A flexible material is disclosed comprising a flexible substrate, a sorbent comprising zirconium hydroxide and a binder, wherein the solids weight ratio of the binder to the zirconium hydroxide is in the range 1:1 to 1:120. Also disclosed is a process for production of a fabric, comprising: providing a flexible material, providing at least one sorbent dispersion comprising zirconium hydroxide and a binder, applying the sorbent dispersion to the flexible material to produce a treated flexible material, squeezing the treated flexible material under pressure, and passing the pressed treated flexible material through a stenter.

A method for producing a finished leather substitute, finished leather substitutes obtainable by such method, and uses thereof are provided. Specifically, a method for producing a finished leather substitute is provided, comprising providing a sheet material grown from mycelium having a top surface layer and a bottom surface, and applying at least one finishing coating to the bottom surface only.

The present disclosure relates to a method for producing leather comprising the step of culturing cells on macroporous polymeric scaffold. The present disclosure also relates to leather obtainable by this method.

This invention, in embodiments, relates to a roofing material comprising (a) a substrate having a top surface and a back surface, (b) a plurality of self-healing particles embedded into the substrate, and (c) a coating applied onto the substrate having the plurality of self-healing particles embedded therein, to provide a coated substrate. The plurality of self-healing particles can be embedded into the top surface and/or the back surface of the substrate. The roofing material can further include a plurality of roofing granules applied to a top surface of the coating of the coated substrate. This invention, in embodiments, further relates to a method of preparing such a roofing material.

An abrasion resistant finish for a fungal material, the finishing comprising an optimum quantity biodegradable polylactic acid plastic (PLA) dispersed in water to produce a PLA mixture. When the PLA mixture is applied to the fungal material, water carries the PLA deeply into the matrix of the fungal hyphae to a depth at least 2 N/10 mm or 1% of the thickness of the fungal material, whichever is greater. The finish fortifies the hyphal structure as the water evaporates and creates a PLA coating on the fungal material with improved abrasion resistance and water resistance.

This invention, in embodiments, relates to a roofing material comprising (a) a substrate having a top surface and a back surface, (b) a plurality of self-healing particles embedded into the substrate, and (c) a coating applied onto the substrate having the plurality of self-healing particles embedded therein, to provide a coated substrate. The plurality of self-healing particles can be embedded into the top surface and/or the back surface of the substrate. The roofing material can further include a plurality of roofing granules applied to a top surface of the coating of the coated substrate. This invention, in embodiments, further relates to a method of preparing such a roofing material.

The subject matter of the invention is an adhesive tape, in particular a wrapping tape for sheathing cables in automobiles. The adhesive tape is equipped with a textile support and at least one adhesive layer applied to one or both sides of the support. The support is coloured by an organic dye which is composed of yellow and red pigments. The yellow pigments are based on anthraquinone. According to the invention, pigments based on perylene are used as red pigments.