Described are a low temperature plasma reaction device and a hydrogen sulfide decomposition method. The reaction device includes: a first cavity; a second cavity, the second cavity being embedded inside or outside the first cavity; an inner electrode, the inner electrode being arranged in the first cavity; an outer electrode; and a barrier dielectric arranged between the outer electrode and the inner electrode. The hydrogen sulfide decomposition method includes: implementing dielectric barrier discharge at the outer electrode and the inner electrode of the low temperature plasma reaction device, introducing a raw material gas containing hydrogen sulfide into the first cavity to implement a hydrogen sulfide decomposition method, and continuously introducing a thermally conductive medium into the second cavity in order to control the temperature of the first cavity of the low temperature plasma reaction device.

The object of the present disclosure is to efficiently generate plasma. In the plasma device of the present disclosure, a dielectric barrier discharger and an arc discharger are included, but the arc discharger is provided downstream from the dielectric barrier discharger in a discharge space where a gas for generating plasma is supplied. Dielectric barrier discharge occurs at the dielectric barrier discharger, and arch discharge occurs at the arc discharger. As a result of the gas for generating plasma being activated in the dielectric barrier discharge, the aforementioned gas can be adequately converted to plasma in the arc discharger.

The present disclosure relates to a portable plasma device which is convenient to carry and has excellent performance and is capable of simply, uniformly, and locally treating an inner surface of a microstructure such as a microwell plate by easily adjusting a plasma flame.

Disclosed are a dental disease treating device, and more particularly, to a dental disease treating device that may generate high-density plasma that is required for a treatment of a dental disease, such as periodontitis, and minimize generation of ozone as well, and a method for treating a dental disease. The dental disease treating device that generates plasma for treating a dental disease, includes a handpiece body having a space part in an interior thereof, a plasma generating part mounted in the space part of the handpiece body, and that generates the plasma by exciting a gas in a plasma generating space in an interior thereof, and a tip part detachably coupled to an end nozzle of the handpiece body or the plasma generating part, and the tip part includes a passage for irradiating the plasma to a local portion while inhibiting oxygen from being introduced into the plasma generating space.

Provided is a mist generator including: a container that stores a liquid; a gas supply unit that supplies a gas into the container; and an electrode that generates plasma of the gas between the electrode and the liquid, where the supply direction of the gas fed from the gas supply opening of the gas supply unit is different from a direction in which gravity acts.

A speculum body is configured to attach to the otoscope. An array of radially situated microchannels is within the speculum body and extends to apertures in a distal end of the speculum body. A power electrode array is within the speculum body positioned with respect to the microchannels to excite plasma generation within the microchannels. An optically transparent central portion is in the body to permit viewing of an eardrum by a practitioner. A method of treatment of the middle ear and/or middle ear cavity incudes actuating plasma jets to extend into the ear canal from a speculum attached to the otoscope and continuing the plasma jet treatment for a period of time sufficient to inactivate or kill a bacterial biofilm in the middle ear and/or the middle ear cavity.

Adjustable distal tips of cold plasma generating devices configured for introduction to and operation within narrow intra-body confines. In some embodiments, a plasma delivery tip of a cold plasma generating device is expandable from a compact delivery configuration, allowing device operation with plasma plume parameters difficult to achieve within size constraints of a narrow delivery catheter and/or endoscope working channel. Additionally or alternatively, in some embodiments, operating parameters of a plasma delivery tip are adjustable to tune characteristics of the plasma plume. Adjustable parameters optionally include, for example: lumen diameter, lumen aperture shape/direction, discharge electrode geometry, dielectric barrier characteristics, and/or relative placement of these components, including placement relative to a stream of ionizing gas. In some embodiments, plasma delivery tip elements are adapted to assist device navigation and/or tissue penetration.

The invention relates to a device (10) for generating a plasma jet (P) comprising a first conduit (11) inside a second conduit (12), a first electrode (17) and a second electrode (18) for generating an electric field in a feed gas flow (F) provided in a first flow channel (15) to generate a plasma jet (P), and adapted to provide a curtain gas flow (C) in the space between the first and second conduit (11,12), wherein the first electrode (17) is positioned radially outside of the first flow channel (15), and wherein the radial distance of the second electrode (18) from a longitudinal axis (I) is larger than the radial distance of the first electrode (17) from said longitudinal axis (1). The invention further relates to an endoscope comprising a device (10), a method for generating a plasma jet (P), a method and a use of the device (10) for manipulating a cavity.

An irradiator includes: a first electrode to which a voltage is applied for generating a plasma; and a holding member holding the first electrode; wherein: the holding member has a first member and a second member that are in contact with each other to constitute an accommodation space accommodating the first electrode; and a contact surface between the first member and the second member includes a non-perpendicular contact surface that is non-perpendicular to an axis of the first electrode.

A flexible elongate atmospheric plasma generator for generating a transverse atmospheric plasma within configured for insertion into an internal channel of an elongate endoscope tube, the plasma generator including an elongate body of dielectric material, an elongate first electrode centrally located within the body of dielectric material and an elongate second electrode around an elongate external surface of the body of dielectric material, the second electrode having a plurality of electrically conductive elements forming a mesh defining holes in the second electrode, wherein application of a potential difference across the first and second electrodes can generate a plasma within atmospheric air surrounding the atmospheric plasma generator.