The disclosure describes a smart bandage assembly. The bandage assembly includes a bandage member; a movement sensor, a pressure sensor, a methane sensor, or a humidity sensor; a microcontroller; a memory; and a radio transceiver for communication with a mobile communications device. The electronic components of the bandage assembly may be embedded within the bandage member. In some implementations, the radio transceiver harvests RF energy to power the memory within the bandage assembly so that sensor data stored in the memory can be accessed by a mobile communications device when other remaining electronic devices in the bandage assembly remain in a sleep state or power off mode.

Systems and methods are described for monitoring compression applied by a compression bandage to a body portion of an individual. A system embodiment includes, but is not limited to, a textile configured to conform to a body portion of an individual subject; one or more strain gauges integrated with the textile, the one or more strain gauges configured to generate one or more sense signals associated with a strain of the textile; circuitry operably coupled to the one or more strain gauges and configured to receive the one or more sense signals associated with the strain of the textile; and a reporter operably coupled to the circuitry and configured to generate one or more communication signals associated with the strain of the textile responsive to instruction by the circuitry when the strain of the textile is less than or greater than a threshold strain value.

Systems and methods are described for monitoring compression applied by a compression bandage to a body portion of an individual. A system embodiment includes, but is not limited to, a deformable substrate integrated with a textile configured to conform to a body portion; a sensor assembly coupled to the deformable substrate, the sensor assembly including one or more strain gauges configured to generate one or more sense signals associated with a strain of the textile; circuitry operably coupled to the sensor assembly and configured to receive the one or more sense signals associated with the strain of the textile; and a reporter operably coupled to the circuitry and configured to generate one or more communication signals responsive to instruction by the circuitry, the one or more communication signals associated with the strain of the textile.

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.

A portable data processing device for forming a wireless network includes a chamber configured within a housing; a microprocessor; a power supply; a sensor communicatively coupled to the microprocessor; and data storage media; and a wireless communication module. The microprocessor is configured to broadcast, by the wireless communication module, a device identification signal; listen for an external device identification signal; transmit device capability data; receive external device capability data. The microprocessor is further configured to receive an internal measurement from the sensor; transmit the internal measurement; receive an external measurement from the external device; analyze the internal measurement and the external measurement to determine an analysis result; and transmit the analysis result.

Augmented wound dressing systems may include traditional wound dressing components and one or more sensor devices such as accelerometers, humidity monitors, temperature monitors, electrocardiography leads, and/or oximetry sensors. Measurements from the sensor devices may be used to monitor one or more aspects of patient and/or wound health. In addition, or alternatively, one or more images of a wound that may be taken over time may be analyzed and/or compared with one another to determine one or more characteristics of the wound in order to, for example, assess wound health/healing and determine whether an intervention is necessary to assist with wound healing.

An orthosis, in particular an elastic venous compression orthosis, provided with a device for measuring the time during which the orthosis is worn.

A suboccipital compression pad may include a pad member configured to contact a suboccipital region of a patient. A suboccipital compression pad may include a pair of securing straps extending respectively from opposing ends of the pad member, the pair of securing straps having proximal ends diverging into upper rear straps and lower rear straps to form an open space between the upper rear straps and the lower rear straps such that portions of the upper rear straps are located above ears of the patient and portions of the lower rear straps are located below ears of the patient without covering ears of the patient, wherein one of the upper rear straps and the lower rear straps of the pair of securing straps is configured to be selectively attachable to different locations of a back side of the pad member.

A bleeding control device for mitigating bleeding includes an outer storage container housing, a compressed gas canister, wound blocking contents and a control element. The bleeding control device may be used to deliver variable contents to a wound at the site of injury to control the bleeding of a victim as temporary solution for mitigating the bleeding until more advanced medical care can be provided. A bleeding control device includes a canister housing, a compressed gas canister arranged within the canister housing, a tube connected to the canister housing, an inflatable balloon disposed on the tube, the inflatable balloon being fluidly connected to the compressed gas canister, and a control element configured to activate the compressed gas canister to inflate the inflatable balloon.

Medical device kits for use in placing, maintaining, altering, and/or removing medical devices in, on, and/or from the body of a patient are disclosed. Such medical device kits can include one or more wrap assemblies for use in the placement/maintenance procedure. In accordance with present embodiments, the one or more wrap assemblies of the medical device kit can include various features to assist the clinician performing the particular procedure. In one embodiment, a medical wrap assembly is disclosed, comprising a foldable wrap body that includes a front surface, wherein the front surface is configured to define a sterile field. A plurality of pockets is included on the front surface of the wrap body. The pockets are configured to contain therein a plurality of medical components. The medical components are arranged in the pockets in a predetermined order of use for the medical procedure.