A mobile negative pressure wound therapy (NPWT) device is described having an inlet; a canister in fluid flow connection with the inlet; a pump having a pump casing with a pump inlet in fluid flow connection with the canister in the canister, and a pump outlet for output of air transported through the pump; an elastomeric jacket at least partly enclosing the pump, the elastomeric jacket being configured to define a flow channel having a first end arranged to receive air output by the pump outlet and a second end spaced apart from the first end for discharging the air output by the pump outlet following passage through the flow channel; a control unit for controlling operation of the mobile NPWT device; a battery arrangement for powering the mobile NPWT device; and a housing enclosing at least the pump, the elastomeric jacket, the control unit, and the battery arrangement.

The present disclosure generally relates to a mobile negative pressure wound therapy (NPWT) device comprising a negative pressure pump, where the NPWT device is adapted to ensure that an operation of the negative pressure pump is terminated if the NPWT device is operating outside of a predefined operational range. The present disclosure also relates to a corresponding method for operating such an NPWT device and a thereto related computer program product.

A layered dressing includes: a permeable wound contact layer for placing in contact with a wound; a breathable barrier layer; a biosensor sensing array configured to detect one or more markers in wound fluid; and a fluid collection layer disposed between the wound contact layer and breathable barrier layer and configured to deliver wound fluid by capillary action from a wound in contact with the wound contact layer to the biosensor sensing array.

An apparatus for treating a tissue site includes a dressing, an oxygen source, a valve, and a negative-pressure source. The dressing is configured to be sealed around the tissue site. The oxygen source is fluidly coupled to the dressing and configured to provide a low flow of oxygen. A first port of the valve is fluidly coupled to the dressing and the valve moves between a closed position preventing flow through the valve and an open position permitting flow through the valve. The negative-pressure source is fluidly coupled to a second port of the valve and provides negative pressure to the second port of the valve at a non-therapeutic level. The valve separates the negative-pressure source from the dressing and selectively opens when a positive pressure is applied on an upstream side of the valve.

This disclosure includes wound dressings and systems with high-flow therapeutic gas sources for topical wound therapy and related methods. Some dressings, which are configured to be coupled to tissue to facilitate delivery of therapeutic gas to the tissue, comprise a manifold that defines a plurality of gas passageways, the manifold configured to allow communication of therapeutic gas to the tissue; and a gas-occlusive layer configured to be disposed over the manifold and coupled to the tissue such that an interior volume containing the manifold is defined between the gas-occlusive layer and the tissue and the gas-occlusive layer limits escape of therapeutic gas from the interior volume; wherein the gas-occlusive layer includes: a first opening configured to allow communication of therapeutic gas into the interior volume; and one or more second openings configured to allow communication of therapeutic gas out of the interior volume.

A wearable treatment and analysis module is provided. The module is positioned on or near a body surface region of interest. The module provides remote access to sensor data, treatment administration, and/or other health care regimens via a network connection with a user device and/or management system.

A system includes an endoscope defining a proximal end, a distal end and an elongated shaft extending between the proximal end and the distal end of the endoscope. A fluid collecting sheath defines a proximal end and a distal end. The fluid collecting sheath is configured for insertion into a vaginal opening. The fluid collecting sheath includes fluid collecting apertures defined at the distal end of the fluid collecting sheath. A fluid line is in fluid communication with the fluid collecting apertures. A channel is formed in the fluid collecting sheath. The channel extends between the proximal end and the distal end of the fluid collecting sheath. The channel defines an opening therein. The channel of the fluid collecting sheath is configured to operably engage the elongated shaft of the endoscope by passing the elongated shaft of the endoscope through the opening of the channel.

In some embodiments, a wound dressing includes at least one motion sensor for sensing a motion related parameter associated with motion of the wound dressing; and at least one further sensor for sensing a healing related parameter associated with wound healing at a region of tissue of a wound or proximate a wound covered by the wound dressing.

Embodiments of negative pressure wound therapy systems and methods for operating the systems are disclosed. In one embodiment, a negative pressure wound therapy apparatus can include a wound dressing, a negative pressure source, and a controller. The negative pressure source can provide negative pressure via a fluid flow path to the wound dressing. The controller can monitor a rate of fluid removal from the wound, wirelessly communicate the rate of fluid removal to a remote device, and output an indication when the rate of fluid removal meets a threshold.

A dressing includes a drape, a metal coating provided on a skin-facing surface of the drape, a pressure-sensitive adhesive provided on a lower surface of the metal coating, and a gasket having a frame shape. The drape is a thin film. The gasket includes an inner edge defining an opening and an outer edge offset inwardly from an outer periphery of the drape. The gasket is in contact with the metal coating and leaves a margin of pressure-sensitive adhesive around the gasket.