An inflatable mattress that has multiple chambers is disclosed that includes a first section with a first pressure valve, and a second section that has a plurality of collapsible airtight vertical cylindrical chambers displaced across the first section and which defines a top surface and each vertical chamber includes valves, controlled by a central controller that is programmable and controls the flow of air in and out of each chamber, thereby providing a method to alter the vertical dimension of each chamber and affect movement to a person on the top surface mattress.

A patient transfer device. According to one embodiment, there is provided a patient transfer device: a support part including a patient seating surface on which a patient is supported; a plurality of propeller parts, connected to the support part, for moving the support part; a power supply unit to be transported while being borne by the user, the power supply unit serving to supply power to the plurality of propeller parts; and a connection member connecting the power supply unit and the support part, wherein the support part is configured to move to follow the power supply unit.

An advanced manually propelled wheelchair (100) is described. The wheelchair (100) has a chassis (110). In certain examples this may be a single piece design. The wheelchair (100) may further have one or more of a load adjustment mechanism (150) and a power-assist mechanism. The load adjustment mechanism (150) is configured to adjust a position of a set of rear wheels (120) for the wheelchair (100) relative to a loading of the wheelchair (100). Load adjustment may be performed based on a sensed loading. The power-assist mechanism provides a powered torque to a set of front wheels (130) to help a user propel the wheelchair (100) or to stabilise the wheelchair (100) during use. The power-assist mechanism may be provided as a set of modular front wheel units.

A wireless, patient-worn, physiological sensor configured to, among other things, help manage a patient that is at risk of forming one or more pressure ulcers is disclosed. According to an embodiment, the sensor includes a base having a top surface and a bottom surface. The sensor also includes a substrate layer including conductive tracks and connection pads, a top side, and a bottom side, where the bottom side of the substrate layer is disposed above the top side of the base. Mounted on the substrate layer are a processor, a data storage device, a wireless transceiver, an accelerometer, and a battery. In use, the sensor senses a patient's motion and wirelessly transmits information indicative of the sensed motion to, for example, a patient monitor. The patient monitor receives, stores, and processes the transmitted information.

A patient control unit for controlling functions of a hospital bed includes a housing having a first side that includes a plurality of user inputs to control the functions of the hospital bed. The housing has a second side that includes a dock to secure a handheld phone in place on the housing. A hospital bed has a head-of-bed angle (HOBA) lockout selector that is used to signal a controller to prevent a head section of the bed from being moved below a threshold.

A patient support apparatus, such as a bed, cot, stretcher, etc., for supporting a patient includes an exit detection system with multiple user-selectable modes of operation that each have different sensitivity levels for triggering an exit alert. The exit detection system also includes one or more non-user selectable modes of operation that are automatically implemented in response to a triggering action. For example, a transition mode may be automatically implemented when the user attempts to switch from a first user-selectable mode to a different user selectable mode, or a motion mode may be automatically implemented when movement of one or more components of the patient support apparatus occurs. In the transition mode, the exit detection system may use a least restrictive sensitivity level. In the motion mode, the exit detection system may inhibit exit alerts and/or change the criteria for issuing the exit alert.

A patient support system comprises a patient support apparatus for patients. The patient support apparatus comprises a base and a patient support surface supported by the base. The patient support apparatus also comprises powered devices that perform one or more predetermined functions on the patient support apparatus. Multiple input devices are employed to control the powered devices. The input devices are designed to enable caregivers to cause operation of the powered devices, as needed, while freeing the caregivers to perform other tasks.

A patient support apparatus, such as a bed, cot, stretcher, or the like, includes an exit detection system and/or a monitoring system that monitors a set of conditions of the patient support apparatus. A user interface of the exit detection system includes a first navigation control for navigating to a control screen for the exit detection system and a second navigation control for navigating to a control screen for the monitoring system. Each navigation control also functions as an automatic arming control, thereby causing the respective exit detection system and monitoring system to be armed. In this manner, a single touch of a navigation control implements the dual function of automatically arming the corresponding system and taking the user to a control screen for the corresponding system. The automatically armed system is armed using one or more preset settings or one or more settings customized to a particular patient.

A patient support apparatus comprising a patient support deck operatively attached to a base with a deck section arranged for movement between first and second positions determined by a deck sensor. A first user interface comprises a screen configured to display visual content including a content portion having first and second content states. A second user interface comprises an access panel including a panel portion with a light module having first and second illumination states. A controller is configured to display the content portion in the first content state and to control the light module in the first illumination state when the deck sensor determines the deck section is in the first section position, and to display the content portion on the screen in the second content state and to control the light module in the second illumination state when the deck section is in the second position.

A head rest accessory is provided for coupling to a bed frame of a hospital bed. The head rest accessory includes a frame and a head rest mount coupled to the frame. A head rest is coupled to the head rest mount and includes a face rest shell. A first angle sensor measures a first tilt angle of the face rest shell. A second angle sensor measures a second tilt angle of the face rest shell.