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 therapy seat cushion, method of making the cushion and method of using the cushion. The cushion has a planar array of at least two sets of alternatively inflatable and deflatable cells controlled by an inflation control system, and at least one non-inflatable offloading cushioning cell interspersed amongst the inflatable cells. The non-inflatable offloading cushioning cell configured and arranged to align with a pressure sore or an area prone to development of a pressure sore on an individual.

A foam-air mattress includes a mattress housing including a top layer and a bottom layer; a plurality of pocket walls, disposed between the top layer and the bottom layer, air bladder inserts that can be inserted into the plurality of pocket walls, wherein the air bladder inserts are configured to be connected to a pumping system via a tubing assembly; and a plurality of foam compartments formed by the mattress housing and the plurality of pocket walls, configured to accept foam inserts. The air bladder inserts when inserted into the plurality of pocket walls and inflated by the pumping system, configure the plurality of pocket walls to expand and compress foam inserts disposed within the plurality of foam compartments so as to increase the density of the foam inserts. This arrangement has applications in both the consumer and medical airbed contexts, as well as in other support system contexts, such as seat cushions for chairs.

A mattress assembly includes: multiple gas-filled chambers each having a top surface, the top surfaces of the chambers collectively composing a top surface of the mattress assembly; multiple composite sensors each associated with a corresponding chamber. Each composite sensor includes a pressure sensor to measure a pressure at a wall of the corresponding chamber and a temperature sensor to measure a temperature of the corresponding chamber. The assembly includes chamber regulators each in communication with a corresponding chamber, each regulator configured to pump gas at a first, higher temperature and gas at a second temperature to the corresponding chamber. The assembly includes a controller in communication with the composite sensors and chamber regulators, programmed to: receive, from composite sensor(s), state data including pressure and temperature information for the chamber corresponding to the composite sensor; determine, based upon the received state data, information about a patient's position relative to the corresponding chamber; and based on the patient's position, control the chamber regulator for the chamber to modify a pressure and/or a temperature of the chamber.

A pump apparatus includes a pump configured for moving air, a housing supporting the pump, and an air output hose in communication with the pump. The housing further includes a rest for retaining a portion of the air output hose. The rest forms a u-shape having two side walls and a valley therebetween.

A mattress has a first support portion configure to receive and support a first user and a second support portion configured to receive and support a second user. The first support portion and the second support portion are adjacent to each other such that the first user is capable of rolling over from the first support portion to the second support portion while sleeping on the first support portion. A sensor is configured to sense first pressure in the first support portion and sense second pressure in the second support portion. The sensor is further configured to transmit data of the first pressure and the second pressure. The controller is configured to receive the data and from the data of the first pressure and the second pressure, determine if the first user has rolled over from the first support portion to the second support portion.

Introduced here are pressure-mitigation systems able to mitigate the pressure applied to a human body by the surface of an object (also referred to as a “structure”). A controller device (or simply “controller”) can be fluidically coupled to a pressure-mitigation device that includes a series of selectively inflatable chambers. When a pressure-mitigation device is placed between a human body and a surface, the controller can continuously, intelligently, and autonomously circulate fluid through the chambers of the pressure-mitigation device. Normally, the controller circulates air through the chambers of the pressure-mitigation device, though the controller could circulate another fluid, such as water or gel, through the chambers of the pressure-mitigation device. The controller may cause the chambers to be selectively inflated, deflated, or any combination thereof.

A system includes a pump having a filter. The filter includes a HEPA material configured for filtering air and the pump used to inflate an inflatable device configured to support a patient. A kit includes a pump configured for moving air to inflate an inflatable device, and a removable filter including a HEPA material couplable to the pump and configured to filter the air to inflate the inflatable device. The inflatable device configured to support a patient on a supporting surface.

A controller for positioning a patient utilizing an inflatable device is provided. The inflatable device may include three independently inflatable chambers. The controller may include first, second, and third pressure output ports; first, second, and third pressure sensors; a plurality of electro-mechanical switches; an electronic user interface; an computer; a pressurized air input port; and an atmospheric air port. The plurality of electro-mechanical switches may be configured to independently control air flow through the first, second, and third pressure output ports. The first, second, and third pressure sensors may be configured to measure pressure internal to the first, second, and third pressure output ports, respectively. The computer may be configured to receive first, second, and third pressure signals from each of the first, second, and third pressure sensors, respectively; to control each of the plurality of electro-mechanical switches; and communication with the user through the electronic user interface.

A mattress support assembly includes a mattress cover that has a coupling feature. A support casing defines an attachment feature and is selectively coupled to the mattress cover via the coupling feature. A support member is operably coupled to the attachment feature of the support casing. The support member has a load surface, a base surface, and an expandable body defined between the load surface and the base surface.