The invention disclosed provides means of inhibiting, ameliorating, and/or treatment of rheumatoid arthritis through the use of Noble gas containing mixtures. In one embodiment, the invention provides means of reducing inflammation and immune associated pathology through administration of Noble gas mixtures. In one specific embodiment, Xenon gas is administered to a patient in need at concentrations and frequencies sufficient to inhibit inflammatory and autoimmune processes. In another embodiment Noble gas mixtures are administered to reduce pain and provide symptomatic relieve to a patient suffering from rheumatoid arthritis. In another embodiment the use of Noble gas containing mixtures is disclosed as a means of reducing joint destruction through inhibition of matrix metalloprotease production and activity.

The invention relates to a medical use of water exerting a hydrostatic pressure higher than 1.1 bar, completely surrounding and affecting a patient's organism under total submergence, for use in prophylaxis, physiotherapy, rehabilitation and therapy of disorders, defects and injuries of skeletal system, arthroskeletal system, musculoskeletal system and other body systems such as circulatory system, nervous system, immune system, as well as pain conditions, such as migraine, myalgia and neuralgia, skin diseases, fertility disorders, potency dysfunctions, as well as overweight, obesity and defects of posture. According to the invention the hydrostatic pressure of water is preferably higher than 1.2 bar, and the patient is human being. The invention is of a particular importance in rehabilitation and therapy that follows after aesthetic medicine treatment, after surgeries, after physical injuries of motor system. The solution according to the invention is advantageously used in combination with procedures of classic hydrotherapy, manual therapy, kinesitherapy or combination thereof. It is of a particular benefit to provide air, mixture of gases of a composition different to the composition of air, mixtures of air and oxygen or pure oxygen for breathing (hyperbaric oxygen therapy HBO/HBOT), while the water may be supplemented with various additives appropriate for the kind of an ailment treated, such as mineral, gaseous, herbal, antiinflammatory, antimicrobial including antibacterial additives.

The present invention relates to a portable and foldable oxygen chamber, and more particularly, relates to a portable and foldable hyperbaric oxygen chamber that may be reduced in volume and conveniently carried and kept by including a tube capable of accommodating a patient and a body part which protects the tube and is divided into multiple cylindrical bodies formed in a longitudinal direction and inserted into and overlapped with one another.

It is disclosed a localized topical hyperbaric therapeutic instrument, comprising: a primary airbag, which is a chamber with an opening at an end; an oxygen generating device, which comprises an oxygen generator and a first pressure controller, wherein the oxygen generator has an oxygen outlet which communicates with the primary airbag through a first air inlet line and supplies oxygen into the primary airbag, and wherein the first pressure controller controls an amount of oxygen supplied to the primary airbag by the oxygen generator; a massage device; a heating piece, which is arranged in the primary airbag and generates heat; a treatment unit, which is arranged in the primary airbag in a detachable manner, disposed at a position corresponding to the heating piece, and comprises medical ingredients which are volatile upon heating.

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.

The present disclosure concerns uses for isoxazole compounds or salts or analogs thereof for the treatment of wounds. The present disclosure also concerns devices for delivering a isoxazole compound or salts or an analogs thereof to a wound site.

The present disclosure provides a hyperbaric thermal therapy system for medical applications. The disclosed system allows for independent control of pressure, temperature, and gas composition in the breathing system supplying breathing gas to the patient, and optionally of the environment surrounding a patient in a hyperbaric chamber, which allows for a wide range of hyperbaric thermal therapy profiles. Such hyperbaric thermal therapy profiles may be utilized in combination with other treatments, including medicament-based treatments, to enhance the therapeutic outcomes of such other treatments.

A chamber has an elongated rectangular flexible panel with a first longitudinal side and a second longitudinal side, a first lateral panel having a substantially triangular shape and rounded corners, and a second lateral panel having a triangular rectangular shape and rounded corners. The first lateral panel is sealingly engaged to the first longitudinal side of the elongated rectangular flexible panel. The second lateral panel sealingly engaged to the second longitudinal side of the elongated rectangular flexible panel. The elongated rectangular flexible panel, first lateral panel, and second lateral panel form the chamber having a substantially triangular prism shape.

A system and method of administrating conventional hyperbaric chamber therapy as well as supplemental oxygen therapy at ambient conditions to an animal using a veterinary hyperbaric chamber. The hyperbaric chamber can function in its usual mode of operation; i.e., providing oxygen at greater than atmospheric pressure and also in a second mode of operation to administer supplemental oxygen thereafter at ambient pressure conditions. In the second mode of operation, the method and apparatus may deliver approximately 80 liters per minute continuous flow of 0.21 through 1.0 FI02 adjustable oxygen gas mixture. The mixture is delivered at ambient pressure from one end of the chamber, flows across the animal positioned within the hyperbaric chamber, and exits at the opposite end for exhaust to ambient conditions. A high flow gas mixture is utilized to maintain accurate gas mixture concentrations with fluctuating supply pressures of medical air and medical oxygen gases.

A mobile hyperbaric hydrogen-oxygen system is installed into a vehicle having a vehicle cabin and a passenger seat disposed therein. The mobile hyperbaric hydrogen-oxygen system includes a sealed gas container, a gas supplier for supplying a flow of hydrogen gas and a flow of oxygen gas, a supercharger for pressurizing the hydrogen gas and the oxygen gas therein so as to mix the hydrogen gas and the oxygen gas to form a mixed gas, an inhalation mask arranged for being disposed at the passenger seat in a hand-reachable distance, and an air pump operatively connected between the sealed gas container and the inhalation mask for delivering the mixed gas from the sealed gas container to the inhalation mask. Therefore, the passenger sitting at the passenger seat is able to wear the inhalation mask in order to inhale the mixed gas in a controllable manner.