Abstract: An electrosurgical method and device for simultaneously cutting and coagulating tissue with an electrosurgical device having an electrode and a channel wherein said channel has a port near a proximal end of said electrode, wherein the method comprises the steps of causing an inert gas to flow through said channel and exit said port, applying high-frequency energy to said electrode while said inert gas flows through said channel, wherein said high-frequency energy applied to said electrode continuously plasmatizes inert gas exiting said port, initiating an electrical discharge from said electrode through said continuously plasmatized inert gas to said tissue, cutting tissue with said electrode, maintaining said electrical discharge from said electrode through said plasmatized inert gas while cutting tissue with said electrode to cause coagulation of said tissue simultaneously with said cutting.

Abstract: An attachment for a gas-assisted electrosurgical device. The attachment has a housing having a channel within it, an electrosurgical blade and an electrical connector. The electrosurgical blade has a conductive member comprising an elongated distal portion and a proximal portion, the distal portion having a width greater than a width of the proximal portion, the width of the distal portion being at least three times the thickness of the distal portion, and a coating on at least a portion of said conductive member.

Abstract: A cold plasma accessory having a hand piece having within in it flexible tubing, wiring, a PCB board connected to the wiring, and a conductive connector tube electrically connected to the PCB board, the conductive connector tube having an inner channel, a rigid tube extending from the distal end of the hand piece, and an electrode within the rigid tube. The electrode comprises a conductive connector having a contact surface contacting the conductive connector tube, a distal end surface facing away from the conductive connector tube, and a channel extending through a center of the conductive connector, the channel being fluidly connected to the flexible tubing, the distal end surface of the conductive connector being outside of the channel in the conductive connector, and a conductive wire connected to the distal end surface of the conductive connector.

Abstract: A gas-enhanced electrosurgical generator. The gas-enhanced generator has a housing, a first gas control module in the housing and configured to control flow of a first gas, a second gas control module in the housing and configured to control flow of a second gas, a high frequency power module, and a controller, processor or CPU within the housing and configured to control the first gas control module, the second gas control module and the high frequency power module. The first gas and second gas may be any of CO2, argon and helium or another gas. The gas-enhanced electrosurgical generator may have a third gas control module in the housing and configured to control flow of a third gas and a third connector secured on an exterior of the housing.

Abstract: A gas control module for a gas-enhanced electrosurgical system. The gas control module has an inlet port, a first solenoid valve connected to said inlet port, a first pressure sensor, a first pressure regulator, a first flow sensor, a first proportional valve, a second flow sensor, a second solenoid valve, said second solenoid valve being a 3-way valve, a vent connected to said second solenoid valve, a second pressure sensor, a third solenoid valve and an exit port.

Abstract: A gas-enhanced electrosurgical generator. The gas-enhanced generator has a housing, a first gas control module in the housing and configured to control flow of a first gas, a second gas control module in the housing and configured to control flow of a second gas, a high frequency power module, and a controller, processor or CPU within the housing and configured to control the first gas control module, the second gas control module and the high frequency power module. The first gas and second gas may be any of CO2, argon and helium or another gas. The gas-enhanced electrosurgical generator may have a third gas control module in the housing and configured to control flow of a third gas and a third connector secured on an exterior of the housing.

Abstract: A multi-functional electrosurgical plasma accessory having a handpiece and an extendable probe assembly. The extendable probe assembly has a shaft member, a tube, an electrode, a spacer and a collet. The shaft member and tube each may be formed of a plurality of structures assembled together, each may be of a single unitary design, or both together may be of a single unitary design. The shaft member has an interior channel, a distal end and a proximal end comprised of a neck portion at the distal end of the shaft member, a grip. The elongated portion of the shaft is movable within the spacer between a first position in which a portion of a distal end of the electrode extends out of the tube and a second portion in which the distal end of the electrode does not extend out of the tube.

Abstract: An integrated gas-enhanced electrosurgical generator. The generator comprises a high frequency power module, a low frequency power module and a gas module. The high frequency power module adapted to generate an electrical energy having a band of frequencies centered around a first frequency, wherein the electrical energy has a first power as the first frequency and a second power lower than the first power at a second frequency lower than the first frequency. The low frequency power module having an input connected to an output of the high frequency module. The low frequency module comprises a resonant transformer comprising a ferrite core, a primary coil and a secondary coil, the secondary coil having a larger number of turns than the primary coil, wherein the resonant transformer has a resonant frequency equal to the second frequency. The gas module is adapted to control a flow of an inert gas.

