A mattress, bed, cushion, or other device to support a user in a pre-determined posture. The mattress, bed, cushion, or other device includes compressible cells configured to inflate based on characteristics of particular contact areas of the user, and contact, in response to inflating based on the characteristics, the user in various contact areas to support the pre-determined posture. In particular, inflating the compressible cells based on characteristics of particular contact areas reduces the risk of the user developing pressure ulcers.

A body support for use with a bed having a top end, a bottom end and a mattress, including a back vertical wall removably mountable at the bottom end of the bed in a fixed position in which the wall extends across the bed and above the mattress, a front vertical wall extending parallel to the back wall above the mattress, and a scissor jack disposed between, secured to and connecting the front wall and the back wall so as to be capable of expanding and contracting horizontally to move the front wall away from and toward the back wall above the mattress in maintained parallel relation to the back wall, whereby the front wall serves as a foot support for an individual lying on the bed and is positionally adjustable in accordance with the individual's height. A pad may be removably mounted on the front wall.

A mattress for patient care. The mattress includes a number of compressible cells and a number of sensors corresponding to the number of compressible cells. Each compressible cell is configured to contact, when inflated, a user in a contact area of a plurality of contact areas of the user. Each sensor is configured to generate a number of measurements, wherein each measurement relates to the contact area of a corresponding compressible cell. Each sensor is further configured to send the number of measurements to a pressure control device.

A support apparatus for a person includes a main cushion having a bottom surface, a top surface to form a support surface for a person supported on the main cushion, and a length having a perimeter that has longitudinal and lateral sides extending around the perimeter. In addition, the support apparatus has at least one sleeve located along one of the sides of the man cushion. The sleeve is configured between a stowed state, where the sleeve is closely adjacent to the one side, and a deployed state, where the sleeve forms an extension of the top surface of the main cushion to thereby increase the width or the length of the support surface.

A system for use with a bed having a frame and a supporting surface includes a sheet having a bottom surface placed above the supporting surface of the bed, a top surface, and a plurality of tether straps connected to and extending from the sheet. Each tether strap is configured for connection to the bed. The bottom surface is at least partially formed of a low friction material, and the top surface is at least partially formed of a high friction material, such that the top surface provides greater slipping resistance than the bottom surface. The tether straps include at least two pairs of tether straps, with one pair connected proximate a top edge of the sheet and another pair connected proximate a bottom edge of the sheet. The sheet may further include a sliding member on the bottom surface to assist in lateral sliding of the sheet.

An infant care device includes a mattress and mattress tray configured to support a baby and an enclosure/barrier surrounding the mattress to create a chamber around the baby. A plurality of sensors, such as load cells, are distributed beneath the mattress and mattress tray. A control unit receives information from the load cells and is able to determine the position of the baby on the mattress. A safe zone and a potential fall zone are defined in the control unit. When the determined location of the baby is within the potential fall zone, the control unit operates a resistance mechanism to restrict movement of the baby toward a perimeter edge of the mattress and generates an alarm. Multiple embodiments of the resistance mechanism are disclosed to restrict the movement of the baby.

A sleep apparatus, such as a mattress, comprises a head support surface sized to support a person's head, and a torso support surface sized to support a person's torso. The head support surface is generally laterally sloped moving from a first side toward a second side of the mattress, and the torso support surface is generally laterally sloped moving from the first side toward the second side. In some embodiments, the lateral slope of the head support surface is at least about 15, the lateral slope of the head support surface is greater than the lateral slope of the torso support surface, and/or, the sleep apparatus slopes in the longitudinal direction as well.

Systems, methods and instrumentalities are disclosed for adaptive infant positioning to reliably maintain an infant of any size in any position. An infant positioning device may comprise, for example, one or more barrier restraints and infant restraints with or without accessory restraints. A barrier may form-fit an infant in any position (e.g. without gap fillers). A barrier restraint may resist barrier movement, e.g., by underlaying an infant and overlaying and tucking under a barrier. An infant restraint may resist infant movement, e.g., by overlaying an infant and tucking under a barrier. An accessory restraint may restrain accessories, e.g., for substrate adaptation, height adjustment, position-sculpting, comfort pads or devices and/or medical devices. Adaptive infant positioning may reliably maintain infants in proper developmental positions, reduce repositioning corrections, simplify positioning and repositioning procedures, reduce positioning errors, reduce handling and aural disruptions, reduce supplemental devices and procedures and/or reduce inventory space and costs.

A patient support includes a cover defining an interior region, an air permeable first layer located in the interior region, and a support layer located beneath the air permeable first layer. A pressure sensing layer is located underneath the support layer. At least one air supply is coupled to the support layer. A controller is coupled to the air supply and to the pressure sensing layer. The controller controls inflation and deflation of the support layer in response to a signal from the pressure sensing layer.

A sleep apparatus, such as a mattress for example, is provided in one embodiment. The apparatus comprises a head support surface sized to support a person's head, and a torso support surface sized to support a person's torso. The head support surface is generally laterally sloped moving from the first side toward the second side, and the torso support surface is generally laterally sloped moving from the first side toward the second side. In some embodiments, the lateral slope of the head support surface is at least about 15, the lateral slope of the head support surface is greater than the lateral slope of the torso support surface, and/or, the sleep apparatus slopes in the longitudinal direction as well.