A functionalized microporous, mesoporous, or nanoporous membrane, material, textile, composite, laminate, or the like, and/or a method of making or using such functionalized membranes. The functionalized porous membrane may be a functionalized microporous, mesoporous, or nanoporous membrane that has a functional molecule attached, such as a functional polymer, to the surface and/or internal fibrillar structure of the membrane.

An article may include first and second components comprising non-woven textiles and a third component positioned between the first two components. A first surface of the third component that is adjacent the first component comprises a thermoplastic polymer material, and the third component is fused with a first region of the first component and unfused with a second region of the first component. A method of manufacturing the article, which may be an article of wear, includes arranging the components to form a stacked configuration so that the third component is positioned between the first and second components. Heat and compression may be applied to at least a first region of the first component to fuse the first region with the third component, whereas a second region of the first component may remain unfused to the second component.

Aspects herein are directed to articles of apparel formed from a base textile and including a plurality of discrete overlay film structures affixed to the base textile at one or more locations on the article of apparel. When exposed to an external stimulus, the film structures undergo an increase in dimension in at least the z-direction and the base textile undergoes a decrease in dimension in one or more of the x-direction and the y-direction.

A knitted component includes a first yarn and a second yarn, where the first yarn comprises a thermoplastic material having a melting temperature. The first yarn is used to create window openings of different shapes and sizes within the knitted component. This is achieved by using the first yarn to releasably secure adjacent edges of a window opening. The first yarn is then heated to release, at least in part, the first yarn from the edges of the window opening, allowing the edges to separate and thereby form a window opening.

The present invention is directed to a hemostatic textile, comprising: a material comprising a combination of glass fibers and one or more secondary fibers selected from the group consisting of silk fibers; ceramic fibers; raw or regenerated bamboo fibers; cotton fibers; rayon fibers; linen fibers; ramie fibers; jute fibers; sisal fibers; flax fibers; soybean fibers; corn fibers; hemp fibers; lyocel fibers; wool; lactide and/or glycolide polymers; lactide/glycolide copolymers; silicate fibers; polyimide fibers; feldspar fibers; zeolite fibers, zeolite-containing fibers, acetate fibers; and combinations thereof; the hemostatic textile capable of activating hemostatic systems in the body when applied to a wound. Additional cofactors such as thrombin and hemostatic agents such as RL platelets, RL blood cells; fibrin, fibrinogen, and combinations thereof may also be incorporated into the textile. The invention is also directed to methods of producing the textile, and methods of using the textile to stop bleeding.

An article of footwear includes an upper formed from a textile element having a fusible yarn and a non-fusible yarn. The fusible yarn comprises a sheath-core structure with a fusible portion peripherally surrounding a non-fusible core. In some configurations, the fusible yarn includes filaments with fusible and non-fusible portions having different melting temperatures. The fusible yarn may be located at a bonding surface of the textile element and enables thermal bonding to a bonded component such as a toe guard, heel counter, or indicia. The textile element may define bonding zones with targeted fusible yarn placement. The bonded component may be secured to the upper via heat and pressure. The sole structure is secured to the upper.

Aspects herein are directed to systems, methods, and articles for producing a patterned film and using the patterned film to form a pattern of discrete overlay film structures on a substrate material. A uniform thickness of a film material is deposited on to a first surface of a run of carrier sheets, where each carrier sheet includes one or more holes extending there through. A first carrier sheet is extracted from the run of carrier sheets, and a second surface of the carrier sheet is positioned on a substrate material. Heat and/or pressure is applied to the film material to cause the film material to transfer to the substrate material through the one or more holes in the carrier sheet forming a pattern of discrete overlay film structures on the substrate material. The carrier sheet along with remaining portions of the film material is removed from the substrate material.