An incontinence detection pad has an RFID tag in which an authentication code, such as an electronic product code (EPC), is stored. A reader in wireless communication with the RFID tag of the incontinence detection pad verifies that the incontinence detection pad is an authorized detection pad. Thus, unauthorized incontinence detection pads that do not have the proper authentication code are not able to be used in an incontinence detection system.

An incontinence detection system includes an incontinence detection pad underneath a patient's pelvic area for detecting an incontinence event. The incontinence detection system further includes a moisture detection sensor, a gas detection sensor, and a reader. The moisture detection sensor is embedded in the incontinence detection pad for detecting a presence of moisture in incontinence detection pad. The gas detection sensor is positioned near the incontinence detection pad for detecting a presence of targeted gas, such as methane. The reader is communicatively coupled to the moisture detection sensor and the gas detection sensor to receive moisture data and gas data, respectively. The reader is configured to determine a type of the incontinence event based on the received moisture data and the gas data and transmit a signal indicative of the type of incontinence event to a server.

The present invention protects a system for monitoring the vital signs of a user of a disposable absorbent article that comprises a sensor device, a bi-dimensional code and a receiver, such that the sensor device is placed in contact with the user and the system is triggered by the reading of the bi-dimensional code through the receiver, such that the bi-dimensional code is place inside the packaging or the disposable absorbent article.

A wound dressing is disclosed. A wound dressing comprises a first adhesive layer, an electrode assembly, a monitor interface and a multiplexer. The first adhesive layer comprises a proximal surface configured for attachment of the wound dressing to a skin surface of a user. The electrode assembly comprises a plurality of electrodes including a first set of first electrodes. The monitor interface is configured to form a mechanical and electrical connection with a monitor device. The monitor interface comprises a coupling part and a plurality of terminals including a first terminal. The multiplexer comprises a number of N input pins and a number of M output pins. The N input pins include a first set of first input pins for connection to first electrodes of the first set of first electrodes, the first set of first pins including a first primary input pin and a first secondary input pin, and the M output pins include a first output pin. The first primary input pin is connected to a first primary electrode of the first set of first electrodes and the first secondary input pin is connected to a first secondary electrode of the first set of first electrodes, and the first output pin is connected to the first terminal of the monitor interface. The multiplexer is configured to connect the first primary input pin to the first output pin in a first multiplexer configuration and to connect the first secondary input pin to the first output pin in a second multiplexer configuration.

An article having a conductive body, a magnetic diverter, and a communication device is described. The magnetic diverter is positioned on an outer surface of the conductive body. The magnetic diverter covers a substantial portion of the outer surface of the conductive body. A communication device is positioned on the outer surface of the diverter or may be recessed therein. The communication device is capable of signal coupling with a reader.

Provided is a healthcare system including a smart defecation detection device. The healthcare system according to an embodiment of the present invention includes: a smart defecation detection device that is detachable to a wearable object of a protected person and detects defecation of the protected person, wherein the smart defecation detection device is provided as one of a plurality of smart defecation detection devices; a relay device that receives detection information in real time from the plurality of smart defecation detection devices; a control server that receives the detection information of the plurality of smart defecation detection devices in real time from the relay device, and comprehensively manages whether a defecation event has occurred and whether processing of the defecation event has been completed for each protected person, based on the detection information; and a reception device configured to receive notification information so that an assigned manager or ward/management station in charge of the protected person in whom the defecation event has occurred is allowed to be aware of the defecation event when it is determined that the defecation event has occurred based on the detection information of the smart defecation detection device.

Disclosed embodiments relate to apparatuses and methods for wound treatment. In some embodiments, a wound dressing apparatus can comprise a wound contact layer, a first area and a second area over the wound contact layer, and a cover layer configured to cover the wound contact layer, the first area, and the second area. The first area can comprise a spacer layer and an absorbent layer over the spacer layer. The second area can comprise an electronics cassette or cradle comprising a negative pressure source and/or electronic components.

A pressure sensing clip (1) and a system including a bandage (19) for detecting and displaying the pressure applied by a (compression) bandage (19) to a human or animal body in which the pressure sensing clip (1) has an inner bandage penetrating arm (2) and an outer arm (3) hingedly attached to the inner arm (2) at a hinge (4) so that the outer arm (3) is movable between a hingedly closed position with respect to the inner arm (2) and a hingedly open position. The device can be operatively attached to an applied compression bandage, or it can be placed beneath or between the bandage during bandage application so that the bandage covers the sensing part of the device. In the latter application, the ability of the arms of the device to adapt an open configuration allows the bandage to be applied over the inner arm leaving the outer arm to close once the bandage has been applied. The device can receive, store and transmit data to a user.

The present disclosure relates to an intelligent internet of things (IoT) monitoring system, and in particular to techniques (e.g., systems, methods, computer program products storing code or instructions executable by one or more processors) for the implementation of an IoT solution to manage urinary incontinence. Some aspects are directed to the concept of a management platform that allows for end users such as health care providers, caretakers, or medical personnel to manage and monitor one or more subjects through one or more client devices using a network of sensors and IoT devices. Other aspects are directed the concept of a data analysis system configured to train and deploy one or more prediction models for analysis and tracking metrics of health or wellbeing for the one or more subjects.