A fine cellulose fiber in which when the fine cellulose fiber is formed into a dispersion, the dispersion has very high light transmittance and viscosity, and a method for producing the fine cellulose fiber.

The fine cellulose fiber has a fiber width of 1 to 200 nm. A part of hydroxy groups of the cellulose fiber are substituted with a predetermine functional group to introduce an ester of phosphorus-oxo acid, and the introduction amount of the functional group is more than 2.0 mmol per 1 g of the cellulose fiber. For producing the fine cellulose fiber, to cellulose fiber is added a solution having a pH of less than 3.0 and including an additive (A) containing at least one of a phosphorus-oxo acid and a phosphorus-oxo acid metal salt and an additive (B) containing at least one of urea and a urea derivative, and the mixture is heated to perform fibrillation.

A composite material includes biodegradable and/or renewable materials such as purified milk protein recovered as a byproduct in cheese making processes. The result is a material suitable for three-dimensional (3D) printing and extrusion based polymer processing, with improved properties but that is still environmentally friendly. Purified milk protein may be used to produce composite thermoplastic materials or resins. Additional chemical modification may improve the blending of purified milk protein.

A fabric comprising a warp component and a weft component. The warp component is made of a spun yarn that is 100% polyester fiber. The 100% polyester fiber spun yarn may be combined with one or more other yarns to form the warp component, such as a texturized polyester yarn but not limited thereto. Alternatively, the warp component is made of a spun yarn that is 100% acrylic fiber. The 100% acrylic fiber spun yarn may be combined with one or more other yarns to form the warp component, such as a texturized polyester yarn but not limited thereto. The weft component of the fabric may be formed of using one or more of manmade fibers and/or natural fibers. The fabric may be used to make bedding products.

Disclosed herein are curled fiber mats. Also disclosed herein are methods of making curled fiber mats, comprising forming a fibrous media from a fibrous material, treating the fibrous media with a crosslinking agent to form a treated fibrous media, and drying and/or curing the treated fibrous media to produce a curled fiber mat that has a permanent curl.

A material web is disclosed. The material web includes a fiber layer having a first side and an opposing second side. The fiber layer has a plurality of fibers, each of which having an intimate admixture of a thermoplastic polymer, and a wax and/or oil, wherein at least some of the wax and/or oil is exposed at an outer surface of the fibers. A surface energy treatment is disposed on the first side and/or the second side of the fiber layer.

A method for wet processing of hemp fibers for commercial use is provided. The method includes steps of loading raw hemp fibers with water into a vessel and heating the contents of the vessel. The method also includes the addition of a sequence of certain chemical compounds, which include a scouring agent, a wetting agent, a caustic compound, an acidic compound, a lubricant, and a softening agent. The water may be heated to boiling during the process to aid in opening up the fibers during processing. Peroxide is not utilized in the process. The process produces commercially viable quantities of hemp fibers that are soft, clean, and easily spinnable while maintaining fiber burst strength.

An ornamental article includes a single piece of metal wire. The ornamental article includes a single piece of organic fiber twine knotted around the metal wire to produce an elongate member with first and second ends. The ornamental article further include at least one crimp connector located on at least one of the first and second ends. The ornamental article further includes a clasp located on one of the first and second ends for connecting to the other of the first and second ends.

A bedding includes: a cushion layer which is formed with a filament three-dimensional bonded member and which is breathable; a breathable water-repellent layer which is provided on the upper side of the cushion layer and which is breathable and water-repellent; and a breathable water-retentive layer which is provided on the upper side of the breathable water-repellent layer and which is water-retentive and is breathable during water retention.

The present invention provides a sheet structure comprising a carrier layer and a foamed cover layer which contains polyvinyl chloride, lignocellulosic based components and hollow microspheres, and a method for producing the sheet structure. The sheet structure can be used as an artificial leather, e.g. for flexible automotive interiors.

The present invention provides a novel miRNA extraction method and a method for analyzing miRNA extracted by using said miRNA extraction method. According to the present invention, provided is, for example, a method for extracting miRNA from extracellular vesicles in a sample solution, by using a device capable of capturing extracellular vesicles, the miRNA extraction method comprising: an extracellular vesicle capturing step for capturing extracellular vesicles in a sample solution onto a device by bringing the sample solution and the device in contact with each other; and a miRNA extraction step for homogenizing the extracellular vesicles by bringing the device having captured the extracellular vesicles in contact with a homogenization liquid for extracellular vesicles to extract miRNA from the extracellular vesicle into the homogenization liquid.