Devices for approximating multiple tissue edges internal to a body are disclosed.

Example embodiments relate to surgical systems. The system includes an end-effector assembly having an instrument. The system includes a first arm assembly. A distal end of first arm assembly is securable to the end-effector assembly. The system includes an elbow joint assembly. A distal end of elbow joint assembly is secured to a proximal end of first arm assembly. A proximal end of elbow joint assembly is secured to a distal end of second arm assembly. The second arm assembly includes a first elbow drive assembly. The first elbow drive assembly includes an integrated motor for driving the elbow joint assembly to pivotally move the first arm assembly relative to an axis. The second arm assembly also includes a second elbow drive assembly. The second elbow drive assembly includes an integrated motor for driving the elbow joint assembly to pivotally move the first arm assembly relative to another axis.

A tool actuation connector includes a tool activation interface, a longitudinal lock interface and a rotation lock interface. The tool actuation connector includes a latching spring, an inner sleeve and an outer sleeve. The latching spring includes a plurality of spring hooks, for coupling with the tool activation interface. The inner sleeve is operable to longitudinally move relative to the latching spring. The inner sleeve couples the latching spring to the activation interface when the inner sleeve is located over the latching spring and releases the latching spring from the activation interface when the inner sleeve moves away from the latching spring toward the proximal direction. The outer sleeve is rotationally locked with the inner sleeve and is operable to longitudinally move relative to the inner sleeve. The outer sleeve is further operable to rotationally lock with the tool via the rotation lock interface.

Example embodiments relate to surgical devices, systems, and methods. The system includes a port assembly and a surgical arm inserted through the port assembly. The surgical arm includes first and second segments, first joint assembly pivotally coupling the first and second segments, end effector assembly, and second joint assembly pivotally coupling the second segment and end effector assembly. The surgical system includes a joint driving assembly having a joint driving cable and lever. A proximal end of the joint driving cable is connected to the lever and a distal end of the joint driving cable is connected to a proximal end of the second segment. The first joint driving subassembly is configurable to pivotally move the second segment. The surgical system includes a telescopic driving assembly configured to provide a linear displacement of the first segment of the surgical arm and the joint driving assembly relative to the port assembly.

Disclosed herein are embodiments of a minimally-invasive surgical system and methods of use which can mimic a mosquito proboscis to efficiently penetrate tissue. The delivery system can utilize a plurality of modular strut instruments to create a working tissue canopy and apply any number of surgical actions to a target tissue.

Embodiments relate to surgical devices, systems, and methods. The system includes a port assembly and surgical arm assembly. The port assembly includes a main body having a main channel. The main channel includes a left channel portion, right channel portion, left anchor channel portion, and right anchor channel portion. The left channel portion is shaped in such a way that, when a surgical arm of the surgical arm assembly is inserted through the left channel portion, a movement of the surgical arm is restricted to be a movement within the left channel portion and along a first central axis. The right channel portion is shaped in such a way that, when the surgical arm is inserted through the right channel portion, a movement of the surgical arm is restricted to be a movement within the right channel portion and along a second central axis.

A surgical tool according to one or more embodiment may include: an end effector; an elongate element that drives the end effector; a hollow shaft that includes a proximal end portion and a distal end portion which is coupled to the end effector; a driving member which the elongate element led via the shaft is wound on; a guide pulley that is disposed between the proximal end portion of the shaft and the driving member and guides the elongate element; and a tension pulley that is disposed between the proximal end portion of the shaft and the guide pulley and biases the elongate element.

Example embodiments relate to surgical devices, systems, and methods. The system includes a surgical arm having segments and joints. A first joint couples first and second segments. A second joint couples second segment to an end effector joint. End effector joint couples second joint to an end effector. A joint driving assembly includes first joint driving subassembly having a first joint driving subsystem and first joint driving cables. First joint driving subsystem is configurable to move second segment relative to first segment. A second joint driving subassembly includes second joint driving subsystem and second joint driving cables. Second joint driving subsystem is configurable to move end effector joint relative to second segment. An end effector joint driving subassembly includes end effector joint driving subsystem and end effector joint driving cables. End effector joint driving subsystem is configurable to move end effector relative to second joint.

Trocar components and methods of use are described, wherein the trocar components are configured to provide access to intraperitoneal space via the rectouterine pouch to surgical tools, which optionally include one or more surgical robot members. The surgical tools are optionally 5 mm or more in diameter. In some embodiments, a cannula part has a lumen sized to provide to a plurality of the surgical tools simultaneous transvaginal access to the intraperitoneal space via the rectouterine pouch. In some embodiments, an incision sized to receive a distal aperture of the cannula is created, optionally using one or two dilators. The dilators are sized to create (optionally starting from a puncture by a needle 2 mm in diameter or less) an oblong aperture. In some embodiments, the oblong aperture is at least twice as wide across a long diameter as across a short diameter.

The embodiments disclosed herein relate to various medical device components, including components that can be incorporated into robotic and/or in vivo medical devices. Certain embodiments include various modular medical devices for in vivo medical procedures.