The present invention discloses a plasma generation unit and a plasma treatment apparatus, the plasma generation unit including a first electrode part that includes a body having an insertion hole therein and having an insulation property and a conductive member disposed on an outer circumferential surface of the body, and a second electrode part that has a gas injection hole communicating with one end thereof, has another end region inserted into the insertion hole of the first electrode part, and has a conductive property, wherein the another end region of the second electrode part has a diameter that is decreased toward the other end and is located to correspond to an arrangement region of the conductive member.

A medical system for providing radiotherapy is disclosed. The system comprises a particle accelerator configured to produce a radiation beam and irradiate at least a part of a subject with the radiation beam. The particle accelerator comprises a plasma zone comprising or configured to receive a plasma, and at least one beam source configured to provide an excitation beam along an axis through the plasma zone. The medical system is configured to provide a plurality of charged particles in the plasma in a region that propagates through the plasma zone behind the excitation beam such that the plurality of charged particles are accelerated to produce a radiation beam comprising the plurality of charged particles with a broadband energy distribution, wherein: at least part or all of the energy distribution of the radiation beam is substantially exponential or power-law; the radiation beam delivers 75% or more of a dose of the charged particles at and below 2 g/cm.sup.2; and/or the energy beam has an energy or energy distribution in the range from 10 eV to 10 MeV.

A floating type plasma electrode pad includes the plasma electrode made of a conductive metal thin film, a flexible dielectric thin film layered on the plasma electrode, and made of a polymer material, the dielectric thin film being spaced apart from the skin by a predetermined distance such that microdischarge is generated in a space defined between the dielectric thin film and the skin, and a spacer layered on the dielectric thin film, to space the dielectric film from the skin by the predetermined distance.

A device has a power source having a high voltage terminal and a low voltage terminal, an oil-free gas compressor, a first molecular sieve, multiple ionized gas generators, an outer metal pipe, an inner metal pipe, a dielectric insulating ceramic sheet, and a gas outlet pipe. The first molecular sieve is connected between the oil-free gas compressor and the ionized gas generators, and is capable of filtering out molecules in the gas except for oxygen. The outer metal pipe and the inner metal pipe are electrically connected to the low voltage terminal and the high voltage terminal respectively. The dielectric insulating ceramic sheet is mounted between the outer metal pipe and the inner metal pipe, and forms an ionizing space, which communicates with the ionizing space, with the outer metal pipe.

An array of non-thermal plasma emitters is controlled to emit plasma based on application of an electric current at desired frequencies and a controlled power level. A power supply for an array controller includes a transformer that operates at the resonant frequency of the combined capacitance of the array and the cable connecting the array to the power supply. The power into the array is monitored by the controller and can be adjusted by the user. The controller monitors reflected power characteristics, such as harmonics of the alternating current, to determine initiation voltage of the plasma and/or resonant frequency plasma emitters. The array of non-thermal plasma emitters may be used in therapeutic, diagnostic, and/or medical sanitization applications, including where a non-thermal plasma treatment regimen is prescribed.

The invention relates to a treatment device for dielectric harrier discharge plasma treatment of a wound surface or skin surface, having: a flexible, planar electrode assembly with at least one planar electrode (6, 6′) and a dielectric layer (5) which at least partially embeds the at least one electrode (6, 6′), has a contact side (7) facing the wound surface or skin surface and electrically shields the planar electrode (6, 6′) from the wound surface or skin surface such that only a dielectric barrier current can flow from the electrode (6, 6′) to the wound surface or skin surface; and a control device (2) which has a separate housing (25) and via which the electrode (6, 6′) can be connected to an operating voltage. The treatment device allows simpler wound treatment in that the assembly of electrode (6, 6′) and dielectric layer (5) is designed for uninterrupted contact with the wound surface or skin surface and that the housing (25) of the control device (2) can be fastened with a fastening device (3, 3′) to the body having the wound surface or skin surface.

A system for generating cold plasma is presented, suitable for use in in-vivo treatment of biological tissue. The system comprising: a control unit connectable to an elongated member at a first proximal end of the elongated member. The elongated member comprises a plasma generating unit at a second distal end thereof and gas and electricity transmission channels extending from said first proximal end towards said plasma generating unit. The control unit comprises a gas supply unit configured to provide predetermined flow rate of selected gas composition through said gas transmission channel and a power supply unit configured to generate selected sequence of high-frequency electrical pulses, typically in mega Hertz range, directed through said electricity transmission channel, thereby providing power and gas of said selected composition to the plasma generating unit for generating cold plasma.

Sterilisation systems suitable for clinical use for generating a flow of hydroxyl radicals, comprising: a coaxial transmission line comprising an inner and outer conductor; an end cap mounted on a distal end of the coaxial transmission line, wherein the end cap comprises an outlet aperture; a fluid conduit extending from a fluid inlet to the outlet aperture; and a plasma generating region at a proximal end of the outlet aperture, wherein the plasma generating region contains a first electrode electrically connected to the inner conductor, and a second electrode electrically connected to the outer conductor, wherein the fluid conduit defines a fluid flow path through the device aligned with a feed direction in which fluid is receivable through the fluid inlet, and wherein the first electrode and second electrode oppose each other in a transverse direction across the longitudinal fluid flow path in the plasma generating region.

There is described herein, a plasma device for the generation of oxygen and nitrogen species (RONS) and methods of generating RONS using the plasma device.

Disclosed is a device having an oscillator and high voltage transformer connected to a glass-like tube filled with an inert gas or a mixture of inert gasses. The tube is located at the end of a wand having a handle. The output of the transformer is an RF high voltage signal. The output of the transformer is fed to the tube through a high voltage wire, where the signal excites the gas to produce a plasma-like beam. The tube is then applied to a patient's skin to aid in healing and the relief of additional ailments. The field generated by the tube interacts with the cells in the patient to increase transmembrane potential, stimulate ATP production, and inject negative ions and ozone into the surface of the user's skin to combat infection and disease.