The present disclosure relates to a system comprising an operating table, and air bladder, and an air compressor, in particular, to a system which is used for kidney surgery.

Introduced here are methods, apparatuses, and systems for mitigating the contact pressure 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, a controller can vary the contact pressure on the human body by controllably inflating one or more chambers, deflating one or more chambers, or any combination thereof. By monitoring the pressure in each chamber over time, the controller can also gain an enhanced understanding of movement(s) performed by the human body when positioned on the pressure-mitigation apparatus.

A bed apparatus includes: a mattress mounted on a bed body; and, first cells arranged on both left and right sides in a longitudinal direction of the bed body and is configured to change the body position of a patient on the mattress by inflating the first cells alternately. When the first cells on the left and right sides are inflated, and when a difference in pressure between the first cells on the left and right sides has continuously fallen within a decision pressure value range for a decision pressure value continuation time, the body position of the patient is changed, whereas when the difference has not continuously fallen within the pressure value range for the continuation time or when the difference has continuously fallen out of the pressure value range for the continuation time, change of the body position of the patient will not be performed.

Active comfort controlled bedding systems include a variable firmness control and/or variable climate control. The active comfort controlled bedding systems generally include a plurality of air bladders, each one of the plurality of air bladders includes a pressure sensor configured to measure pressure within a respective air bladder. A control unit configured to selectively operate a pump and valves to sequentially adjust a pressure in two or more of the plurality of air bladders having an applied load of an end user thereon to provide a repeating pattern within the two or more plurality of air bladders, wherein the repeating pattern is defined by a pressure increase and subsequent decrease in a selected one of the plurality of air bladders followed a pressure increase and subsequent decrease in a selected other one of the plurality of air bladders to provide a massaging action.

A negative pressure room with a safety management system according to an embodiment of the present disclosure includes an interior space being under negative pressure and is provided in a movable form, so that the negative pressure room can be constructed promptly and economically in the event of a spreading infection, thereby enabling rapid and efficient quarantine treatment and observation of patients with confirmed and suspected infections, the negative pressure room is isolated from a general ward, thereby preventing the possibility of further infection to other patients or medical staff, and real-time monitoring whether negative pressure is appropriately generated in the interior space, air quality in the interior space, and the state of an isolated patient is enabled.

A controller for operative connection to a power assisted transport vehicle that is at least partially directed by a human operator in physical contact with the vehicle, the controller including: a contact surface with a deadman switch, a first sensor and a second sensor each responsive to manual actuation of the contact surface, each sensor having a respective first sensor output signal and a second sensor output signal, and a signal processing means adapted to process the first and second output signals, and control the mode of operation of the controller in accordance with the state of the deadman switch.

A system for monitoring medical conditions including pressure ulcers, pressure-induced ischemia and related medical conditions comprises at least one sensor adapted to detect one or more patient characteristic including at least position, orientation, temperature, acceleration, moisture, resistance, stress, heart rate, respiration rate, and blood oxygenation, a host for processing the data received from the sensors together with historical patient data to develop an assessment of patient condition and suggested course of treatment, including either suspending or adjusting turn schedule based on various types of patient movement. The sensor can include one or more of bi-axial or tri-axial accelerometers, magnetometers and altimeters as well as resistive, inductive, capacitive, magnetic and other sensing devices, depending on whether the sensor is located on the patient or the support surface, and for what purpose. In some embodiments, the sensor can be self-contained in that it can detect orientation and suggest repositioning independent of a host.

Introduced here are pressure-mitigation apparatuses able to mitigate the pressure applied to a human body by the surface of an object. A controller device 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 device can continuously, intelligently, and autonomously circulate air through the chambers of the pressure-mitigation device. As further discussed below, the controller device may cause the chambers to be selectively inflated, deflated, or any combination thereof. Such an approach is useful in a variety of contexts. For example, pressure-mitigation apparatuses may be used to improve treatment of patients suffering from respiratory illnesses and patients who are partially or completely immobilized for extended durations (e.g., as part of a medical procedure).

A posture support system for a person supporting appliance comprising: a module (300), each module (300) comprising: an expandable body (20), means (60) for changing the degree of expansion of the expandable body (20); a sensor (27) configured to produce measurement data corresponding to the degree of expansion of the expandable body (2); a processor (116) arranged to process the measurement data generated from the sensor (27); and a wireless communication unit (114) arranged to transmit the measurement data wirelessly to a controller (320) and receive control data to control the degree of expansion of the expandable body (20).

Systems and methods for providing data continuity for a mobile medical cart are provided. A battery board comprising a voltage detection circuit (“VCD”), a microcontroller, and a switching device electrically interposed between an alternative power source, a removable battery, and system boards for controlling cart functions. The microcontroller commands the switching device to: begin sourcing power solely from the alternative power source upon detection of a voltage decrease, begin sourcing power solely from the removable battery upon detection of a voltage increase where a valid charge state exists, and continue sourcing power solely from the alternative power source upon detection of the voltage increase where no valid charge state exists.