A medical punching/cauterizing device includes a handle having a body, a cap detachably coupled to a front portion of the body, a connection terminal coupled to the body and electrically connected to a power supply means, a conductor provided in the front portion of the body and having one end electrically connected to the connection terminal, and a guide wire provided on a front portion of the handle and having one end electrically connected to the conductor.

An electrosurgical probe for ablating tissue includes an elongated shaft having an axis and a distal end. An electrically insulating housing at the distal end of the shaft has a window, and an interior channel in the shaft extends through the housing to the window. The window faces laterally relative to the axis, and a moveable member with a blade-like electrode edge is disposed within the window. A motor drives the energized electrode edge axially in the window to ablate tissue.

In one embodiment, the present disclosure relates to an electrosurgical device that includes an outer body, an inner body disposed partially within the outer body, three plates and an insulator. A first plate of the three plates includes a plurality of apertures and is positioned so that each of two projections extending from the inner body extend through a respective aperture of the plurality of apertures of the first plate. A second plate and a third plate of the three plates are both disposed on the first plate such that each of the two projections extends through an aperture of the second plate or the third plate, the second and third plates being fixed to a respective projection. The insulator is disposed around the inner body and is attached to the outer body at a first end and abuts the first plate at a second end opposite the first end.

A deployable radio-frequency (RF) ablation needle is provided. The deployable RF ablation needle is used to apply RF energy to hard and/or soft tissues to facilitate ablation thereof. Portions of the deployable RF ablation needle are configured for expansion from an undeployed configuration to a partially or completely deployed configuration via actuation by a user. The undeployed configuration of these portions of the deployable RF ablation needle affords a relatively small insertion size to facilitate insertion thereof into the hard and/or soft tissues, and the expansion of these portions from the undeployed configuration to the partially or completely deployed configuration correspondingly increases the application area of the RF energy to correspondingly increase the ablation zone afforded by use thereof.

The present disclosure provides an electrode assembly wherein an electrically conductive material is configured to extend into an insulating moulding via an opening in a wall of said moulding to electrically contact an active tip placed into the insulating moulding and thereby retain the active electrode therein, such that the height and space required to anchor the active electrode within the moulding is greatly reduced while still providing the necessary retention strength and electrical connection. As such, the electrode assembly retains and connects the active tip with a conductive element that is mounted within the insulating moulding.

An electrocautery unit for connecting to a handle of an electrocautery device, the unit comprises a body, a light unit and an electrode. The body has a body proximal end and a body distal end, and a body axis extending lengthwise along the center of the body. The body’s proximal end comprises a connecting element for connecting said body to a handle having a handle axis extending lengthwise along the center of the handle, so that said body axis is coaxial with said handle axis when said body is connected to said handle. The light unit may be constructed and arranged to emit a light having a central axis coaxial with said body axis. The electrode comprises a proximate end connected to the body distal end, and an electrode tip at a distal said. When the electrode is connected to the body, the electrode lays outside of the body axis and extends into said body axis such that the electrode tip is within said body axis, wherein said light and said electrode tip are coaxial to said body axis and said handle axis.

Disclosed are an extruded honeycomb catalyst, a process for preparing the catalyst, a method for reducing NOx in the exhaust gas from an internal combustion engine by using the catalyst, and a method for treatment of the emission gas generated from power plant comprising exposing the emission gas to the catalyst.

A medical device includes a shaft including a central lumen configured to direct a flow of fluid through the shaft, and an electrode positioned at a distal portion of the shaft. The electrode includes an electrode lumen in fluid communication with the central lumen, and the electrode lumen is configured to receive the flow of fluid from the central lumen. The electrode also includes one or more channels angled relative to the electrode lumen, and the one or more channels are in fluid communication with the electrode lumen to receive the flow of fluid from the electrode lumen. The one or more channels are configured to divert the flow of fluid from the electrode lumen toward one or more outlets laterally offset from the electrode lumen.

Systems and methods for controlling energy delivered to an area of tissue during a treatment procedure are provided. The system includes a device for delivering energy to the area of tissue; an energy generator for generating and supplying energy to the device; and a controller for controlling an amount of energy generated by the energy generator and delivered to the area of tissue by the device. Controlling the amount of energy delivered to the area of tissue alters a primary zone of the area of tissue to a first level, alters a secondary zone to a second level, alters a tertiary zone to a third level, or a combination thereof, where the first level, the second level, the third level, or a combination thereof is predetermined, and where a coverage area of the primary zone, the secondary zone, the tertiary zone, or a combination thereof is also predetermined.

A minimally invasive tissue incision system for creating joint capsulotomies and releasing/incising various tissues, tendons, and fibrous band structures is described. The system contains a penetrating needle which is retractable so as to expose a cutting element, and which may be used as a penetrating needle to pierce the skin and other soft tissue structures. The cutting element provided within the penetrating needle may be used to incise subsequent tissue structures after the initial penetration. The system facilitates such procedures by providing the cutting element with the confines of the needle which provides safe introduction of the cutting element directly to the site via the needle.