A patient transfer device includes a chamber formed by an upper layer coupled to a lower layer, the chamber configured to be inflated and supported by a support surface in contact with the lower layer. The patient transfer device further includes a port configured for connection to an air flow device. In various embodiments, the patient transfer device includes a low-friction sheet coupled to a bottom surface of the lower layer, wherein the low-friction sheet is configured to slide against itself to facilitate sliding of the chamber relative to the support surface. In other embodiments, the patient transfer device includes at least one air-expelling region disposed within a bottom surface of the lower layer, wherein the region is configured to expel air from within the first chamber along the bottom surface of the lower layer to facilitate sliding of the first chamber relative to the support surface.

A medical pad includes a piece of substrate with a major surface and an electric circuit on the major surface, a sensor connected with the electric circuit for measuring the electrical resistance of the electric circuit, and a wireless data transceiver or a radio frequency identification (RFID) tag electrically connected with the sensor for receiving results of the measuring from the sensor for subsequent transmission. The system carries out real time self-calibration to adaptively monitor the condition of a medical pad even in the face of changing environment and changing material properties.

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.

A system for use with an inflatable device includes an air output and a nozzle at a distal end of the air output. The nozzle includes a lip extending radially from the nozzle and configured to retain the nozzle in a port of the inflatable device. The lip has a non-circular shape around the nozzle.

A patient support device includes an inflatable body having a top sheet, a bottom sheet, and a cavity formed by the top sheet and the bottom sheet, wherein the top sheet and the bottom sheet are coupled together along a peripheral edge. The device further includes a port formed at the peripheral edge to permit inflation of the cavity and configured for connection to an air output device for inflation of the cavity. The port includes an opening configured to receive a portion of the air output device and a strap configured to wrap around at least a portion of the opening to retain the portion of the air output device within the opening. The strap is configured to adjust the size of the opening to retain the portion of the air output device.

An incontinence detection pad for detecting incontinence events includes a moisture absorbent layer that has non-embossed areas and embossed areas. The non-embossed areas have a first density of fibers of the layer, and the embossed areas have a second density of fibers of the layer that is greater than the first density. The incontinence detection pad further includes a plurality of electrodes positioned beneath the moisture absorbent layer and a transmitter connected to the plurality of electrodes and configured to transmit a signal indicative of a status of the moisture absorbent layer.

A patient transfer device includes a chamber formed by an upper layer coupled to a lower layer, the chamber configured to be inflated and supported by a support surface in contact with the lower layer. The patient transfer device further includes a port configured for connection to an air flow device. In various embodiments, the patient transfer device includes a low-friction sheet coupled to a bottom surface of the lower layer, wherein the low-friction sheet is configured to slide against itself to facilitate sliding of the chamber relative to the support surface. In other embodiments, the patient transfer device includes at least one air-expelling region disposed within a bottom surface of the lower layer, wherein the region is configured to expel air from within the first chamber along the bottom surface of the lower layer to facilitate sliding of the first chamber relative to the support surface.

A patient transfer device includes a chamber formed by an upper layer coupled to a lower layer, the chamber configured to be inflated and supported by a support surface in contact with the lower layer. The patient transfer device further includes a port configured for connection to an air flow device. In various embodiments, the patient transfer device includes a low-friction sheet coupled to a bottom surface of the lower layer, wherein the low-friction sheet is configured to slide against itself to facilitate sliding of the chamber relative to the support surface. In other embodiments, the patient transfer device includes at least one air-expelling region disposed within a bottom surface of the lower layer, wherein the region is configured to expel air from within the first chamber along the bottom surface of the lower layer to facilitate sliding of the first chamber relative to the support surface.

Described herein are systems and apparatuses for enhanced comfort through contact pressure reduction. In particular, the systems and apparatuses disclosed herein prevent or otherwise mitigate pressure by actively orienting a patient over an anatomy-specific pressure-mitigating contact surface on which the patient rests. A pressure-mitigating contact portion of the contact surface includes a plurality of independently pressurized chambers configured in a specific geometric pattern that is designed to mitigate contact pressure between a support surface (e.g., bed or chair) and a specific anatomic region of a patient's body when the specific anatomic region of the patient's body is oriented over an epicenter of the geometric pattern. Additionally, a plurality of elevated side support portions and a wedge interconnected on the base material are configured to actively orient the specific anatomic region of the patient's body over the epicenter of the geometric pattern.