A method is provided for preparing a fibrous material of crosslinked microfibrillated cellulose. Dialdehyde microfibrillated cellulose is spun into a fibrous material; said fibrous material is pre- or post-treated (by reduction of pH) to provide crosslinking between the dialdehyde microfibrillated cellulose. Fibrous materials such as filaments or mats, and polymer composites comprising such materials are also described.

A method is provided for preparing a film of crosslinked microfibrillated cellulose. Phosphorylated microfibrillated cellulose is cast or wet-laid into a film; and then said film is post-treated (e.g. by heat-treatment) to provide crosslinking between the phosphorylated microfibrillated cellulose. Films and hygiene products comprising such films are also described.

In one inventive concept, a product for modifying a cellulose-lignin material with siloxane includes a mixture having a siloxane species, a metal catalyst, and a nonpolar solvent. The mixture is operative to modify a cellulose-lignin material with siloxane upon wetting of the cellulose-lignin material with the mixture and subsequent drying of the cellulose-lignin material. In another inventive concept, a product includes a siloxane-modified cellulose-lignin material having a cellulose-lignin network and a network of siloxane in cross-linking bridges in the cellulose-lignin network.

In one inventive concept, a product for modifying a cellulose-lignin material with siloxane includes a mixture having a siloxane species, a metal catalyst, and a nonpolar solvent. The mixture is operative to modify a cellulose-lignin material with siloxane upon wetting of the cellulose-lignin material with the mixture and subsequent drying of the cellulose-lignin material. In another inventive concept, a product includes a siloxane-modified cellulose-lignin material having a cellulose-lignin network and a network of siloxane in cross-linking bridges in the cellulose-lignin network.

The present invention is directed to a cellulosic fibre composition comprising regenerated cellulose and one or more additives, wherein a) the cellulosic fibre composition is produced by injecting an aqueous alkaline spindope solution or suspension comprising dissolved cellulose in a concentration from about 5% to about 12% by weight of spindope and at least one of an additive and a nano-sized structured particulate filler through a nozzle into an alkaline coagulation bath forming cellulosic filaments; and b) stretching or washing cellulosic filaments from a) in one or more stretching and washing baths forming a regenerated cellulosic fibre.

The present invention is directed to a cellulosic fibre composition comprising regenerated cellulose and one or more additives, wherein a) the cellulosic fibre composition is produced by injecting an aqueous alkaline spindope solution or suspension comprising dissolved cellulose in a concentration from about 5% to about 12% by weight of spindope and at least one of an additive and a nano-sized structured particulate filler through a nozzle into an alkaline coagulation bath forming cellulosic filaments; and b) stretching or washing cellulosic filaments from a) in one or more stretching and washing baths forming a regenerated cellulosic fibre.

The present invention is directed to provide a tumor sealant that causes no serious side effects or radiation by the agent and is used in a therapy that is an improvement of a very simple and low invasiveness therapy of starving tumor cells and makes radical cure possible. The present invention relates to a particle tumor sealant that can be injected. directly into needle-accessible tumor and that cuts off and/or isolates tumor tissue from surrounding tissue including blood vessels by permeating through blood vessels in the tumor site, selectively accumulating in and/or adhering to tumor tissue, swelling with water in the body, settling for a certain time and pressing tumor and peritumoral cells and/or blood vessels, and covering the whole tumor, or a particle tumor sealant that cuts off between blood vessels in a tumor site and tumor tissue.

The present invention relates to a reinforced composite material, comprising an organic polymer, a silicon polymer, and an interphase between said organic polymer and said silicon polymer, wherein said interphase comprises chemical bonds between the organic polymer and the silicon polymer, and to a method to obtain said reinforced composite material. The present disclosure can be used to improve the mechanical properties of silica aerogels by functionalization of textile materials.

The present invention relates to a reinforced composite material, comprising an organic polymer, a silicon polymer, and an interphase between said organic polymer and said silicon polymer, wherein said interphase comprises chemical bonds between the organic polymer and the silicon polymer, and to a method to obtain said reinforced composite material. The present disclosure can be used to improve the mechanical properties of silica aerogels by functionalization of textile materials.

The present invention relates to a method for manufacturing at least one layer of a film wherein the method comprises the steps of; providing a first suspension comprising microfibrillated cellulose, providing a second suspension comprising microfibrillated dialdehyde cellulose, mixing the first suspension with the second suspension to form a mixture, applying said mixture to a substrate to form a fibrous web and drying said web to form at least one layer of said film. The present invention further relates to a film comprising said at least one layer.