The present disclosure generally relates to a garment component for use in a garment. The garment component comprises: a liquid impermeable base layer; a liquid impermeable peripheral layer disposed along a periphery of the liquid impermeable base layer; and a space defined by the liquid impermeable base and peripheral layers. When the garment comprising the garment component is worn on a user, the garment forms a sealing engagement between the liquid impermeable peripheral layer and the user's skin, such that the liquid impermeable base and peripheral layers prevent liquid flow into and out of the space and the space collects bodily fluids from the user.

An item of clothing comprising an internal layer, made of vapor-permeable material, which faces the body of the user, an external layer, which is opposite with respect to the internal layer, a hybrid portion, which belongs at least partially to the internal layer and is located in the region of the collar of the item of clothing, and an interspace between the internal layer and the external layer. The item of clothing has at least one open region in the hybrid portion, the hybrid portion being at least partially not in contact with the body of the user.

A garment includes a bandroll for a waistband of the garment, the bandroll having an absorption layer and a wicking layer. The wicking layer controls stretch properties of the absorption layer. The waistband comprises a second material and wherein a shrinkage of a material substrate of the bandroll substantially matches a shrinkage of the second material. The bandroll provides memory to the waistband. The garments may be pants, shorts, overalls, skirts, dresses, jumpers, and one-piece suits, and may be a uniform.

A wettable SMS material for personal protective equipment, such as a SMS fabric that has been treated to improve the wettability and absorbency properties of the SMS fabric is provided. A treated SMS fabric for personal protective equipment can retain its durability, breathability, and comfort, and may also provide the fabric with wettability and absorption properties. An article for personal protective equipment formed from a wettable SMS fabric is also provided.

Aspects herein are directed to garments that incorporate adaptive stand-off structures in the form of fluid-filled bladders that transition from a first shape to a second shape when exposed to moisture in the form of, for example, perspiration. When the fluid-filled bladders are in the first shape, the fluid-filled bladders are generally planar with a surface plane of a textile layer forming the garment so that the garment comes into contact or near contact with the wearer's body surface. When the fluid-filled bladders are in the second shape, they extend in a z-direction away from the surface plane of the textile layer forming the garment such that the textile layer is spaced apart from the wearer's body surface by the stand-off structures to reduce cling and facilitate the evaporation of perspiration.

A material system with a plurality of panels, process of making, and methods of use are presented herein. The material system provides a plurality of panels that can be reconfigured in various ways so that a clean surface is made available to a user with minimal effort. Generally speaking, a burp cloth with a plurality of panels and an attachment feature is presented such that when a liquid is dispelled during a burping session, the contaminated panel used can be easily removed such that a clean panel is readily available.

An athletic garment includes sensors at different locations of the garment. The sensors are electrically coupled to a processing unit and/or a power source via one or more conduits that are printed onto the garment. The conduits are designed for improved flexibility to accommodate stretching in the garment that occurs as a user wearing the garment performs an exercise and for improved durability to resist corrosion due to friction, sweat, or washing of the garment. In one embodiment, the conduits are designed for decreased stress concentrations at seams of the garment. In one embodiment, the conduits are designed to create a conductive pathway between different surfaces of the garment to electrically couple sensors on a first side (skin side) of the garment and a processing unit and/or a power source on a second side (outer side) of the garment.

Aspects herein are directed to garments that incorporate adaptive stand-off structures in the form of fluid-filled bladders that transition from a first shape to a second shape when exposed to moisture in the form of, for example, perspiration. When the fluid-filled bladders are in the first shape, the fluid-filled bladders are generally planar with a surface plane of a textile layer forming the garment so that the garment comes into contact or near contact with the wearer's body surface. When the fluid-filled bladders are in the second shape, they extend in a z-direction away from the surface plane of the textile layer forming the garment such that the textile layer is spaced apart from the wearer's body surface by the stand-off structures to reduce cling and facilitate the evaporation of perspiration.

A removable, attachable, and disposable sweatband strip that adheres directly to a body part so as to absorb sweat therefrom without having to wrap around or circumscribe that or other body parts.

A multilayer fabric for selectively blocking or transmitting particular wavelengths in the electromagnetic spectrum, such solar radiation, and far infrared (FIR) radiation. The multilayer fabric may include a microporous water vapor permeable layer that selectively filters particular wavelengths depending on the size of its pores. In some embodiments, the multilayer fabric may include a nanostructured layer that selectively filters particular wavelengths.