Abstract: An integrated gas-enhanced electrosurgical generator. The generator comprises a high frequency power module, a low frequency power module and a gas module. The high frequency power module adapted to generate an electrical energy having a band of frequencies centered around a first frequency, wherein the electrical energy has a first power as the first frequency and a second power lower than the first power at a second frequency lower than the first frequency. The low frequency power module having an input connected to an output of the high frequency module. The low frequency module comprises a resonant transformer comprising a ferrite core, a primary coil and a secondary coil, the secondary coil having a larger number of turns than the primary coil, wherein the resonant transformer has a resonant frequency equal to the second frequency. The gas module is adapted to control a flow of an inert gas.

Abstract: An electrosurgical method and device for simultaneously cutting and coagulating tissue with an electrosurgical device having an electrode and a channel wherein said channel has a port near a proximal end of said electrode, wherein the method comprises the steps of causing an inert gas to flow through said channel and exit said port, applying high-frequency energy to said electrode while said inert gas flows through said channel, wherein said high-frequency energy applied to said electrode continuously plasmatizes inert gas exiting said port, initiating an electrical discharge from said electrode through said continuously plasmatized inert gas to said tissue, cutting tissue with said electrode, maintaining said electrical discharge from said electrode through said plasmatized inert gas while cutting tissue with said electrode to cause coagulation of said tissue simultaneously with said cutting.

Abstract: A method for manufacturing plasma-activated saline for treatment of cancer cells. The method comprises the steps of immersing a cathode in saline solution in a container, positioning an anode at a fixed distance from a surface of said saline solution in said container and applying electrical energy to said anode for a fixed period of time, wherein said fixed distance and said fixed period of time are selected to cause a plasma self-organized pattern at a surface of said saline solution with an atmospheric discharge between said anode and said cathode.

Abstract: An attachment for a gas-assisted electrosurgical device. The attachment has a housing having a channel within it, an electrosurgical blade and an electrical connector. The electrosurgical blade has a conductive member comprising an elongated distal portion and a proximal portion, the distal portion having a width greater than a width of the proximal portion, the width of the distal portion being at least three times the thickness of the distal portion, and a coating on at least a portion of said conductive member.

Abstract: A cold plasma accessory having a hand piece having within in it flexible tubing, wiring, a PCB board connected to the wiring, and a conductive connector tube electrically connected to the PCB board, the conductive connector tube having an inner channel, a rigid tube extending from the distal end of the hand piece, and an electrode within the rigid tube. The electrode comprises a conductive connector having a contact surface contacting the conductive connector tube, a distal end surface facing away from the conductive connector tube, and a channel extending through a center of the conductive connector, the channel being fluidly connected to the flexible tubing, the distal end surface of the conductive connector being outside of the channel in the conductive connector, and a conductive wire connected to the distal end surface of the conductive connector.

Abstract: A gas control module for a gas-enhanced electrosurgical system. The gas control module has an inlet port, a first solenoid valve connected to said inlet port, a first pressure sensor, a first pressure regulator, a first flow sensor, a first proportional valve, a second flow sensor, a second solenoid valve, said second solenoid valve being a 3-way valve, a vent connected to said second solenoid valve, a second pressure sensor, a third solenoid valve and an exit port.

Abstract: A method for manufacturing plasma-activated saline for treatment of cancer cells. The method comprises the steps of immersing a cathode in saline solution in a container, positioning an anode at a fixed distance from a surface of said saline solution in said container and applying electrical energy to said anode for a fixed period of time, wherein said fixed distance and said fixed period of time are selected to cause a plasma self-organized pattern at a surface of said saline solution with an atmospheric discharge between said anode and said cathode.

Abstract: A device uses cold plasma to treat cancerous tumors. The device has a gas supply tube with a delivery end. The gas supply tube is configured to carry a gas to the delivery end. A syringe is provided having an opening. The syringe is connected to the supply tube and configured to carry the gas to the opening. A first electrode is positioned inside said syringe, and a second electrode is positioned adjacent to the opening. The first and second electrodes excite the gas to enter a cold plasma state prior to being discharged from the opening of the syringe. An endoscopic tube can be used instead of the syringe. An exhaust tube can be provided to remove gas introduced into the body cavity by the cold plasma jet.

Abstract: An electrosurgical method and device for simultaneously cutting and coagulating tissue with an electrosurgical device having an electrode and a channel wherein said channel has a port near a proximal end of said electrode, wherein the method comprises the steps of causing an inert gas to flow through said channel and exit said port, applying high-frequency energy to said electrode while said inert gas flows through said channel, wherein said high-frequency energy applied to said electrode continuously plasmatizes inert gas exiting said port, initiating an electrical discharge from said electrode through said continuously plasmatized inert gas to said tissue, cutting tissue with said electrode, maintaining said electrical discharge from said electrode through said plasmatized inert gas while cutting tissue with said electrode to cause coagulation of said tissue simultaneously with said cutting.