A thermoelectric device including a panel, formed of a thermally insulating material, and having a plurality of thermoelectric elements including compacted conductors inside the insulating material and expanded conductors outside the insulating material wherein the thermoelectric elements run substantially parallel to or at an acute angle relative to the long dimension of the panel. The thermoelectric device may be integrated into a variety of surfaces or enclosures needing heating or cooling with controls and configurations to optimize the application.

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 support cushion liner includes a liner body having a cavity disposed between an outer layer and an inner layer and a plurality of artificial muscles disposed in the cavity of the liner body. Each of the plurality of artificial muscles include a housing having an electrode region and an expandable fluid region, a dielectric fluid housed within the housing, and an electrode pair positioned in the electrode region of the housing. The electrode pair includes a first electrode fixed to a first surface of the housing and a second electrode fixed to a second surface of the housing. The electrode pair is actuatable between a non-actuated state and an actuated state such that actuation from the non-actuated state to the actuated state directs the dielectric fluid into the expandable fluid region, expanding the expandable fluid region thereby applying pressure to the outer layer of the liner body.

A combination patient-transfer air-inflated pad and intraoperative heater device has first and second interlocking chambers laterally fused together. The air-inflated pad has a top surface and a bottom surface formed by way of the first and second interlocking chambers. The first interlocking chamber is formed as a comb-type structure having a main spine with two or more prongs alternately separated by valleys. The second interlocking chamber is a mirror comb-type structure to the first interlocking chamber. The device is fabricated from two thin layers of plastic material, selectively configured and fused. With this construction, the bulk of the device, as well as the cost of manufacture, are reduced. The device is affordable for single use, obviating the difficulty and possible incompleteness of sterilization between uses. The first interlocking chamber has an inlet appointed to be supplied with regulated, controlled low pressure and controlled temperature heated or cooled air. The second interlocking chamber has a plurality of air venting apertures in said bottom surface of said air-inflated pad. The second interlocking chamber has an inlet appointed to be supplied with ambient air at a regulated, controlled pressure to facilitate lifting and lateral displacement during patient transfer. The device may be easily re-employed when the patient is transferred from one location to another and may function as an alternating pressure mattress if needed.

An MRI-compatible system for supporting a patient during a medical procedure includes a frame, first and second platforms, a cooling device support, a therapeutic-applicator-positioning-system support, and a pair of leg rests. The first platform is configured to support the patient. The second platform is disposed between the foot end of the frame and the first platform. The cooling device support and the therapeutic-applicator-positioning-system support are mounted on the second platform. The cooling device support positions and releasably secures a cooling device. The therapeutic-applicator-positioning-system support releasably secures a therapeutic applicator positioning system. Each leg rest includes a leg support and a foot support. The leg rests are disposed on the frame and are configured to be slidably positioned towards the head end or towards the foot end of the frame.

A drawer includes insulation defining a climate-controlled insulated interior of the drawer, and a refrigeration system. The interior of the drawer may be divided into compartments having lids, and actuators may be provided for unlocking the lids. The actuators may include solenoids, which may be disposed outside the climate-controlled interior of the drawer. The drawer may include an air inlet, an outlet, and a fan. The fan may draw air through an air flow path defined at least in part by the insulation.

A thermal transfer device for providing thermal treatment to a patient. A patient support portion supporting and contacting the patient includes a first segment of a fluid flow path to receive a fluid from a fluid source. A flexible covering coupled and movable relative to the patient support portion defines a space therebetween that substantially conforms to the patient. The flexible covering includes a second segment of the fluid flow path. The fluid is circulated through an inlet, an outlet, and fluid flow path for supplying heat to or removing heat from the patient support portion and the flexible covering. A fluid circulation system with a controller may selectively adjust heat transfer from temperature zones defining the patient support portion. The thermal transfer device or a mattress cover may provide for controlling the microclimate, or conditions at or near the interface between the patient and the patient support portion.

A medical device, such as a patient support apparatus or a thermal control unit, includes a plurality of mechanical components and a plurality of nodes adapted to communicate with each other over a local network onboard the medical device, and a gateway in communication with an off-board network. The gateway translates messages between the onboard and off-board networks, manages subscriptions to content of the local network, controls bidirectional communication, and otherwise oversees communications between the local and remote networks. The gateway utilizes a configuration file for managing the communications between the off-board and onboard networks, and the gateway is configured to switch to using new or modified configuration files without requiring a reboot or power cycle of the gateway. Updates to the communications between the onboard and off-board networks can therefore be implemented without any downtime and/or without requiring updates to software executables.

The described apparatuses, devices, and mechanisms are configured to measure the temperature of one or more Abreu brain thermal tunnel (ABTT) terminuses. In addition, some embodiments are configured to provide treatment for the diagnosed conditions and diseases.

Described herein are components, systems, and methods of use of an integrated sterilization system comprising a pass-through logistics cabinet, an ozone sterilization system, a floor sterilization robot, and systems for controlling such components. An integrated operating room sterilization system will allow mitigation or elimination of risks (e.g., infrastructural risks (e.g., OI risks), procedural risks (e.g., risk of infection and contamination) that are associated with a setting in a healthcare environment. The elimination of clutter, control of major components under a unified and intuitive user interface, and the logical elimination of potential accumulated risk events (e.g., OI risks) and procedural risks are deliberately addressed, in whole or in part, by the present disclosure. The present disclosure describes the following: a pass-through logistics cabinet, an ozone sterilization system, a floor sterilization robot, and systems for controlling such components.