Composite wound dressings including an activated carbon material, a barrier material layer, a liquid-absorbing material layer and an outer liquid-impermeable layer are disclosed herein. The composite wound dressings include a bond substantially bonding a portion of the liquid-impermeable outer layer and the barrier material layer to the activated carbon containing layer, the bond forming a sealed pouch of un-bonded layer of the composite and encapsulating the liquid-absorbing layer. Methods for manufacturing and using such composite wound dressings to effectuate healing of wounds on humans or other animals are described herein.

Systems, methods, and apparatuses for forming a multi-function core for a dressing are described. The multi-function core includes a contact layer configured to be positioned adjacent to a tissue site, a wicking layer adjacent to the contact layer, an ion exchange layer adjacent to the wicking layer, an absorbing layer adjacent to the ion exchange layer, a blocking layer adjacent to the absorbing layer, and an odor-absorbing layer adjacent to the blocking layer. The contact layer, the wicking layer, the ion exchange layer, the absorbing layer, the blocking layer, and the odor-absorbing layer are coextensive and formed from a plurality of fibers disposed in a fibrous web. Methods of manufacturing the multi-function core are also described.

The present invention relates to a wound packing material, suitable for use in negative pressure wound therapy, comprising a body of a porous material, the body comprising frangible regions defining a plurality of portions, the frangible regions allowing the portions to be selectively removed from the body. The invention further relates to methods of manufacturing the wound packing material, and to methods of its use.

Some embodiments of a manifold pad may be configured to distribute reduced pressure relative to a tissue site and to provide instillation to the tissue site. In some embodiments, the manifold pad may comprise open-cell foam and at least one skinned channel extending through the open-cell foam. The at least one skinned channel may be configured so that the skin is substantially impermeable to liquid, preventing liquid within the channel from seeping into the open-cell foam. In some embodiments, this may allow for two isolated pathways for fluid movement through the manifold pad. Some dressing embodiments may utilize such a manifold pad in conjunction with a treatment device. Other apparatus, dressings, systems, and methods are disclosed.

A wound dressing is made from a tubular inner layer and at least one outer layer disposed radially beyond the inner layer. The inner layer permits egress of fluid from weeping wounds, prevents desiccation of skin disposed beneath the inner layer, and prevents desiccation of ointment disposed between the inner layer and the skin. The at least one outer layer absorbs fluids that leak through the inner layer, protects the inner layer from outside contaminants, and prevents fluids from escaping. The at least one outer layer is affixed to the inner layer, and each of the layers is elastic in at least the radial direction. Optionally, a layer of ointment may be applied to an inner surface of the inner layer. Note that the tubular inner layer may be either pre-formed or formed at the time of application.

A wound-closing dressing, which is suitable for use as part of a reduced-pressure, wound-treatment system, may include a sealing drape, one or more contracting elements, and a gripping member. The contracting element may be coupled to the sealing drape and is configured to contract when activated and to generate a closing force. A gripping member is coupled to the sealing drape and is configured to transmit the closing force to a patient's epidermis. Other dressings, systems, and methods are also disclosed.

A wound dressing includes an absorbent core including a top surface and a bottom surface containing a superabsorbent substance, a facing layer including folded sections folded towards the top surface of the absorbent core, the facing layer entirely covering the bottom surface of the absorbent core, a backing layer, and a contact layer including folded sections covering parts of the folded sections of the facing layer, the contact layer folded to cover an entire area of the facing layer covering the bottom surface of the absorbent core and the contact layer is configured to be brought into contact with a wound. The facing layer and the backing layer form a pouch in which the absorbent core is located. The folded sections of the facing layer and the backing layer are joined together. The folded sections of the contact layer and the facing layer or the backing layer are joined together.

An open-cavity, reduced-pressure treatment device and system for treating a cavity in a patient's body, such as an abdominal cavity, is presented. In one instance, an open-cavity, reduced-pressure treatment device includes a plurality of encapsulated leg members, each having an interior portion with a leg manifold member and formed with fenestrations operable to allow fluid flow into the interior portion, and a central connection member fluidly coupled to the plurality of encapsulated leg members. The central connection member has a connection manifold member. The open-cavity, reduced-pressure treatment devices, systems, and methods allow for, among other things, removal of fluids.

A hemostatic textile comprising glass fibers circular knit with bamboo-sourced rayon fibers in a tubular fashion. The knitted textile is scoured and dried to shrink the bamboo-sourced rayon relative to the glass fibers and to orient the glass fibers exteriorly of the bamboo-sourced rayon fibers such that when the hemostatic textile is administered to a wound, the glass fibers are the first to come in contact with any wound fluid, for example blood. This orientation aids in the activation of the hemostatic response which leads to faster clot times and improved overall wound-healing. A method of manufacturing and utilizing the hemostatic textile is also provided.

A wound-closing dressing, which is suitable for use as part of a reduced-pressure, wound-treatment system, may include a sealing drape, one or more contracting elements, and a gripping member. The contracting element may be coupled to the sealing drape and is configured to contract when activated and to generate a closing force. A gripping member is coupled to the sealing drape and is configured to transmit the closing force to a patient's epidermis. Other dressings, systems, and methods are also disclosed.