An intubation chamber comprising a vertical member that comprises at least one arm port, an enclosure member comprising at least one access port; and a transparent angled member coupled to the vertical member and the enclosure member, said at least one arm port to allow access to intubate a patient.

Introduced here are pressure-mitigation systems able to mitigate the pressure applied to a human body by the surface of an object. A system can include a pressure-mitigation device with chambers whose pressure can be varied by a controller that regulates the flow of fluid produced by a pump. The controller may be deployed as part of a closed loop system that autonomously infers information related to the health of a patient based on data related to the pressure of these chambers. For example, the data may be examined to determine whether the values indicate the patient is properly situated. A notification may be presented responsive to determining that the patient is not situated on the pressure-mitigation device, the patient has been improperly situated on the pressure-mitigation device for a certain amount of time, etc. Thus, real-time feedback may be provided to those responsible for monitoring the patient.

A sensor bed pad has a plurality of layers including an outermost layer made of a flexible material and a pair of inner layers, wherein each inner layer has an electrically conductive material thereon. A central layer is positioned between the pair of inner layers, wherein the inner layers are made of cloth, and wherein the central layer has a plurality of openings extending therethrough. The electrical conductive material of one of the inner layers contacts the electrical conductive material of the other inner layer through the openings in the central layer when a force is applied to the sensor bed pad to complete an electrical circuit between the inner layers.

The present disclosure generally relates to a manifold valve assembly engaged to an inflatable apparatus, such as a cushion to prevent pressure ulcers, for example. The manifold valve assembly is also in communication with a processing device to determine an optimal immersion level for a user seated on the inflatable apparatus. Additionally the processing device, in communication with the manifold valve assembly may save optimal immersion or air pressure levels for comparison to future checks of cushion pressure and send that to a user interface at the processing device. The assembly and processing device may also save and dis play a history of pressure checks.

A patient support apparatus includes a plurality of primary sensors adapted to measure different parameters used in the control of the patient support apparatus. One or more suites of secondary sensors are added to the patient support apparatus to provide data about the primary sensors. The secondary sensors may be used to detect errors in the primary sensors, to modify outputs from the primary sensors, and/or to provide usage and/or diagnostic data about the use of the patient support apparatus. The suite(s) of secondary sensors may measure parameters that affect the outputs of one or more of the primary sensors. In some embodiments, the suite(s) of secondary sensors include one or more dormant sensors that are not used on the patient support apparatus until a code modification is received from one or more external sources instructing the control system of the patient support apparatus to begin using the dormant sensor(s).

Patient transport apparatus with defined transport height comprises a support structure and a litter that are interconnected by a lift mechanism. The support structure comprises a base frame and a plurality of articulable support members or legs. The litter comprises a litter frame and a patient support surface with articulating back and leg sections. The lift mechanism may comprise one or more actuators configured to raise and lower the litter between a lowered position and one or more defined raised positions. The Patient transport apparatus may further comprise a controller coupled to one or more sensors and the lift mechanism. The controller may be configured to define a transport height for the litter based, at least in part, on a characteristic detected by the one or more sensors, and to manipulate the lift mechanism to adjust the litter to the defined transport height.

There is disclosed a method and system for determining the partial pressure of at least one gas in a mixture of gasses contained in a pressure vessel, in particular a pressure vessel in the form of a life support pressure chamber/decompression chamber, or a diving gas storage cylinder. The method comprises the steps of: coupling a gas analysis sensor (14) to a pressure vessel (10); directing a portion of the mixture of gasses in the pressure vessel to the sensor for analysis; reducing the pressure of the portion of the mixture which is to be analyzed by the sensor to a level which is below the pressure in the vessel but above local atmospheric pressure; operating the sensor to measure the partial pressure of the at least one gas at the reduced pressure level; and using the partial pressure of the at least one gas, measured at the reduced pressure level, to determine the actual partial pressure of said gas in the mixture contained in the vessel.

A bed includes an electronic controller comprising a first interface to monitor at least one sensor and a second interface to control at least one actuator; and an adjustable surface configured to be at least partially adjusted by the at least one actuator. The at least one sensor is configured, at least during some time intervals, to detect a momentary application of force by a bed occupant to at least one location on the adjustable surface; and the electronic controller interprets a defined sequence of momentary applications of force to the at least one location on the adjustable surface as one of a set of defined coded commands from the bed occupant, the set of defined coded commands each indicating the bed occupant desires one of a set of defined actions by the electronic controller.

Introduced here are apparatuses and systems for mitigating contact pressures applied to a human body by the surface of an object, such as a chair, bed, or table. A pressure-mitigation apparatus can include a series of chambers whose pressure can be individually varied. When placed between a patient and a contact surface, the pressure-mitigation apparatus can vary the contact pressure on a specific anatomical region of the patient by controllably inflating and/or deflating one or more cell. Moreover, a pressure-mitigation system can be readily integrated into a conventional treatment regimen for a variety of different conditions.

A support surface includes a patient fluid support surface that includes a first set of inflatable portions having an adjustable width and a second set of inflatable portions having an adjustable length, the width and length both adjustable by changing an amount of fluid in each of the first and second inflatable portions and a controller housing that includes a user interface device and a controller operative to provide control of both inflating and deflating of the first and second set of inflatable portions in response to electronic control signals from the user interface device.