A gas barrier laminate having a laminate structure including a paper base material and a transparent vapor-deposited layer, in which the paper base material has a maximum light transmittance of 0.85% or more for a light beam having at least one wavelength among light beams having a wavelength within a range of 300 nm to 800 nm.

The present invention aims at dissolving hydrogen gas in a liquid and maintaining the solubility of the hydrogen gas in the liquid at a high state. A sealing bag 1 that dissolves hydrogen gas in a liquid by being put into the liquid includes a hydrogen permeable film that can permeate hydrogen gas that is sealed and filled in the sealing bag to outside. By sinking this sealing bag 1 into the liquid in advance, the hydrogen gas that is permeated through the hydrogen permeable film is dissolved in the liquid. Furthermore, since the hydrogen gas is continuously permeated little by little through the hydrogen permeable film, the solubility of the hydrogen in the liquid can be maintained at a high state.

A packaging container that can be easily disassembled is provided at low cost. The packaging container is formed by a laminate including a base layer being folded into a box shape and each end thereof being overlapped to be sealed with each other, the laminate having a fragile part formed thereon. The laminate further has, for example, a film layer, and includes, as a fragile part, a first scored part formed on a base layer and a second scored part formed on a film in a 2.0-mm-wide band area with the first scored part being a widthwise center.

The invention relates to a pharmaceutical formulation comprising 40-O-(2-hydroxy)ethyl-rapamycin in a high drug load part and an immediate release part. In addition, the invention relates to a formulation comprising 40-O-(2-hydroxy)ethyl-rapamycin in a first layer and a surfactant in a layer beneath the first layer. The pharmaceutical composition is particularly suitable for use as a medicament.

The present invention provides a laminate (10A) having a first gas barrier layer (11) formed of a gas barrier transparent resin film and a second gas barrier layer (12) formed of a metal foil, in which at least one adhesive layer (X) (21) formed of an adhesive (x) including a polyepoxy resin as a main ingredient and a polyamine resin as a curing agent is provided between the first gas barrier layer (11) and the second gas barrier layer (12).

The present disclosure is directed to a package of one or more moisture- and/or humidity-sensitive unit dose products. The package comprises a package material comprising natural fibers. The package comprises a plurality of panels comprising a consumer-facing panel. The package is sealed such that the one or more products are enclosed therein. The package material exhibits a HuBa value of greater than about 5 hours, according to the HuBa Test. The package is recyclable. The package comprises a side seal having a seal strength that is in the range of about 5.1 N/15 mm to about 15 N/15 mm, according to Seal Tensile Strength Test. The package material comprises a barrier film.

This disclosure concerns a barrier packaging film including a polyolefin substrate layer having a thickness in the range of from 10 m to 100 m, an inorganic coating layer, and a polymeric buffer layer positioned between the polyolefin substrate and the inorganic coating layer, the polymeric buffer layer in direct contact with the inorganic coating layer, wherein the inorganic coating layer comprises a wave structure characterized by an average amplitude in the range of from 0.25 m to 1.0 m and a wavelength in the range of from 2 m to 5 m. Also disclosed are packages (e.g., hermetically sealed packages) formed from the barrier packaging film.

Provided is a multilayered coextruded thermoplastic food casing comprising a porous inner layer capable of absorbing, retaining, desorbing and transferring at least one functional additive to food encased in said casing; a layer having a barrier effect for water vapor; and an adhesive layer, wherein the porosity of said porous inner layer is generated by (co)extruding a composition comprising a polymer and a supercritical pore-forming agent, and a method for producing said multilayered coextruded thermoplastic food casing.

A self-supporting packaging bag formed by heat-sealing two body portions each including a substrate layer and a sealant layer, to a bottom tape including a substrate layer and a sealant layer and having a mountain fold, includes two side seal portions adhering the two body portions to each other in a vertical direction of the self-supporting packaging bag; and bottom seal portions adhering the respective two body portions to the bottom tape in a horizontal direction of the self-supporting packaging bag, wherein the substrate layers and the sealant layers are made of similar resin materials; a ratio a/L of a minimum width a of each of the bottom seal portions to a distance L from a base of each of the body portions to the mountain fold is 0.15 or greater and 0.50 or less.

A laminated article includes at least a substrate layer and a sealant layer. The sealant layer is located on at least one outermost side of the laminated article, and the sealant layer is a resin layer containing a polyhydroxyalkanoate resin component. In differential scanning calorimetry of the polyhydroxyalkanoate resin component, a highest melting peak temperature is 130 C. or higher, and a total crystalline melting enthalpy calculated from all melting peaks is in a range of 20 to 65 J/g.