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 reduced outflow valve in fluid communication with an inflatable apparatus comprising a tubular body defining an inner bore and a plunger slidingly engaged in the bore. Inflation of the inflatable apparatus urges the plunger to a first position configured to allow rapid ingress of air into the cushion to inflate the cushion and deflation of the inflatable apparatus urges the plunger to a second position wherein the plunger is configured as a baffle to dampen or slow air egress during release of air.

Pressure modulating soft actuator array devices and related systems and methods. One example of the present systems comprises: a device having a body that defines a plurality of cavities; a pressure source configured to be in fluid communication with the plurality of cavities; a plurality of sensors configured to capture data indicative of pressure within the plurality of cavities; and one or more controllers configured to actuate the pressure source to move fluid toward and/or away from one or more of the plurality of cavities in response to data captured by the plurality of sensors; wherein the device is configured to be disposed between a user and a surface on which the user is seated upon.

A flexible circuit package. The circuit package includes a termination point on a flexible base substrate. The termination point is connected with an interface by conductive material on the base substrate. The conductive material extends across the surface area of the base substrate in multiple individual connections, which are in communication with each other and separated by voids in the conductive material for mitigating communication failure between the termination point and the interface during or following flexion, stretching, compression or other deformation of the base substrate and the circuit package. The termination point may include an input module such as a sensor, switch or other input. The termination point may include an output module such as a light, vibrator or other output. The interface may include an output interface for receiving data or an input interface for sending a command or other signal.

Devices, systems, and methods for supporting the body of user are described. Devices, systems, and methods can employ a plurality of cells where each of the cells within the plurality of cells can comprise a bladder containing air or another compressible fluid supported by a base that forms a fluid-tight seal with the bladder The base and bladder can be constructed and arranged so that the bladder forms a rolling diaphragm portion with the base. The height and/or applied pressure in response to an applied load of such bladder may be adjustable substantially independent of the crosssectional shape and dimensions of the bladder. Each of the cells within the plurality of cells which may be a subset or all of the cells of a given support, can also comprise, or otherwise be operatively associated with its own: pressure sensor, height sensor, or both, and/or controllable inlet/outlet valve(s).

The invention relates to a stand device (1) for arranging in an operating room and for locally moving a medical device (20), comprising a braking device (50) having at least one brake (51) that is configured to adjust a degree of freedom of movement of the medical device (20) or a support system (10) holding the device, wherein the stand device (1) further comprises a control device (30) connected to the braking device (50) that is configured to evaluate an external force acting on the stand device (1) or a movement caused by the external force and configured to control the braking device (50) and to adjust the degree of freedom of movement. As a result, the medical device can be moved without operating a switch/pushbutton. Furthermore, the invention relates to a corresponding control device and a method for positioning the medical device.

Disclosed herein is a cushioning device that includes a plurality of fluid cells each containing fluid for supporting a load. The cushioning device further includes a manifold system interconnecting the plurality of fluid cells, a first reservoir, and a second reservoir connected to the first reservoir in series. The first and second reservoirs are connected with a pressure relief valve allowing fluid to escape from the first reservoir to the second reservoir when the pressure in the first reservoir exceeds a threshold and a check valve allowing fluid to flow back from the second reservoir to the first reservoir. Further disclosed is a method of cushioning a body with a cushioning device.

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 body state determination device includes a detection unit that is configured to detect a plurality of pressure distributions formed by a body weight of a user, and a determination unit that is configured to determine a state of a body of the user by comparing the plurality of pressure distributions detected by the detection unit with each other.

The present disclosure generally relates to the field of temporal and spatial risk mapping and risk response. More particularly, the present disclosure relates to spatial and temporal mapping of outcomes, risk analysis, and responsive and preventative actions derived through artificial intelligence driven workflow augmentation using spatial and temporal data mapping of data from a plurality of historical and streaming data sources.