A wound dressing assembly includes a wound cover and a carrier. The wound cover has a length and width substantially greater than a height (or thickness), a first major surface, and a second major surface, opposite the first. The first major surface has disposed thereon a wound cover pressure sensitive adhesive comprising a colloidal absorbent, and it is arranged and configured to adhere to mammalian skin during use. The carrier has a length and width substantially greater than a height (or thickness), a first major surface, and a second major surface, opposite the first. The first major surface of the carrier is disposed in facing relation and is removably attached to the second major surface of the wound cover, and it has disposed thereon at least one pressure sensitive adhesive. After application of the wound cover to skin for use, the carrier is removable from the wound cover to leave the wound cover adhered to the skin.

Embodiments disclosed herein are directed to the treatment of wounds using negative pressure. Some embodiments disclosed herein provide for a hydrophilic drainage layer, which may be suitable for use in abdominal wound sites, and which may be sized in a dimensionally-independent manner. Additional embodiments provide for an organ protection layer, as well as a system for the treatment of abdominal wounds.

Hydrocolloid composition and bio-patch comprising the same are provided. The hydrocolloid composition has a hydrophobic elastomer matrix. Hydrocolloid particles and aerogel particles are dispersed in the matrix. The aerogel particles may be silica aerogel particles. The aerogel particles may include particles having hydrophobic functional groups formed on the particle surface. The aerogel particles may be hydrophobic aerogel particles, hybrid aerogel particles in which hydrophobic functional groups and hydrophilic functional groups are simultaneously formed on the particle surface, or a mixture of the hydrophobic aerogel particles, the hybrid aerogel particles, and hydrophilic aerogel particles.

Dressings for tissue treatment with negative pressure and methods of assembling the dressings for tissue treatment with negative pressure are disclosed. A method of assembling a dressing, which may comprise at least three layers assembled in a stacked relationship, may comprise providing an assembly station having at least one retaining pin, placing a first layer on the assembly station, placing a second layer on the assembly station, and bonding the second layer to the first layer. The first layer may comprise a plurality of apertures, at least some of which may be engaged by the retaining pins, and the second layer may comprise fluid restrictions and alignment areas for engaging with the retaining pins so that the fluid restrictions may be aligned with the apertures of the third layer.

A dressing for use with percutaneous tubes/drains/pins and tracheostomies that is designed to be impermeable to aid in the prevention of leakage of body secretions or fluids and to help prevent microbes from entering the body around the percutaneous device from the outside of the dressing. The dressing includes three layers or more including a layer having antimicrobial, bacteriocidal, or hemostatic agents, a cushioned absorbent layer covered by an outer see through impermeable adhesive layer.

The present invention relates to an adhesive patch. The adhesive patch includes a plurality of reliefs, each relief having a flat top face, and each micro channel groove defined between adjacent reliefs of the plurality of reliefs, wherein the plurality of reliefs and the micro channel groove are respectively formed on and defined the adhesive patch, and wherein a hydrogel layer is disposed on at least a portion of a bottom face of the micro channel groove and is contained in the groove. Therefore, the adhesive patch is well-adhered to a dry or wet adhered face.

Silicone gels are described that are adhesive to the skin. The gels are able to be used in particular for articles that are adhesive to the skin for medical or paramedical use.

An apparatus for cleansing wounds, in which wound exudate is removed from a wound bed and selectively cleansed and returned to the wound. The cleansing means removes materials deleterious to wound healing, and the cleansed fluid, still containing materials that are beneficial in promoting wound healing, is returned to the wound bed. The associated wound dressing and cleansing means are conformable to the wound, and may have irrigant fluid circulated from a reservoir by a device for moving fluid through a flow path which passes through the dressing and a means for fluid cleansing and back to the dressing.

Wound treatment materials can have at least two perforated biomatrix layers which are interconnected. Methods for preparing such wound treatment materials include the application of adhesives. Treatment of exuding wounds, and vacuum-assisted wound treatment therapy, can be carried out with the wound treatment materials.

A wound therapy device is disclosed. The wound therapy device may include a housing for covering at least a portion of a wound and for sealing to a body surface of a patient. The housing may also include a liquid collector for retaining liquid therein and a vacuum connection for coupling to a vacuum source. The vacuum connection may be in gaseous communication with the liquid collector. The vacuum connection may be separated from the liquid collector by a liquid barrier.