A polyp removal device comprises an outer tubular body; an inner tubular body being movable with respect to the outer tubular body; a handle; an actuation member configured to cause movement of the inner tubular body with respect to the outer tubular body when the actuation member is moved with respect to the handle; a vacuum port for coupling thereto of a vacuum source; and an opening near a distal end of the polyp removal device, the opening configured to allow fluid communication between an environment external to the polyp removal device and the lumen of the inner tubular body, wherein a size of the opening is variable based on the movement of the inner tubular body with respect to the outer tubular body.

The present disclosure is directed to a medical device. Systems and methods are provided for accessing and visualizing the pancreatico-biliary system. The medical device may include a guide catheter with a first lumen and a second lumen. A first elevator may be disposed in the first lumen, wherein the first elevator is movable relative to the first lumen for elevating a first tool insertable into the first lumen. A second elevator may be disposed in the second lumen, wherein the second elevator is movable relative to the second lumen for elevating a second tool insertable into the second lumen.

The invention comprises a system to alleviate conditions such as prostate cancer, benign prostatic hyperplasia (BPH), and the like. The system includes a probe for mechanically cutting tissue and a device for simultaneously tamponading, inducing hemostasis, and dilating a plurality of lumens while minimizing inflammation. The tamponading device has a plurality of balloons configured for inflation with a coolant fluid. Other components of the system include a luminally protective sheath, a microscopic end cauterizing probe, a surgical console, an identification-sensitive self-sealed cassette, and a plurality of flexible tubing lines with pinch valves thereon.

Medical devices for shearing tissue into small pieces are provided. One exemplary device includes oppositely rotating first and second rotatable members, each located at least partially within a distal housing. The device also includes first and second circular axle portions, and first and second blades that are directly adjacent to one another and positioned to partially overlap such that tissue may be sheared between the first and second blades, between the first blade and the second axle portion and between the second blade and the first axle portion. The rotatable members are configured to engage tissue from a target tissue site with teeth of the first and second blades, rotate towards one another and inwardly to direct tissue from the target tissue site through a tissue engaging opening and into an interior portion of the distal housing. Methods of fabricating and using the above device are also disclosed.

A method treating a deficient native mitral valve includes advancing the distal end portion of a delivery catheter into a heart, wherein the delivery catheter contains a support band stretched into a linear form, wherein the support band comprises a shape-memory material, and then ejecting the support band from the distal end portion of the delivery catheter such that the support band transitions from the linear form to a curved shape extending around native leaflets of the native mitral valve.

Ablation devices useful for removing nerve and soft tissue via a minimally invasive procedure to alleviate pain are provided. The device comprises a cannula having an opening at a distal tip of the cannula, the opening configured for suction of a surgical site, and a movable tissue capture member having a portion disposed within the opening or adjacent to the cannula, the movable tissue capture member configured to capture tissue when moved in a first position. Methods for ablating nerve and/or soft tissue utilizing the ablation devices are also provided.

The present invention relates to medical and veterinarian rotary tools. In particular, the present invention relates to a rotary tool for the taking of biopsies and drilling into tissues such as nail and bone. More particularly, the present invention relates to nail care devices and procedures to improve the condition of nails, especially relating to the treatment of fungal infections. Onychomycosis is a fungal infection that causes the toenails and/or fingernails to thicken, discolour, and split. Onychomycosis can result in permanent nail deformity. The disease can have a significant impact on a patient's quality of life arising from psychosocial issues e.g., due to concern regarding the appearance of one's toenails and fingernails, and may cause pain associated with wearing shoes. The present invention seeks to provide an improved mechanical system for use in the treatment of onychomycosis and other nail bed conditions, and other animal keratin, bone and cartilaginous conditions.

A medical device system configured to dynamically control a shaver window opening via controlling positioning of an opening in an inner drive shaft relative to an opening in an outer housing based on continuously tracking the motor is disclosed. The medical device system may include a shaver at a distal end and an aspiration system configured to aspirate material through the inner drive shaft. A processor of the medical device system may control rotational motion of the inner drive shaft based on continuously sensing the position of the opening in the inner drive shaft to reduce clogs and increase cutting effectiveness of the system. By continuously monitoring the medical device system, the processor can correct out of phase conditions in oscillation mode to prevent poor cutting conditions. The processor can also dynamically determine a reversal position on the opening in the inner drive shaft to create a desired cutting action.

The present technology is directed generally to devices, systems, and methods for capturing and cutting fibrous and trabeculated structures (such as synechiae) in vessel lumens. In one embodiment, the present technology includes an intraluminal tissue modifying system configured to capture the fibrous structures, put the fibrous structures in tension, and controllably cut through the fibrous structures without applying appreciable additional force to the vessel wall. The system may include an expandable capture device and a cutting device.

A tissue cutting device has an outer sleeve with a distal window and an inner cutting sleeve which moves past the window to cut tissue. The inner cutting sleeve has a lumen which may have a larger proximal diameter than distal diameter. A perimeter of the window may comprise a dielectric material. A distal edge of the inner sleeve may be displaced inwardly.