This adhesion prevention film for medical devices is a single-layer or multilayer adhesion prevention film that is formed on the surface of a medical device. This adhesion prevention film for medical devices comprises an outermost layer that contains a plurality of conductive particles and a resin having a continuously usable temperature of 200° C. or higher. The surface of the outermost layer is provided with recesses and projections by having parts of the plurality of conductive particles exposed from the resin.

A medical apparatus includes a first jaw; a second jaw that opens and closes with the first jaw; a shaft to which the second jaw is pivotably attached; and a sliding member provided between the second jaw and the shaft, abutted to each of the second jaw and the shaft, and configured to be slidable with respect to at least one of the second jaw or the shaft.

Disclosed are a detection mechanism, a radio-frequency ablation catheter, and a radio-frequency ablation system. The radio-frequency ablation catheter includes a handle portion, a needle tube portion, a central electrode, and a detection mechanism. The needle tube portion includes a first tube and a second tube, the handle portion includes a cylinder sleeve and a sliding button, the central electrode includes an electrode body, an electrode wire, and an electrode connector, and the detection mechanism includes a fixing base, a pulling string, a connecting base, and multiple detection electrodes arranged in a claw-shaped configuration. A distal end of the pulling string is fixed to the fixing base, and a proximal end of the pulling string is fixed to the sliding button; and the detection electrodes are fixed to the fixing base, and slidably provided in the connecting base.

An electrosurgical apparatus is provided including a housing, a flexible shaft, and a distal tip. The housing may further be coupled to an electrosurgical generator and gas supply. The distal tip of the electrosurgical apparatus may be grasped by a grasping tool, such that the orientation and position of the distal tip relative to the housing may be manipulated to achieve a plurality of positions. The electrosurgical apparatus provides electrosurgical energy and inert gas to an electrode within the distal tip of the electrosurgical apparatus to generate a plasma beam. In one aspect, the electrode is a retractable blade such that the electrosurgical apparatus can be used for mechanical and electrosurgical cutting during surgery when the electrode is in an extended position and for cold plasma applications during surgery when the electrode is in a retracted position.

Methods, devices, and systems employ cryolysis of oropharyngeal adipose tissues to selectively remove fat cells from the tissues causing obstructive sleep apnea. In various embodiments, a chilled liquid—e.g., a liquid or air—is applied to the target tissue at a temperature and for a duration sufficient to cause cryolysis.

A cooled radio-frequency (RF) ablation probe is provided. The RF ablation probe includes a first tubular portion defining at least part of an internal cavity for circulating coolant through the cooled RF ablation probe; a second tubular portion surrounding the first tubular portion along a first portion of the length of the cooled RF ablation probe; a third tubular portion surrounding the second tubular portion along a second portion of the length of the cooled RF ablation probe; and a fourth tubular portion surrounding the third tubular portion along a third portion of the length of the cooled RF ablation probe. A gap is defined between the third tubular portion and the fourth tubular portion that can be filled with air or a vacuum can be formed in the gap to insulate one or more thermocouples attached to the fourth tubular portion from the coolant in the internal cavity.

A jaw member of an electrosurgical instrument includes a U-shaped structural frame defining a cavity therein and extending therealong configured to receive at least a portion of an insulative spacer therein such that the insulative spacer extends distally therefrom. The insulative spacer includes a tapered fin at a distal end thereof. A tissue treating plate is disposed on the face of the insulative spacer, the tissue treating plate is adapted to connect to a source of energy to treat tissue therewith. The tapered fin is configured to extend to and support a distal end of the tissue treating plate.

Ablation systems and methods of the present disclosure include a catheter including one or more image sensors. The one or more image sensors can facilitate, for example, positioning an ablation electrode at a treatment site of an anatomic structure and, additionally or alternatively, can facilitate controlling delivery of therapeutic energy to a treatment site of an anatomic structure.

Systems and methods for cutting tissue using a transcatheter approach are disclosed. In some examples, the systems and methods are implemented as part of a delivery system that includes an implant with a support structure and a cutting element coupled to the support structure, such that the cutting element configured to cut tissue.

A plasma scalpel head for spinal percutaneous puncture and an operation method of the plasma scalpel head for spinal percutaneous puncture are provided. The plasma scalpel head for spinal percutaneous puncture includes a needle core. The needle core includes a main ablation electrode and a needle core body. The main ablation electrode is arranged at an ablation end of the plasma scalpel head. The needle core body is externally provided with a first insulating layer. The first insulating layer is externally provided with a reflow electrode layer. A part of the first insulating layer that is not covered with the reflow electrode layer forms a main ablation electrode protection insulating ring. The reflow electrode layer is provided thereon with a second insulating layer, and a part of the reflow electrode layer that is not covered with the second insulating layer forms a reflow electrode.