A patient support apparatus, such as a bed, cot, stretcher, or the like, includes a frame, a support surface, an emitter, a detector, and a controller. The emitter and detector are coupled to the patient support apparatus at first and second locations, respectively. The emitter is adapted to emit electromagnetic waves in a direction aimed toward the detector. The detector is adapted to detect the electromagnetic waves emitted from the emitter. The controller is adapted to perform a spectral analysis of the detected electromagnetic waves to determine a parameter associated with the gas exhaled by a patient positioned on the patient support apparatus. The parameter may refer to a carbon dioxide level of gas exhaled by the patient, the patient's respiration rate, the patient's metabolic rate, or the like. The emitter, detector, and controller may alternatively be separate from, but attachable to, and in communication with, the patient support apparatus.

A patient support apparatus, such as a bed, cot, stretcher, or the like, includes a frame, a support surface, an emitter, a detector, and a controller. The emitter and detector are coupled to the patient support apparatus at first and second locations, respectively. The emitter is adapted to emit electromagnetic waves in a direction aimed toward the detector. The detector is adapted to detect the electromagnetic waves emitted from the emitter. The controller is adapted to perform a spectral analysis of the detected electromagnetic waves to determine a parameter associated with the gas exhaled by a patient positioned on the patient support apparatus. The parameter may refer to a carbon dioxide level of gas exhaled by the patient, the patient's respiration rate, the patient's metabolic rate, or the like. The emitter, detector, and controller may alternatively be separate from, but attachable to, and in communication with, the patient support apparatus.

A patient support system includes independently adjustable end columns supporting a centrally hinged, jointed or breaking patient support structure. At least one column includes a powered rotation assembly. The patient support includes at least two sections. A coordinated drive system provides for both upwardly and downwardly breaking or jointed orientations of the two sections in various inclined and tilted positions. Cable, cantilevered and pull-rod systems are included.

The present invention relates to a system and method for sacral and trochanteric support and off-loading. The system provides a ultra low pressure plenum and a positioner. The patient body size and size and corresponding surface area of the positioner control the amount of gas which is displaced evenly against the walls of the ultra low pressure plenum to allow the combination of the ultra low pressure plenum and the positioner to slightly lift a patient from a bed surface, thereby offloading the sacrum and trochanter. The positioner can be an ultra low pressure bladder.

Systems include a plurality of sensors coupled to a person support apparatus, at least one moisture sensor configured to sense a moisture level between the person and the support surface, and at least one computing device coupled to the plurality of sensors coupled to the person support apparatus and the at least one moisture sensor. The at least one computing device receives data from the plurality of sensors coupled to the person support apparatus and the at least one moisture sensor, obtains data from an electronic medical record associated with the person supported by the person support apparatus, calculates a pressure injury score indicative of a likelihood that the person will develop a pressure injury based on the data from the plurality of sensors, the at least one moisture sensor, and the electronic medical record, and alters a treatment plan for the person based on the calculated pressure injury score.

A caregiver assistance system is disclosed for helping caregivers manage the care of existing bed sores and/or reduce the risk of a patient developing bed sores. The system may also help the caregiver to perform rounding tasks and/or to reduce the likelihood of patient falls. The system comprises a server application in communication with the patient's bed and one or more mobile electronic devices (e.g. smart phones). The mobile devices receive individual assessments of a plurality of bed sore risk factors and forward them to the server. The server generates bed sore risk scores from the answers and forward them to an EMR server. The server may also determine one or more risk reduction steps, display them on the mobile electronic device, and/or forward them to the patients' beds for implementation thereon. Additional bed sore information may be captured and sent to the EMR.

A patient support apparatus includes a mattress for supporting a patient, and low-volume turning bladders coupled to the mattress, and a low-volume, high pressure air supply for inflating the turning bladders.

A device for use with a bed having a frame and a supporting surface includes a flexible sheet with a tether strap connected to the sheet and extending from the sheet. The flexible sheet has opposed top and bottom surfaces, with the top surface having a high friction material with a higher coefficient of friction as compared to the bottom surface, which includes a low friction material. The tether strap is configured for connection to the frame of the bed to secure the sheet in place. A system incorporating the flexible sheet may also include an absorbent pad configured to be placed on the top surface of the sheet, where the high-friction top surface resists sliding of the absorbent pad, as well as one or more wedges having a base wall that the wedge rests on and a ramp surface configured to confront the sheet when the wedge is placed under the sheet. The base wall and the ramp surface may also contain high friction and low friction materials, respectively.

An inflatable device includes a top sheet of material and a bottom sheet of material, wherein the top sheet of material is connected to the bottom sheet of material thereby defining a cavity therebetween to be inflated. The device further includes a plurality of passages in the bottom sheet extending from the cavity to an exterior of the device, wherein the passages are configured to permit air to pass from the cavity to the exterior of the device and to flow between a bottom surface of the device and a supporting surface upon which the device is configured to rest. The inflatable device further includes a plurality of inflation-limiting members connecting the top sheet to the bottom sheet, and an input configured for receiving air to inflate the device.

A power supply system for a facility includes a patient support apparatus with a controller and a patient support. A power source is operably coupled to the patient support apparatus. The controller is in communication with the power source. A transmitting assembly is coupled to the patient support apparatus and the power source. A receiving assembly is operably coupled to the patient support. The transmitting assembly wirelessly communicates with the receiving assembly to power the patient support. A locating feature is in communication with the controller of the patient support apparatus. The locating feature is configured to aid in aligning the power source on the patient support apparatus to indicate when the receiving assembly is in communication with the transmitting assembly.