A engineered textile construction includes a first textile having a first average pore size forming a textile cell growth matrix in which the first textile is a woven or a knit construction, the textile cell growth matrix is configured to have a surface area sufficient to promote cell expansion and the first average pore size is preselected to prevent filling of the pores during cell expansion.

A textile with an electrically conductive first side and an electrically conductive second side where the two sides are separated by an electrically insulating part of the textile and where the electrically conductivity is provided by a graphene coating on the respective sides and where a capacitance can be formed between the respective conductive sides.

A fluid-driven actuator 100 includes a bending actuator 200 including a first wall portion 201, a second wall portion 203 cooperating with the first wall portion 201 to define an undulating actuator profile. The bending actuator 200 also includes an inner fluid bladder 202 disposed between the first and second wall portions 201,203 and following the undulating actuator profile. The fluid-driven actuator 100 further includes a restraint member 300 arranged to cooperate with the bending actuator 200 to produce a plurality of motions in response to fluid supplied to the inner fluid bladder 202.

A fluid-driven actuator 100 is disclosed herein. In a specific embodiment, the fluid-driven actuator 100 comprises a bending actuator 200 including a first wall portion 201, a second wall portion 203 cooperating with the first wall portion 201 to define an undulating actuator profile. The bending actuator 200 also includes an inner fluid bladder 202 disposed between the first and second wall portions 201,203 and following the undulating actuator profile. The fluid-driven actuator 100 further comprises a restraint member 300 arranged to cooperate with the bending actuator 200 to produce a plurality of motions in response to fluid supplied to the inner fluid bladder 202. Methods of producing the fluid-driven actuator are also disclosed.

The present invention relates to clothing having a silicone pattern formed to correspond to the shape of the muscles of the human body and a method of manufacturing the same, in which a silicone resin is formed on a clothing fabric using a fine spray method so as to include anion ore powder in a silicone pattern, and a pore-forming agent for forming micropores and a photocatalyst material are further added into a liquid silicone resin so that the silicone pattern is expanded and contracted to correspond to the expansion and contraction forces of the fabric, and the anion emission efficiency of the silicone pattern can be further increased.

A method of producing a variable compression garment. The method includes: identifying, in a base textile having a first elongation and memory characteristic, a first region having a second elongation and memory characteristic; applying to the base textile, in the first region, a first layer of an elastomer; drying the first layer of the elastomer to adhere the first layer of the elastomer to the base textile; applying to the base textile, in the first region, at least a second layer of the elastomer; drying the second layer of the elastomer to adhere the second layer of the elastomer to the first layer on the base textile; and baking the first and second layers of the elastomer to cure the first and second layers of the elastomer.

To obtain a textile-shaped bioelectrode that is flexible, highly comfortable to wear, and unlikely to move out of position, there is provided a bioelectrode having a layered structure of a fiber base layer composed of non-conductive fibers and a conductive layer, wherein the conductive layer is a layer formed of a conductive material including carbon black, urethane resin, and a water-based thickener.

A slip-resistant material is disclosed. According to embodiments of the disclosure, the slip-resistant material can partially conform to the body's contours during physical activity to eliminate, or at least to reduce, slippage. The slip-resistant material can be a coated lightweight, synthetic hexagonal mesh. The slip-resistant material can also be a base wicking fabric with soft nodules formed on it. The slip-resistant material can also be a base wicking fabric with a top layer comprising nodules and pores. The slip-resistant material can also be a combination of a base wicking fabric with a polymer-based thread. The embodiments of the disclosure are safe to be worn directly against skin and are comfortable, breathable, and durable. The embodiments of the disclosure can be used as a liner between an article and the wearer's skin to hold the article in place during movement.

Described herein are wound dressings, methods for their production and components for use therein. Described herein are a knitted structure including a blend of gelling fibres and non-gelling fibres wherein the yarn includes at least 50% w/w gelling fibres, a three-dimensional textile material including gelling fibres, and a yarn including a blend of gelling and non-gelling fibres which may be used in their production, the knitted structure and three-dimensional textile material being suitable for use as wound dressings or as components of composite wound dressings. The wound dressings may be adapted for use in negative pressure wound therapy (NPWT). It has been found that the incorporation of gel-forming fibres provides a material which has a high absorbency, enabling good transfer of exudates away from a wound, which retains structural integrity, and which is non-adherent and easily removed from the wound.

Disclosed herein is a medical implant component comprising a composite biotextile, which biotextile comprises i) a polyolefin fibrous construct comprising at least one strand with titer of 2-250 dtex, tensile strength of at least 10 cN/dtex and comprising high molar mass polyolefin fibers and ii) a coating comprising a biocompatible and biostable polyurethane elastomer comprising a polysiloxane segment and/or having one or more hydrophobic endgroups, wherein the polyurethane coating is present on at least part of the surface of the biotextile and in an amount of 2.5-90 mass % based on composite biotextile. Such composite biotextile, like a partly coated woven fabric, shows an advantageous combination of good biocompatibility, especially hemocompatibility, high strength and pliability, and laser cuttability; allowing to make pieces of fabric having well-defined regular edges that have high suture retention strength. The invention also provides a method of making said composite biotextile. Further embodiments concern the use of such biotextile in or as medical implant component for an implantable medical device and the use of such medical implant component in making an implantable medical device; such as in orthopedic applications and cardiovascular implants. Other embodiments include such medical devices or implants comprising said medical implant component.