The present invention is a mobile hyperbaric unit including a vehicle having a vehicle chassis with a front cabin and a rear bed. A partition can extend upwardly from the rear bed at a position next to the cabin. A pod can be removably attachable to the vehicle chassis, the pod having top wall, left and right side walls, a front wall, a rear wall, and a bottom wall that is sized and shaped to occupy and rest upon the rear bed. A detachable connection can enable attachment or detachment of the pod from the vehicle chassis, the connection can be connected to the pod at the bottom wall. The partition can have a portion that extends at least partially over the pod top wall. A pod chassis enables the pod to be transported independently of the vehicle chassis, the pod chassis can have a lift that enables elevation of the pod between lower and upper positions. A control station that has ambient pressure can be located in between the partition and the pod. A desired pressure that is not ambient pressure can be maintained within said pod interior by means on the vehicle.

A method of transporting a patient may include providing a medical pod having a pallet forming a floor structure and including sidewalls extending upwardly from the pallet to a roof section to form a container. The method may additionally include coupling a patient restraint system to the floor structure using a transport system located on the floor structure, and moving the patient restraint system from a first position to a second position using the transport system.

A method of transporting a patient may include providing a medical pod having a pallet forming a floor structure and including sidewalls extending upwardly from the pallet to a roof section to form a container. The method may additionally include coupling a patient restraint system to the floor structure using a transport system located on the floor structure, and moving the patient restraint system from a first position to a second position using the transport system.

An equipment mounting system may include a quick mount track having a backing plate with a center slot, a first outer slot, and a second outer slot, the first outer slot and the second outer slot comprise a plurality of diamond contour target regions, and a plurality of locking pin apertures along the center slot in the backing plate, the locking pin apertures are in horizontal alignment with the plurality of diamond contoured target regions. The equipment mounting system also may include a mount removably coupled to the quick mount track wherein the plurality of diamond contour target regions allow for a round head of a t-shaped stud of the mount to engage the first outer slot and the second outer slot at an angle to the backing plate.

A mobile plasma collection system comprising a mobile platform including a collection chamber, a freezing chamber operationally associated with the collection chamber, a mechanical and electrical chamber operationally associated with the collection chamber and the freezing chamber, wherein the mechanical and electrical chamber is isolated from the freezing chamber, and a refrigeration system operationally associated with the freezing chamber and the mechanical and electrical chamber.

A radiation device is wirelessly connected to a radiography device that generates dynamic image data and which controls sequential radiation. The radiation device includes a signal generator and a first determiner. The signal generator generates (i) first pulse signals emitted by the radiography device, (ii) second pulse signals synchronized with a first count value obtained by counting up the first pulse signals, and (iii) a second count value obtained by counting up the second pulse signals. The first determiner determines whether to start radiation based on a delay time which is a difference between a first time point count value and a second time point count value. The first time point count value indicates a time point at which a radiation permission signal is transmitted. The second time point count value indicates a time point at which the radiation permission signal is received.

Load control apparatuses, systems and methods to control a location, orientation, or rotation of a suspended load by imparting thrust vectors to the suspended load or to a structure that holds the load. The load control apparatuses, systems and method may be integrated into a structure that holds a load, such as a rescue litter. The load control apparatuses, systems, and methods may be modular. The modular load control apparatuses, systems, and methods may be secured to a load or to a structure that holds the load.

Container mounting assemblies are disclosed. According to one embodiment, a container mounting assembly includes mounting plates (31, 33), track engagement members outwardly extending from the track engagement surface, mounting receptacles (20, 20) spaced and outwardly extending from the container mounting surface (3), and a retention locking member (40) near at least one mounting receptacles. Each mounting plate has a track engagement surface and a container mounting surface opposite the track engagement surface. The track engagement members can engage one or more track slots of a track member. Each mounting receptacle has at least one vertical slot (17) for receiving an insert of a container. The retention locking member is configured to secure the container to the container mounting surface.

The disclosure relates to a mobility system. The mobility system has at least one driven exoskeleton for a person. The at least one driven exoskeleton has at least one electronic unit that controls and/or regulates an operating state of the exoskeleton. At least one vehicle has a passenger compartment and at least one mechanical coupling station, which is arranged in the passenger compartment. The exoskeleton can be mechanically coupled to the mechanical coupling station. The vehicle has at least one electronic device, wherein the electronic unit is connectable, via at least one communication connection, to the electronic device.

A shock absorbing apparatus for mitigating agitations while riding within a vehicle. The apparatus is configured to allow a gurney to be connected thereto and further be connected to the floor of an emergency vehicle. The apparatus includes an airbag system that is deflated/inflated by closing/opening the gurney entrance door of the vehicle.