The garments disclosed herein have integrated gripping technology to grip the body of the wearer over large interior surfaces. The distribution of gripping technology throughout the garment gives increased freedom of body movement and reduces bulkiness over conventional garments, while also allowing for free cut edges. Furthermore, the dispersion of the gripping technology over the majority of the garment eliminates the problem of polymer strips and beading digging into the skin. Slip garment embodiments are disclosed herein that include a lower region having an interior surface with exposed elastic threads configured to directly contact the wearer. The slip garment embodiments include a free-cut lower edge. The slip garment embodiments can be constructed using cut and sew methods.

Disclosed is a compression and/or contention garment for lymphoedema treatment, the garment including a main body made of a compression textile. The garment has at least a first targeted area, in which the garment includes at least one layer of reinforcement textile, and at least a second targeted area, in which the garment includes at least one layer of contention textile.

Fabrics comprising regenerated cellulose fibers and a nanoparticle dispersed throughout the fabric are disclosed herein. The regenerated cellulose fibers can be derived from a biomass such as a fibrous cellulose, wood pulp, cotton, paper, bast fiber, bagasse, or a combination thereof. The nanoparticle included in the fabric can be chosen to confer a desirable property, such as a thermal insulating property, to the fabric. Methods of making the fabrics comprising the regenerated cellulose fibers and nanoparticle are also provided. The method can include (a) at least partially dissolving a cellulose substrate in a medium comprising one or more ionic liquids; and dissolving or suspending a nanoparticle in the medium; (b) recovering a solid nanoparticle-modified regenerated cellulose material comprising the cellulose substrate and the nanoparticle; and (c) processing the solid nanoparticle-modified regenerated cellulose material to form the fabric.

A knit component may include a knit-in tensile area, which may include an opening at least partially bounded by a first intersecting portion and a second intersecting portion. A course of tensile material that is integrally knitted with the first intersecting portion via a knit stitch may include a float extending from the first intersecting portion, across the opening, to the second intersecting portion. A knitting method may knit courses of the knit component on needle beds and then widen and/or narrow parts of the opening by transferring stitches of one of the courses of the knit component to different needles.

An apparatus and method of manufacturing same is provided. The apparatus comprises a base layer integrated with an article; an electrode mounted adjacent to a conductive layer, both the electrode and conductive layer mounted on the base layer; an active electrode board in electrical communication with the conductive layer and the electrode, the active electrode board configured receive and/or send electrical signals from the electrode. The electrode comprises filaments or filament yarn knitted into a textile. The filaments or filament yarn comprise thermoplastic elastomers (TPE) blended with one or multiple conductive filler/s for improving impedance at the skin-electrode interface.

Advances in actuating fabrics could enable a paradigm shift in the field of smart wearables by dynamically fitting themselves to the unique topography of the human body. Active fabrics and fitting mechanisms are described herein that enable garments to conform around surface concavities without requiring high elasticity or a multiplicity of closure devices. Advanced materials and systems innovations (1) enable novel garment manufacturing and application strategies, (2) facilitate topographical fitting (spatial actuation) through garment architectural design, and (3) provide tunable NiTi-based SMA actuation temperatures to enable actuation on the surface of human skin. Such fabrics and garments are usable in a variety of fields including medical compression, technical sportswear, exosuits, space suits and components thereof, or non-garment applications.

The present invention relates to a shoe upper including a knitted component having a plurality of integrally knitted lines of loops including a set of consecutive lines, wherein each line in the set of consecutive lines includes a plurality of consecutive loops which are interlooped with adjacent loops of the respective line and not interlooped with loops of a line which is not contained in the set, and wherein the set of consecutive lines forms at least a portion of an eyelet which is configured to receive a lace.

In one aspect, the present disclosure provides a method. The method may include placing an upper on a last, where the upper includes a lower perimeter edge secured to a lasting element, and where the last includes an opening for receiving the lasting element. The method may further include feeding the lasting element at least partially through an opening of the last and tensioning the lasting element to tighten the upper around the last by pulling the tensioning element at least partially through the opening.

A knitted textile having a first layer including a first yarn with a thermoplastic composition integrally formed with a second layer including a second yarn, the first yarn forming an array of knitted patterns defining voids through the first layer to the second layer. The first layer may be heat treated to form a film. Treatment of the first layer may change zonal and directional tensile properties of the knitted textile. The Poisson's ratio of the knitted textile may be greater than or equal to zero in a first axis and/or a second axis, before and/or after treatment. Articles of apparel, including articles of footwear and garments incorporating the knitted textile, and methods of forming the knitted textiles and articles are disclosed.

A textile interconnection system for a textile substrate. The textile substrate may include at least one conductive fibre configured to transmit at least one of a power or data signal. The textile interconnection system includes a textile receptacle projecting from the textile substrate to define a cavity for receiving a controller device. The textile interconnection system includes a textile docking device received within the textile receptacle and coupled to the at least one conductive fibre of the textile substrate to electrically interconnect the received controller device and the textile substrate. The textile interconnection system includes a housing coupled to the textile docking device and received within the textile receptacle to mechanically interconnect the received controller device and the textile substrate.