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 can be 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 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. 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 the pod interior by support systems on the vehicle.

The present invention relates to a hyperbaric ambulance and transfer-under-pressure (TUP) unit. More particularly, the present invention relates to a vehicle for emergency transport and treatment of a patient that is capable of providing hyperbaric oxygen treatment to the patient, and a mobile unit for transferring the patient from the vehicle to a medical care facility. More particularly, the present invention includes a vehicle having a driver section and a vehicle chassis having a patient section that includes a hyperbaric treatment chamber. An entrance module can be positioned in between the driver section and the patient section, the entrance module having a communication and control compartment and a pressure module. The pressure module can have at least two pressure hatches, wherein at least one of the at least two pressure hatches allows personnel to enter the pressure module from the control compartment, and at least one of the at least two pressure hatches allows personnel to enter the treatment chamber from the pressure module. The pressure module enables a user to selectively enter or exit the entrance module while simultaneously maintaining a selected elevated pressure value in said patient section, and preferably enables a user to selectively enter or exit said hyperbaric treatment chamber from the entrance module while simultaneously maintaining a selected elevated pressure value in the patient section.

A portable and compact hyperbaric chamber includes an inflatable chamber, a weighted base, a dump valve, at least one auxiliary port, an external pressure gage, a plurality of fill valves, and a plurality of pressure relief valves. The access opening is integrated into a lateral panel of the inflatable chamber and provide in and out access to the inflatable chamber. The weighted base is mounted to the base panel and functions as a stable base. The plurality of fill valves is in fluid communication with the inflatable chamber to provide compressed air from a compressor so that the inflatable chamber can be pressurized. The plurality of pressure relief valves is in fluid communication with the inflatable chamber to maintain a specific pressure within the inflatable chamber. The dump valve, the auxiliary port, and the external pressure gage are in fluid communication with the inflatable chamber to optimize the functionality.

The present disclosure concerns methods and systems for improving cognitive performance. More specifically, the disclosure concerns methods and systems for cognitive training under hyperbaric conditions.

The subject matter of the invention is a therapeutic device in the form of a cylindrical chamber which comprises a hyperbaric chamber, LED matrices (5) and inductive coil rings (10, 11, 12, 13), constructed in one inseparable set in the form of a chamber of 200-280 cm in length and diameter of the round cylinder (70-130 cm).

The present invention relates to a resuscitation chamber apparatus for administering hyperbaric oxygen to a patient. More particularly, the present invention relates to a hyperbaric oxygen compatible critical care chamber apparatus preferably for use in emergency departments and/or prehospital ambulance management of patients. In a preferred embodiment of the present invention, the apparatus is a resuscitation monoplace hyperbaric chamber preferably used in critical care management of acutely ill or injured patients in prehospital emergency medical services (EMS) settings or in hospital emergency departments. The apparatus preferably allows a critical care shock or arrested patient to be pressurized preferably without compromise for application of best medical equipment, medications and human resuscitating intervention.

The present disclosure relates to methods for lengthening telomeres. administering a hyperbaric oxygen therapy protocol; prescribing an exercise regimen that is performed inside of a hyperbaric chamber during the administration of the hyperbaric oxygen protocol; and prescribing a specialized nutrition plan comprising a daily intake of high fiber.

The present subject matter relates to devices, systems and methods for the construction of pressure chambers. Such pressure chamber devices, systems, and methods can include a plurality of substantially rigid panels arranged around a space, each of the substantially rigid panels comprising a metal frame formed from a plurality of metal frame elements. One or more connecting plate can be coupled to adjacent pairs of the plurality of substantially rigid panels. In this way, the one or more connecting plate is configured to provide a pressure-tight seal between a respective adjacent pair of the plurality of substantially rigid panels.

Disclosed herein are modules for performing hyperbaric oxygen therapy (“HBOT”) on a patient submerged in pressurized water where substantially no gas is present in the module. The modules generally have an entry, a fluid inlet for introducing water into the module, first and second fluid outlets positioned substantially at a base and a top of the module respectively, and a utilities inlet and outlet in part for transferring breathing air to and from the patient. The module permits HBOT treatment on a patient submerged in water with no air in the module, thus reducing the risk of fire or explosion. Methods and systems are also contemplated. Disclosed herein are methods of filling a module with water until there is substantially no gas in the module, and providing the patient in the module with treatment air during HBOT treatment.

The present invention relates to an adaptive hyperbaric oxygen chamber designed to function as a medical apparatus in order to treat a subject suffering from any FDA approved medical condition. The hyperbaric oxygen chamber is designed and constructed in such a way that only one subject can be allowed to sit in an upright seated position, unless the pediatric seat is occupied by a pediatric patient and the adult is seated in the standard seat to accompany the pediatric patient. The upright patient seat when treating a pediatric patient is in the extended position while the occupant enters and exits the mono medical hyperbaric oxygen chamber and the seat is returned to the fixed position inside the hyperbaric oxygen chamber while the overhead door is closed, the seat being operated by an extension device. The hyperbaric oxygen chamber is made, using additive manufacturing technology. The hyperbaric oxygen chamber provides two hundred to five hundred liters of one hundred percent oxygen per minute to the pressure vessel. A nitrogen scrubber is connected to a discharge air duct of this hyperbaric oxygen chamber that converts the oxygen being expelled through the air duct to one hundred percent nitrogen.