Some embodiments provide for an inspiratory limb for a breathing circuit that includes a first segment that comprises a first heater wire circuit and a second segment that comprises a second heater wire circuit. The inspiratory limb can include an intermediate connector that includes a connection circuit that electrically couples the first heater wire circuit to the second heater wire circuit. The inspiratory limb can be configured to operate in two modes wherein, in a first mode, electrical power passes through the first electrical connection to provide power to the first heater wire circuit without providing power to the second heater wire circuit, and in a second mode, electrical power pass through the first electrical connection to provide power to both the first heater wire circuit and the second heater wire circuit.

A patient support is provided. The patient support may include a plurality of inflatable members. The plurality of inflatable members may include a core including a resilient material. The patient support may be controlled with a first controller positioned within an envelope of the patient support. The patient support may include a detector to detect when an external controller is coupled to the patient support, the patient support being controlled by the second controller when the second controller is present.

A hospital bed may include a support structure, a controller, a pressure source coupled to the controller, and a hospital bed mattress carried by the support structure and having first and second ends, and first and second sides extending between the first and second ends. The hospital bed mattress may include bladders coupled to the pressure source. The bladders extend between the first and second ends and between the first and second sides and configured to provide pressure differential. The controller may be configured to pseudo-randomly adjust an internal pressure of each of the bladders.

A hospital bed may include a support structure, a controller, a pressure source coupled to the controller, and a hospital bed mattress carried by the support structure and having first and second ends, and first and second sides extending between the first and second ends. The hospital bed mattress may include bladders coupled to the pressure source. The bladders extend between the first and second ends and between the first and second sides and configured to provide pressure differential. The controller may be configured to pseudo-randomly adjust an internal pressure of each of the bladders.

A patient support is provided. The patient support may include a plurality of inflatable members. The plurality of inflatable members may include a core including a resilient material. The patient support may be controlled with a first controller positioned within an envelope of the patient support. The patient support may include a detector to detect when an external controller is coupled to the patient support, the patient support being controlled by the second controller when the second controller is present.

A seating system, particularly suited for personal mobility vehicles, such as wheelchairs, that includes a seat cushion having pressure relieving properties and enhanced thermal absorption properties. The seat cushion includes a thixotropic fluid contained within a flexible envelope. The thixotropic fluid includes a phase change material that enhances the thermal absorption properties of the seat cushion to increase thermal absorption from a seated user to provide a reduced temperature sensory effect. The thixotropic fluid further includes a thermal conduction medium that facilitates heat distribution to the phase change material.

The present disclosure provides a patient positioning device and methods of using such a device that allows for the easy securing of the device to the operating room table or hospital bed, a comfortable surface for patients to rest on during their diagnostic, therapeutic or surgical procedure, that helps reduce the likelihood of developing pressure ulcers, protects the patient by providing an infectious barrier, helps protects the patient from electrical injury by creating a non-conductive barrier between the patient the metal operating table, and protects the operating room table and equipment with an integrated, impermeable barrier to prevent blood, other bodily fluids and other fluids such as intravenous fluids, blood products and irrigation from soiling the operating or procedure table and nearby equipment. The device overcomes several challenges that exist with current devices and methods and is simple, disposable, and cost-effective. It allows for easier, faster and safer patient positioning, improved infection control, lower risk of electrical injury, improved protection from pressure ulcer formation, less waste compared to current options in a single, one-package solution. Additionally, a leg portion of the device can include an inflatable member which serves as a Sequential Compression Device which can be repeatedly inflated/deflated to facilitate circulation and prevent formation of blood clots.

A support apparatus configured to support a person is provided. The support apparatus includes a top surface including one or more predetermined areas, one or more conduits located inside the support apparatus which are located proximate to the one or more predetermined areas, and an air supply configured to provide air to the one or more conduits for delivering to the one or more predetermined areas. The air supply includes a temperature sensor configured to measure a temperature of the air provided by the air supply, a cooling element, and a controller communicatively coupled to the temperature sensor and the cooling element. The controller determines whether the measured temperature of the air is higher than a predetermined temperature, and controls the cooling element to cool the air to the predetermined temperature if it is determined that the temperature of the air is higher than the predetermined temperature.

A temperature modulation system for a bed, blanket, or other furniture includes a fluid for moderating temperature change, a number of conduit circuits for directing the fluid through respective zones, a control unit including a thermoelectric device for modulating temperature of the fluid, and a pump. Each of the conduit circuits selectively and independently directs fluid through its respective zone in order to produce a temperature within the zone that is independent of the temperature outside the zone. The system also includes an arrangement of one or more zones in an arrangement in which the control unit is programmed to vary the zone temperature over time according to a schedule.

A patient support apparatus includes a frame having a patient support deck. A footboard is removably coupled to the frame. A compression therapy module is located inside the footboard or is mounted to a foot section of the frame. A sleeve port is pneumatically coupled to the compression therapy module and is located on the foot section. The sleeve port is configured for attachment to at least one tube extending from a compression sleeve worn on a limb of a patient. Control circuitry is coupled to the frame and is operable to control functions of the patient support apparatus and to control the compression therapy module. A graphical display screen is coupled to the control circuitry and displays user inputs that are selected to control functions of the patient support apparatus and the compression therapy module.