the drying of the masking layer is carried out at a temperature below the temperature Tg until a mask having a two-dimensional network of submillimetric openings is obtained with substantially straight mask area edges, in a zone referred to as a network mask zone, a zone free of masking is formed on the face by mechanical and/or optical removal of at least one peripheral portion of the network mask zone. The invention also relates to the network mask and the grid with an electroconductive solid zone that are thus obtained.

Abstract: A radiation-collecting device includes at least one radiation-collecting element and a scattering layer placed, in relation to the element, on that side on which the radiation is incident on the device. The scattering layer has a transparent fibrous structure and a transparent medium for encapsulating the fibers of the fibrous structure, the absolute value of the difference between the refractive index of the fibers of the fibrous structure and the refractive index of the encapsulating medium being equal to or greater than 0.05.

Abstract: The present invention relates to antibodies anti-sPLA2-IIA and uses thereof.

Abstract: The present invention relates to isolated antibodies against human sPLA2-X and uses thereof.

Abstract: The present disclosure relates to isolated antibodies against human SPLA2-V and uses thereof.

Abstract: This substrate (11) for a device (50) that collects or emits radiation comprises a transparent polymer layer (1) and a barrier layer (2) on at least one face (1A) of the polymer layer. The barrier layer (2) consists of an antireflection multilayer of at least two thin transparent layers (21, 22, 23, 24) having both alternately lower and higher refractive indices and alternately lower and higher densities, wherein each thin layer (21, 22, 23, 24) of the constituent multilayer of the barrier layer (2) is an oxide, nitride or oxynitride layer.

Abstract: A process for manufacturing a mask having submillimetric openings, in which: for a masking layer, a first solution of colloidal nanoparticles in a first solvent is deposited, the particles having a given glass transition temperature Tg, the drying of the masking layer, known as the first masking layer, is carried out at a temperature below said temperature Tg until a mask having a two-dimensional network of substantially straight-edged submillimetric openings, that defines a mask zone known as a network mask zone is obtained, a solid mask zone is formed by a liquid deposition, on the face, of a second masking zone, the solid mask zone being adjacent to and in contact with the network mask zone, and/or at least one cover zone is formed, the cover zone being in contact with the network mask zone, and/or after the drying of the first masking layer, a filled mask zone is formed by filling, via a liquid route, openings of a portion of the network mask zone.

Abstract: The present invention relates to an electrochemical device (1) having electrically controllable optical and/or energy properties, comprising a first electrode coating (4), a second electrode coating (12) and an electrochemically active medium (6, 10) capable of switching reversibly between a first state and a second state of different optical transmission by supplying electrical power to the first electrode coating (4) and to the second electrode coating (12), the material of the electrode coatings being based on a metal oxide having a light transmission factor D65 equal to or greater than 60%, preferably equal to or greater than 80%, and having a concentration of free charge carriers such that the material has an absorption spectrum satisfying (????/2)?1.8 ?m, where ? is the plasma wavelength of the material and ?? is the full width at half maximum of the absorption spectrum at the plasma wavelength.

Abstract: The invention relates to an electrochemical device (1) having electrically controllable optical and/or energy transmission properties, of the type comprising two electrode coatings (4, 6) and, between them, an electrochemically active layer (6) made of an inorganic material capable of reversibly switching between two states having different optical and/or energy transmission properties by the insertion and extraction of ions. An electrolyte (8) is present between the electrochemically active layer and the second electrode coating. The material of the electrochemically active layer is a material, the insertion and extraction of the ions of which during switching between the two states correspond to a variation in the plasma wavelength ? of the material and in that the material has, at the plasma wavelength ?, a full width at half maximum ?? of the absorption spectrum equal to or less than 1 micron in the two states.

Abstract: An electroconductive layer (2) designed to be combined with a substrate having a glass function, said layer (2) being composed of a metal grid (9), characterized in that the metal grid (9) consists of a pure metal and in that it is coated with at least one electrochemical protection layer (10), especially a metal layer or a metal nitride layer.

Abstract: The present invention relates to an electrochromic device having at least one active area (CDEF), having, on a carrier substrate (3), a multilayer stack comprising a layer forming a lower electrode (4), various functional layers (7) at least one of which is an electrochromic layer, at least one (6, 7a) of these layers being electrically insulating, and an upper electrode (9), in which device: at least one partition (5) separating the surface of the lower electrode (4) into two isolated regions, namely a free region (4a) and an active region (4b) containing the active area (CDEF); and at least one partition (12) separating the surface of the upper electrode (9) into two regions electrically isolated from each other, namely a free region (9a) and an active region (9b) containing the active area (CDEF).

Abstract: A radiation-collecting device includes at least one radiation-collecting element and a scattering layer placed, in relation to the element, on that side on which the radiation is incident on the device. The scattering layer has a transparent fibrous structure and a transparent medium for encapsulating the fibers of the fibrous structure, the absolute value of the difference between the refractive index of the fibers of the fibrous structure and the refractive index of the encapsulating medium being equal to or greater than 0.05.

Abstract: The present invention relates to an electrochromic device comprising: at least one partition (12) that separates the surface of the upper electrode (9) into two regions isolated from each other, namely a free region (9a) and an active region; at least one partition (5) that separates the surface of the lower electrode (4) into two regions electrically isolated from each other, namely a free region (4a) and an active region (4b); at least one free region (9a) of the upper electrode (9) receives a first current-supply connector (15) soldered to the active zone (4b) of the lower electrode (4); and the active area (9b) of the upper electrode (9) is in electrical contact with the connection means (20, 21a) connected to a second current-supply connector (21) electrically isolated from the free zone (9a) connected to the lower electrode (4).

Abstract: An electrochromic device, with controlled transparency, for example of electrically controllable type, including between a transparent carrier substrate and a counter-substrate, at least one stack of functional layers, the outermost layers of which include electroconductive layers, the conductivity of at least one electroconductive layer not in contact with the carrier substrate being reinforced by a network of conductive elements in contact with this layer. The network includes a mesh, for which the area of the intermesh free space is substantially between 0.04 mm2 and 0.16 mm2 or in a vicinity of 0.09 mm2.

Abstract: Electrochemical/electrically controllable device having variable optical and/or energetic properties, including a first carrier substrate provided with an electrically conductive layer associated with a first stack of electrically active layers and a second carrier substrate provided with an electrically conductive layer associated with a second stack of electrically active layers, wherein the first and second stacks each function optically in series on at least a portion of their surface and are separated by an electrically insulating means, which is a gas, or is a vacuum.

Abstract: This substrate (11) for a device (50) that collects or emits radiation comprises a transparent polymer layer (1) and a barrier layer (2) on at least one face (1A) of the polymer layer. The barrier layer (2) consists of an antireflection multilayer of at least two thin transparent layers (21, 22, 23, 24) having both alternately lower and higher refractive indices and alternately lower and higher densities, wherein each thin layer (21, 22, 23, 24) of the constituent multilayer of the barrier layer (2) is an oxide, nitride or oxynitride layer.