A wound dressing for use with a closure device is disclosed. The first and second base panels of the closure device are positioned on opposite lateral sides of a wound or incision. The base panels are coupled together to maintain wound or incision closure. A release liner is removed from a bottom surface of the wound dressing. The wound dressing is positioned over the closure device and the wound or incision. Exudate is absorbed by an absorbent material of the wound dressing through a porous strip of the wound dressing. The wound dressing is slightly larger than the closure device so that its perimeter area is adhered to the skin area around the closure device. Alternatively or in combination, the wound dressing is lightly adhered to the closure device and wound or incision area so that it can be removed without harming the underlying device and tissues.

A therapy system in which one or more eye patches are used to apply thermal energy to meibomian glands of an eye of a user to improve the release of meibum. The system comprises includes a headband which is worn by a user and in which a control unit is provided. At least one eye patch is provided which is connectable to the control unit. Each eye patch includes an outer area, an inner area with a flexible heating element located in the inner area. Electrical connections are used to connect the flexible heating element to the control unit to provide at least heat therapy to at least the meibomian gland in the eyelids. A charging unit is provided for recharging a rechargeable battery in the control unit.

A method is provided which includes providing a sensor operable to measure movement over time on a user. The sensor includes an alert unit. The sensor is configured with a threshold to activate the alert unit when the measured movement over time is below the threshold. The measurements of movement over time are obtained, and it is determined whether the measured movement over time is below the threshold. When the measured movement is below the threshold, the alert unit at the sensor is activated to alert the user.

A wound debridement system includes a wound dressing having an active layer (40) and a wound interface layer (10). The active layer is formed from one or more pneumatic members (45). The pneumatic members are arranged about a film layer (60), by which the pneumatic members are attached to the wound interface layer. A control unit (80) controls a drive unit (70) to intermittently apply pressure to the pneumatic members of the active layer. The pressure applied by the drive unit causes the pneumatic members to expand and contract. This movement of the pneumatic members is transferred to the wound interface layer, causing the wound interface layer to move relative to a tissue site to which the wound dressing is applied. The wound interface layer may be formed having an abrasive wound-facing surface, such that the movement of the wound interface layer causes a mechanical disruption and debridement of debris at the tissue site.

Systems, instruments or devices, and methods or procedures are described in which a scalpet array is applied to a target site with the use of a pattern. The scalpet array comprises scalpets positioned on a device. Skin pixels are incised at the target site via application of a load through the scalpet array. A recipient site is prepared by positioning the pattern at the recipient site and applying the scalpet array to generate skin defects. The incised skin pixels are applied at the skin defects of the recipient site.

In-vivo fluid monitoring devices and methods are disclosed herein. An example device is configured for patients which monitors increases and decreases of fluid retention in patients with various clinical conditions such as heart and renal failure pre-operation and post operation thus allowing physicians to more accurately detect said fluid retention gains through a mechanism directly or indirectly connected to circulatory stocking which act as a conduit to detect said fluid changes through skin electrolysis and alterations respective to fluid changes directly corresponding with galvanic skin response measurement changes.

A method and system for pairing a band-aid type of bandage with a wet wipe pouch adhered to the exterior, non-wound facing side of said bandage.

A method of detecting detachment of an ostomy device from a patient includes providing, in the ostomy device, a first electrode separated from the patient by an adhesive that attaches the ostomy device to the patient, where a first capacitor is formed between the first electrode and the patient. The method includes applying a signal to an electrical circuit that includes the first capacitor, and detecting changes in a capacitance value of the first capacitor based on frequency responses of the electrical circuit to the signal. The method additionally includes activating an alarm based upon detecting the changes in the capacitance value of the first capacitor.

Embodiments herein provide hemostatic compositions comprising a plurality of liquid-expandable articles arranged on a backing material. In general, embodiments include methods for treating hemorrhagic injuries. More specifically, there is provided a method to effect rapid hemostatic response and control hemorrhage by introducing a hemostatic composition into a bleeding wound cavity. An embodiment also provides a method of preparing or manufacturing such a hemostatic composition.

A monitor device (4) for a wound dressing system the device comprising a processor; a memory; a first interface connected to the processor and the memory, configured for collecting wound data from a wound dressing (2), the wound data comprising wound data from different sensor points of the wound dressing; and a second interface. The processor configured to: obtain parameter data based on the wound data; and determine an operating state of the wound dressing based on the parameter data, wherein the operating state is indicative of a degree of wetting of the wound dressing. The monitor device is configured to, in accordance with a determination that the operating state is a first operating state, transmit a first monitor signal comprising monitor data indicative of the first operating state via the second interface and, in accordance with a determination that the operating state is a second operating state, transmit a second monitor signal comprising monitor data indicative of the second operating state via the second interface.