A surgical instrument including an end effector that has a selectively reciprocatable implement movably supported therein. The implement is selectively advanceable in a distal direction upon application of a rotary actuation motion thereto and retractable in a proximal direction upon application of a rotary retraction motion thereto. An elongate shaft assembly is coupled to the end effector and is configured to transmit the rotary actuation motion and rotary retraction motion to the reciprocatable implement from a robotic system that is configured to generate the rotary actuation motion and said rotary retraction motion.

Surgical instruments with articulatable surgical end effectors and rotary driven flexible drive members.

A surgical instrument navigation system and method of use is provided that visually simulates a virtual volumetric scene of a body cavity of a patient from a point of view of a surgical instrument residing in the cavity of the patient, wherein the surgical instrument, as provided, may be a steerable surgical catheter with a biopsy device and/or a surgical catheter with a side-exiting medical instrument, among others. Additionally, systems, methods and devices are provided for forming a respiratory-gated point cloud of a patient's respiratory system and for placing a localization element in an organ of a patient.

A system and associated method for manipulating tissues and anatomical or other structures in medical applications for the purpose of treating diseases or disorders or other purposes. In one aspect, the system includes a delivery device including a flexible portion that is suited to access target anatomy. The flexibility of an elongate portion of the delivery device can be varied. Additionally, the delivery device can include structure that maintains the positioning of the delivery device in patient anatomy.

A method, apparatus and computer readable medium for schematically representing a spatial position of an instrument used in a robotic surgery system is disclosed. The instrument includes an end effector coupled to a positioning device for spatially positioning the end effector in a surgical workspace in response to input signals generated by movement of a hand controller of an input device in an input device workspace. The method involves causing a processor circuit to calculate a current three-dimensional spatial position of the instrument within the surgical workspace for current input signals received from the input device. The method also involves causing the processor circuit to generate display signals for displaying a graphical depiction of the surgical workspace on a display in communication with the processor circuit, the graphical depiction including a planar representation includes an instrument movement region having a boundary indicating limitations to transverse movement of the instrument within the surgical workspace, and a two-dimensional projection of the current spatial position of the positioning device and the end effector onto the planar representation.

An example medical system includes a medical device configured to join the edges of the leaflets together, an elongate body configured to be navigated through vasculature to a heart valve of patient, and a plurality of tissue engagement devices extending from a distal end of the elongate body, each tissue engagement device comprising at least one clamp configured to capture leaflets of the heart valve.

Provided is a medical device comprising a handle comprising a distal hub, a proximal hub, and a middle hub disposed between the distal hub and the proximal hub. The medical device may comprise an outer sheath coupled with the distal hub, a basket configurable in a deployed state and an undeployed state, and a jet tube shaft coupled with the proximal hub, the jet tube shaft coaxial to the outer sheath. The jet tube shaft may comprise a jet tube comprising an aperture configured to expel a fluid, a jet tube lumen sized to accept the jet tube, and an evacuation lumen.

A coil structure used in an endoscope includes a coil tube formed by densely winding a wire rod, both ends of the coil tube being fixed, a first contact surface formed on one surface of the wire rod on a distal end side, and a second contact surface formed on the other surface of the wire rod on a proximal end side, the first contact surface coming into contact with the second contact surface. The first contact surface is formed as a convex curved surface arcuate in cross section, a curvature center of which is located further on an inner side than an outer circumferential portion of the coil tube. For the convex curved surface, a curvature radius larger than a radius of the coil tube and smaller than a curvature radius during maximum bending of an insertion section is set.

A robotic system comprises an instrument including proximal distal sections. The distal section comprises a steerable segment and a distal tip. The instrument also includes a main lumen and a pull wire. The system also comprises a sensor to detect a position of the distal tip of the instrument and a computing device that causes the system to record a position of a working configuration of the distal tip, determine, based on a sensor signal, a movement of the distal tip in response to insertion of a probe into the main lumen, and generate a control signal based on the determined movement. The system also comprises a drive interface connected to the pull wire at the proximal section of the instrument. The drive interface adjusts a tensioning of the pull wire based on the control signal to return the distal tip towards the working configuration recorded before the movement occurred.

An implantable device for optically stimulating a brain of a human being or animal, including: a multi-channel biocompatible catheter including a plurality of channels extending substantially parallel to each other relative to a longitudinal axis of the multi-channel catheter; a light guide, extending into one channel, for optically stimulating the brain, the multi-channel catheter acting as a sheath totally enveloping the light guide; a functional element, extending into another channel, to measure light injected into a surrounding medium at a distal end of the light guide and/or an element acting on the shape of the multi-channel catheter.