A super-absorbent dressing assembly for use with a reduced-pressure wound treatment system includes a breathable, fluid restricted dry layer for placement against a wound, a super-absorbent layer, and a non-breathable layer, and a drape extending over the non-breathable layer. A reduced-pressure interface is available to fluidly couple the super-absorbent layer to a reduced-pressure subsystem. The super-absorbent dressing assembly preferably supplies a compressive force when placed under reduced pressure. A reduced-pressure treatment system uses a super-absorbent bolster to treat wounds, e.g., linear wounds.

A wound dressing comprising: a water-absorbent fabric comprising at least about 10 wt. % of hydrogel-forming absorbent fibers based on the dry weight of the fabric; and an adhesion-resistant, water-permeable wound contacting surface textile layer that is substantially continuously bonded to at least one surface of said fabric. The surface textile layer may be formed by surface treatment of the fabric, or by bonding a suitable textile web to the surface of the fabric.

A modular transdermal drug delivery system is provided, the system including: an upper module in which an outer backing layer is laminated to a pressure-sensitive adhesive layer that is covered by a removable release liner prior to assembly; and a lower module with a porous drug reservoir layer laminated to a skin-contact adhesive that affixes the system to the skin during drug delivery, where the skin-contact adhesive is, in one embodiment, an adhesive layer that is substantially co-extensive with the porous drug reservoir layer and, prior to use, protected with a second removable release liner. Methods of manufacture and use are also provided, as is an assembled transdermal drug delivery system fabricated by affixing the pressure-sensitive adhesive layer of the upper module to the porous drug reservoir layer of the lower module.

A dynamic gas-flow wound dressing assembly and method for enhancing the effect of generated gas flow across a wound creates spacing between a medical dressing cover and the wound to enhance ventilation. The assembly provides a medical dressing cover that covers a wound. The medical dressing couples to a gas flow framing structure having a gas inlet and enclosed gas outlets. A high rate gas flow is introduced through gas flow framing structure. The gas discharges to cross the wound. A scaffolding partition member serves as a resilient spacer between the gas flow framing structure and wound, enhancing ventilation by forces on the skin and directing gas flow. The scaffolding includes intake ports and outlet ports in fluid communication with inlets and outlets of gas flow framing structure. The scaffolding carries generated gas flow from the gas flow framing structure to wound, covering a larger gas flow volume across wound.

This invention provides wound healing systems, which delivers oxygen to the wound bed and applies negative pressure thereto, where the source of oxygen and negative pressure are simultaneously applied to distal sites of the dressing. Methods of treating wounds and methods of treating or preventing anaerobic infection of wounds using such systems are described.

The present invention provides a device and method for preventing or curing pressure ulcers or chronic wounds. A multilayer dressing comprises a soft silicone jell layer of a suitable thickness which is placed in the multilayer dressing, above an absorbent layer. The matrix of the silicone jell layer is populated with a plurality of silicone beads of suitable size. The beads are connected to each other, and to the silicone jell layer. Breathing of wound and substantial supply of oxygen to the wound is duly insured for all layers of the multiple layer dressing. The beads play a pivotal role in promoting the effectiveness and performance of the multilayer dressing by acting as the plurality of effective cushions, as they absorb and uniformly redistribute a patient's body weight across the entire applied dressing area. The low adhering adhesive coating of about 5 mm in width is applied to the peripheral edges of all the layers. Unlike the multilayer dressing already available in the market, skipping the application of low adhering adhesive coatings on the entire top and bottom surfaces of the layers helps in promoting overall breathability and consequently, the efficiency of the multilayer dressing of the present invention.

A method of preparing a crosslinked, collagen-based wound care dressing is provided, comprising: (a) immersing a sample of fibrous and/or non-fibrous collagen in a buffered acidic, aqueous solution comprising an alcohol; (b) contacting the collagen in solution with a catalytic component comprising 1-ethyl-3-[3-dimethylaminopropyl]carbodiimide hydrochloride for a time at least sufficient to effect reaction between amino and carboxyl groups present on the collagen and to yield crosslinked collagen that is resistant to pronase degradation; and (c) drying the crosslinked collagen to yield a porous, crosslinked collagen article wherein the porous, crosslinked collagen article demonstrates a pore size of 10-500 microns. Also provided are bioactive collagen medical scaffolds for hernia repair prosthetics and surgical incision closure members, prepared using the method above.

A closing dressing bolster and assembly for use with a system for treating a linear wound on a patient includes a bolster body formed from a flexible closing bolster material having closing members that are operable to develop an inward closing force when the closing dressing bolster is placed under reduced pressure. In one aspect, when the closing dressing bolster is under reduced pressure, the system, dressing, or assembly develops an inward force realized at the linear wound and a compression force. A wicking-material holder and wicking material may be used as well. The member components may all be see-through to allow visual inspection of the wound without requiring removal of the dressing.

The present application provides a negative pressure wound dressing, including foam and a bio-cellulose film with a three-dimensional reticular structure formed on a surface of the foam, wherein a projected area of the bio-cellulose film on a bonding surface of the foam and the bio-cellulose film is greater than or equal to that of the foam. The presence of the bio-cellulose film between the foam and a wound avoids the foam from sticking to the wound and the growth of new tissue into the foam when performing a negative pressure wound therapy. Also, when replacing the foam, a secondary damage to the wound is reduced, so as to relieve pain that the patient suffers.

Dressings, systems, and methods are disclosed for treating tissue with reduced pressure. A dressing for distributing reduced pressure to a tissue site includes a plurality of liquid-impermeable layers that are stacked and a plurality of spacers disposed at least partially between adjacent liquid-impermeable layers. The plurality of liquid-impermeable layers are fenestrated at least in part. The plurality of spacers and plurality of liquid-impermeable layers form a plurality of flow paths for allowing fluid flow under reduced pressure. Adjacent layers of the plurality of liquid-impermeable layers are stacked without foam between at least a majority of coextensive surfaces. Other dressings, systems, and methods are disclosed.