The invention relates to a medical container unit for designing and/or manufacturing an implant, comprising a plurality of container subunits, each of which forms a sector, is equipped with at least one means for designing and/or manufacturing an implant, and is formed by self-supporting partial substructures on at least two sides.

A method for providing medical services to a patient, including: receiving a medical service request associated with a patient location; selecting an aircraft, located at an initial location, from a plurality of aircraft based on the patient location and the initial location; determining a flight plan for flying the aircraft to a region containing the patient location; at a sensor of the aircraft, sampling a first set of flight data; at a processor of the aircraft, autonomously controlling the aircraft to fly based on the flight plan and the set of flight data; selecting a landing location within the region; and landing the aircraft at the landing location, including: sampling a set of landing location data; determining a safety status of the landing location based on the set of landing location data; outputting a landing warning observable at the landing location; at the sensor, sampling a second set of flight data; and in response to determining the safety status and outputting the landing warning, autonomously controlling the aircraft to land at the landing location based on the second set of flight data.

A method for providing medical services to a patient, including: receiving a medical service request associated with a patient location; selecting an aircraft, located at an initial location, from a plurality of aircraft based on the patient location and the initial location; determining a flight plan for flying the aircraft to a region containing the patient location; at a sensor of the aircraft, sampling a first set of flight data; at a processor of the aircraft, autonomously controlling the aircraft to fly based on the flight plan and the set of flight data; selecting a landing location within the region; and landing the aircraft at the landing location, including: sampling a set of landing location data; determining a safety status of the landing location based on the set of landing location data; outputting a landing warning observable at the landing location; at the sensor, sampling a second set of flight data; and in response to determining the safety status and outputting the landing warning, autonomously controlling the aircraft to land at the landing location based on the second set of flight data.

A safety system for an aerial vehicle, preferably including: a ballistic subsystem, preferably including one or more rockets operable to adjust motion of the aerial vehicle and a mounting unit that couples the ballistic subsystem to the aerial vehicle; and/or a deployable parachute subsystem. An aerial vehicle, preferably including a safety system. A method for aerial vehicle operation, preferably including activating a safety system.

A safety system for an aerial vehicle, preferably including: a ballistic subsystem, preferably including one or more rockets operable to adjust motion of the aerial vehicle and a mounting unit that couples the ballistic subsystem to the aerial vehicle; and/or a deployable parachute subsystem. An aerial vehicle, preferably including a safety system. A method for aerial vehicle operation, preferably including activating a safety system.

A mobile transportation system, having a plurality of modules, including a self-sufficient hospital facility, small-scale medical device manufacturing facility, vaccine production facility, pharmaceutical production facility, sterilization facility, and food production facility, as well as an accommodation facility; wherein each of said plurality of modules, when necessary can be unloaded from the aerospace object and connected to other modules to become part of a larger modular facility with specific purposes, to allows for customization of the facility depending on the medical or other needs.

A lift system for an oxygen bottle is described. The lift system includes a frame. The lift system includes a counterbalance assembly and a cradle assembly. The cradle assembly hold the oxygen bottle or other article. The counterbalance assembly includes several biasing devices to adjust a counterbalance force provided by the counterbalance assembly to accommodate oxygen bottles with different weights. The lift system may be employed on ambulances or other emergency vehicles.

A securement system for portable bottles, intended for use in a vehicle, is disclosed and claimed herein. In one particular embodiment, the securement system is constructed from a vertical stanchion. Disposed about the periphery, on four sides, are four vertically oriented mounting channels. A top bottle holder and a bottom bottle holder are installed in a selected mounting channel. At least the top bottle holder can be adjusted vertically to accommodate bottles with various heights. The bottom bottle holder includes a platform for supporting the bottle, and both the top and bottom holder include a cradle that receives a side of the bottle. Both the top bottle holder and bottom bottle holder include releasable, hook and loop straps to hold the bottle flush and secure against the cradles. The base of the stanchion includes features for securing the stanchion in a convention L-Track, of the type typically found in transit vehicles.

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 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.