Sleep tracking systems and techniques for monitoring two or more co-sleepers in a single bed are disclosed. Such systems and techniques may incorporate sleeper identification, as well as various non-user-specific aspects. Some implementations may incorporate user-specific or user-tailored alarm functionality.

A hospital bed is configured to monitor data from a second patient support based on the one or more alarms set by the user. The hospital bed detects whether an alarm triggering event occurred based on the monitored data. In response to a determination that the alarm triggering event occurred, the hospital bed will provide a signal indicative of the alarm triggering event to a nurse call system.

A location detection system identifies the locations of medical devices such as patient support apparatuses and/or patient care devices within a medical facility. The devices communicate via a wired connection to one or more medical facility systems (e.g. nurse call system, computer network, etc.), and/or via a wireless connection to such systems. The location detection system automatically determines location information of the devices and communicates the location information so that the recipient of any outgoing alerts and/or other information sent from the devices is apprised of the location of the particular device sending the alert or other information. Caregivers are thereby able to respond to the correct location of an alert, and software systems such as EMR systems, admission discharge and transfer (ADT) systems, etc. are able to correlate transmitted device data with the location and/or patient assigned to that location.

The present system generates output signals conveying information related to a position of one or more body parts of the subject, location of the body of the subject and/or physiological information related to the subject; obtains a set of fall criteria that describe whether the subject is likely to fall; determines one or more body position parameters, one or more physiological parameters, and/or one or more body location parameters; compares the determined one or more physiological parameters, the one or more body position parameters, and/or the one or more body location parameters to criteria in the set of fall criteria; and, responsive to the one or more body position parameters, the one or more physiological parameters, and or the one or more body location parameters satisfying individual fall criteria in the set of fall criteria, generate an alert.

A wearable, body position monitor and activity alert device, designed to protect patients with a compromised ability to stand or walk from their own impulses to stand up by delivering a personal audible message of “caution”, “persuasion”, “discouragement” and/or “direction” when detecting the initiation of a “signature body movement” that could lead to a dangerous fall. The objective is to prevent falls from happening by monitoring a person's movements using a 3D accelerometer sensor and/or a 3D gyroscope sensor. No caregiver assistance belts, tethers, or other restraints are needed. When the patient starts to stand up, the patient monitoring system simultaneously and wirelessly alerts a caregiver, who is wearing a Caregiver's Personal Alert Device (CPAD), of the patient's intent to stand. When alerted by the CPAD, the caregiver then intervenes before the patient falls.

A system for monitoring medical conditions including pressure ulcers, pressure-induced ischemia and related medical conditions comprises at least one sensor adapted to detect one or more patient characteristic including at least position, orientation, temperature, acceleration, moisture, resistance, stress, heart rate, respiration rate, and blood oxygenation, a host for processing the data received from the sensors together with historical patient data to develop an assessment of patient condition and suggested course of treatment, including either suspending or adjusting turn schedule based on various types of patient movement. Compliance with Head-of-Bed protocols can also be performed based on actual patient position instead of being inferred from bed elevation angle. The sensor can include bi-axial or tri-axial accelerometers, as well as resistive, inductive, capacitive, magnetic and other sensing devices, depending on whether the sensor is located on the patient or the support surface, and for what purpose.

One embodiment of a monitoring system includes a sensing subsystem adapted to sense an external parameter within a region of interest relative to an occupant support or an occupant of the occupant support. The monitoring system also includes a processor. The processor is adapted to adapted to receive data representing the sensed external parameter and to execute machine readable instructions thereby causing the monitoring system to evaluate, based on the received data, a likelihood that the occupant will attempt an egress from the occupant support. The processor is also adapted to generate a notification of the likelihood of attempted egress.

A patient support apparatus comprises a plurality of load cells, a frame supported on the load cells, a mattress, a plurality of air pressure sensors, and a control system. The mattress includes a plurality of inflatable zones positioned on the frame, the mattress and frame cooperating to direct any patient load through the mattress and frame to the load cells. Each of the plurality of air pressure sensors measures the pressure in a respective inflatable zone of the mattress. The control system includes a controller operable to receive a separate signal from each of the plurality of load cells and each of the plurality of air pressure sensors and process the signals to identify movement data and communicate the movement data to a caregiver.

A CPAP compliance notification apparatus for use with a CPAP device having a flow generator, a CPAP hose, and a CPAP mask, the CPAP compliance notification apparatus, including a patient occupancy mat, an air pressure sensor, an air pressure tube, a compliance notification controller unit, a housing, a user interface, a programmable logic controller together with a patient to control parameters of the CPAP compliance notification apparatus in implementing a compliant CPAP treatment to the patient.

A person support apparatus supports a person in a laying-down or a seated position. One or more body-mounted sensors detect changes in the position of the person relative to a reference. A control system receives output from the body-mounted sensor or sensors through a remote coupling. The control system uses patient position information obtained from the body-mounted sensors to determine whether the person has experienced a change-in-position and/or a change-in-activity event. Alternatively or in addition, the position of the person situated on a person support apparatus is detected using one or more sensors that are not body-mounted, but rather are coupled to the person support apparatus or to another component of a patient support system. The patient position information is used to estimate the patient's torso angle. The estimated torso angle is used to assess the patient's condition.