An endoscopy device is configured with a flexible cannula or tube for nasal insertion and has multiple parallel and adjacent lumens that provide sub-chambers configured to provide means to diagnose and treat Barrett's esophagus, such as by spray cryo-therapy with no further insertion of tubes. The lumens are configured to impart a small diameter with sufficient flexibility for nasal insertion into a patient's esophagus and accommodate a means any treatment modality. In the case of cryo-therapy, a lumen provides gas pressure relief, and is along the tube, with separate lumens for the delivery of a liquid freezing agent and an imaging means, which includes a source of illumination. Outer lumens may support guide wires used to steer the tube tip and aim the camera to determine the where to immobilize tip before the start of the treatment and/or to correct strictures formed in prior procedures.

Provided is an ultrasonic treatment apparatus provided with: a treatment-ultrasonic-wave irradiator that irradiates the biological tissue with focused ultrasonic waves, thus heating the vicinity of a focal point of the focused ultrasonic waves at a deep portion of the biological tissue to a temperature that is equal to or greater than a thermal-denaturation temperature of the biological tissue; and a pre-heating-energy irradiator that irradiates the biological tissue with energy waves, thus heating the vicinity of the focal point to a temperature that is less than the thermal-denaturation temperature, wherein the pre-heating-energy irradiator irradiates the biological tissue with the energy waves from a direction different from the direction in which the treatment-ultrasonic-wave irradiator irradiates with the focused ultrasonic waves.

An ablation assembly includes a handle, a catheter assembly and a connector locking assembly. The catheter assembly includes: a catheter shaft, a balloon and a connector at the distal and proximal ends of the catheter shaft, and a delivery tube extending between there between. The connector includes a connector body secured to the proximal end and a plug secured to the delivery tube, the plug and delivery tube movable axially and rotationally. The handle includes an open portion receiving the plug and the connector body. The connector locking assembly includes: means for simultaneously automatically connecting the plug and the connector body to the handle to place the connector in a load state prior to use, and means for automatically releasing the connector body and thereafter the plug from the handle to place the connector in an eject state to permit the connector to be removed from the handle.

A method in which a location is determined on the skin that is proximate to a sensory nerve that is associated with a painful condition. At least one needle of a cryogenic device is inserted into the location on the skin such that the needle is proximate to the sensory nerve. The device is activated such that the at least one needle creates a cooling zone about the sensory nerve, thereby eliminating or reducing severity of the painful condition.

An intravascular catheter is provided, including a flexible elongate body; an expandable element positioned on the elongate body; a substantially linear thermal segment located proximally of the expandable element, the thermal segment defining a first flexibility, where the thermal segment is positioned between two portions of the catheter body each including a flexibility less than that of the thermal segment; a first fluid flow path in fluid communication with the expandable element; and a second fluid flow path in fluid communication with the thermal segment.

A cryosurgery system for application of medical-grade liquid nitrogen to a treatment area via a small, low pressure, open tipped catheter. The system includes a console, including a touch panel computer, a cryogen module, a suction module and an electronics module, and a disposable spray kit. Features include optional low cryogen flow setting to reduce the cryogen flow rate by 50%, improved cryogen flow consistency reducing pressure pulses and peaks, an integrated suction pump for improved consistency and self-checks, specified vent tube areas and corresponding maximum expected pressures during cryospray procedure; optional pressure sensing capability to monitor pressure during a treatment, and novel catheter designs of multilayer and flexible construction providing a variety of spray patterns.

Devices, systems, and methods for degassing fluid prior to applying fluid to a treatment site during ablation therapy are provided. In one embodiment, an ablation system can include an elongate body, an ablation element, a heating assembly, and a fluid source. Fluid in the fluid source can be at least partially degassed prior to being provided as part of the system, or, in some embodiments, a degassing apparatus can be provided that can be configured to degas fluid within the system prior to applying the fluid to the treatment site. The degassing apparatus can include one or more gas-permeable and fluid-impermeable tubes disposed therein, which can allow gas to be removed from fluid passing through the apparatus. Other exemplary devices, systems, and methods are also provided.

A method of producing an array of sharp tips including a biocompatible coating, wherein the biocompatible coating is thicker at a sharp end of the sharp tips than at a broader section of the sharp tips, the method including providing an array of sharp tips, and coating the sharp end of the sharp tips differentially from coating the broader section of the sharp tips. A method of treating skin including producing a hollow in the skin by heating and mechanically compressing epidermis while retaining a covering of stratum corneum. A method of treating tissue including heating a tip to a temperature suitable for producing a crater in the tissue, advancing the tip toward the tissue, detecting when the tip comes into contact with the tissue by detecting a change in mechanical resistance to the advancing, and measuring the mechanical resistance to the advancing. Related apparatus and methods are also described.

Methods, apparatuses and systems are provided for non-invasive delivery of microwave therapy. Microwave energy may be applied to epidermal, dermal and subdermal tissue of a patient to achieve various therapeutic and/or aesthetic results. In one embodiment, the microwave energy is applied to a target tissue via an energy delivery applicator connected to an energy generator. The energy delivery applicator may comprise one or more antennas, including monopole, dipole, slot and/or waveguide antennas (among others) that are used to direct the microwave energy to the target tissue. The energy delivery applicator may also comprise a cooling element for avoiding thermal destruction to non-target tissue and/or a suction device to localize thermal treatment at specific portions of a skin fold.

Compositions, systems, devices, and methods for performing precise chemical treatment of tissues are disclosed. Systems, devices, and methods for administering a chemical agent to one or more a precise regions within a tissue mass are disclosed. Compositions, systems, devices, and methods for treating targeted regions within a tissue mass are disclosed. Systems, devices, and methods for identifying, localizing, monitoring neural traffic in the vicinity of, quantifying neural traffic in the vicinity of, and mapping neural traffic near targeted regions within a tissue mass are disclosed.