Various embodiments of the systems, methods and devices are provided for breaking up calcified lesions in an anatomical conduit. More specifically, an electrical arc is generated between two spaced-apart electrodes disposed within a fluid-filled balloon, creating a subsonic pressure wave. In some embodiments, the electrodes comprise a plurality of points that allow the electrical arc to form at any one of the plurality of points to, among other things, extend the electrode life.

Various embodiments of the systems, methods and devices are provided for breaking up calcified lesions in an anatomical conduit. More specifically, an electrical arc is generated between two spaced-apart electrodes disposed within a fluid-filled balloon, creating a subsonic pressure wave. In some embodiments, the electrodes comprise a plurality of points that allow the electrical arc to form at any one of the plurality of points to, among other things, extend the electrode life.

Various embodiments of the systems, methods and devices are provided for breaking up calcified lesions in an anatomical conduit. More specifically, an electrical arc is generated between two spaced-apart electrodes disposed within a fluid-filled balloon, creating a subsonic pressure wave. In some embodiments, the electrodes comprise a plurality of points that allow the electrical arc to form at any one of the plurality of points to, among other things, extend the electrode life.

A robotic surgical system is described. In some embodiments, the robotic surgical system includes a physician-side shaft controlled by a physician, the movement of which is tracked by a plurality of physician-side balls and transmitted to a plurality of patient-side balls, which in turn, move a patient-side shaft and attached surgical device, such as a stent retriever.

A robotic surgical system is described. In some embodiments, the robotic surgical system includes a physician-side shaft controlled by a physician, the movement of which is tracked by a plurality of physician-side balls and transmitted to a plurality of patient-side balls, which in turn, move a patient-side shaft and attached surgical device, such as a stent retriever.

Devices and methods for the treatment of chronic total occlusions are provided. One disclosed embodiment comprises a method of facilitating treatment via a vascular wall defining a vascular lumen containing an occlusion therein. The method includes inserting an intramural crossing device into the vascular lumen, positioning at least the distal tip of the crossing device in the vascular wall, advancing an orienting device over the crossing device such that an orienting element of the orienting device resides in the vascular wall, inserting a reentry device, and re-entering the true vascular lumen.

An endoscopic tissue separator surgical device and method. The device has a multi-lumen shaft having proximal and distal ends, a central lumen for accepting an endoscope, and at least two fluid lumens, with a head coupled to the distal end of the shaft and a handle coupled to the proximal end. The head has an endoscope port and at least two fluid ports whose centers are all disposed along an arcuate line of curvature, while the handle has at least two fluid supply ports. Gas and fluid may be conveyed through the shaft from the handle to the head in the at least two fluid lumens separate from the lumen for accepting an endoscope. At least one lumen of the multi-lumen shaft may house a stainless steel tube with an inside diameter of sufficient size to accept an endoscope.

An endoscopic tissue separator surgical device and method. The device has a multi-lumen shaft having proximal and distal ends, a central lumen for accepting an endoscope, and at least two fluid lumens, with a head coupled to the distal end of the shaft and a handle coupled to the proximal end. The head has an endoscope port and at least two fluid ports whose centers are all disposed along an arcuate line of curvature, while the handle has at least two fluid supply ports. Gas and fluid may be conveyed through the shaft from the handle to the head in the at least two fluid lumens separate from the lumen for accepting an endoscope. At least one lumen of the multi-lumen shaft may house a stainless steel tube with an inside diameter of sufficient size to accept an endoscope.

The cannula (1) comprises a tube (2) with a front end (4) at which there is provided at least one suction opening (10), and with a back end (3) intended to be connected to a source of vacuum; in the tube (2) there being defined at least one longitudinal flow conduit (8, 9) for the aspirated material; and an imaging apparatus (11, 12) capable of supplying first signals or data allowing the generation of a visual representation of the environment in close proximity to the front end of the tube (2) of the cannula (1) down to a first depth or distance, and second signals or data allowing the generation of a visual representation of the environment around the front end of the tube (2) of the cannula (1) down to a second depth or distance, greater than the said first depth or distance.

The cannula (1) comprises a tube (2) with a front end (4) at which there is provided at least one suction opening (10), and with a back end (3) intended to be connected to a source of vacuum; in the tube (2) there being defined at least one longitudinal flow conduit (8, 9) for the aspirated material; and an imaging apparatus (11, 12) capable of supplying first signals or data allowing the generation of a visual representation of the environment in close proximity to the front end of the tube (2) of the cannula (1) down to a first depth or distance, and second signals or data allowing the generation of a visual representation of the environment around the front end of the tube (2) of the cannula (1) down to a second depth or distance, greater than the said first depth or distance.