An end effector for a surgical clip applier includes a housing, and jaws that include opposed first and second jaw members each comprising an independent structure movable relative to the other, the first jaw member defining a first inner surface and the second jaw member defining a second inner surface opposite the first inner surface. An actuation mechanism is arranged within the housing and is operable to move the jaws between an open position and a closed position, the actuation mechanism including a linear drive that provides transition pins engageable with angled slots defined in the first and second jaw members. Linear movement of the linear drive moves the jaws between the open and closed positions, and the first and second inner surfaces remain substantially parallel to each other as the jaws move between the open and closed positions.

A force transmission mechanism includes a force adjuster that receives a driving force and that is configured to change a force transmission efficiency, and also includes a driving member that is configured to connect an end effector and the force adjuster via a joint section and transmit the driving force. The force adjuster converts the driving force into a linear force via a rotational force, and increases the conversion efficiency from the driving force to the linear force such that an amount of increase in the force transmission efficiency increases with increasing displacement amount of the driving member when the driving member is displaced in accordance with flexing or curving of the joint section.

A surgical instrument for use with a robotic manipulator includes an end effector assembly having one or two end effector members, each having a distal treatment end, a proximal end, and a tendon pass-through. Each end effector member is sandwiched between a corresponding pair of pulley members that, when assembled define an annular tendon pathway that is between the pulley members and that is aligned with the pass-through. For each end effector member, a tendon having a distal loop portion ends through the tendon pass-through, with its legs passing proximally from the pass-through, extending in opposite directions around the tendon pathway and proximally through the instrument's shaft.

Medical systems, devices and methods are provided for engaging tissue, e.g. for clipping tissue, closing a perforation or performing hemostasis. Generally, the medical system including a housing, first and second jaws rotatable relative to the housing, a driver, and an elongate drive wire. The elongate drive wire may be disconnected from the driver, first and second jaws, and the housing, which are left in vivo engaged with the tissue.

A surgical stapling system for treating tissue of a patient is disclosed. The surgical stapling system comprises an end effector, a firing member, a motor, a RF transceiver configured to transmit RF signals, and a sensing array. The end effector comprises an elongate channel, an anvil rotatable relative to the elongate channel from an open position toward a closed position, and a staple cartridge removably positioned in the elongate channel. The staple cartridge comprises a plurality of staples removably stored therein. The firing member is movable between an unfired position and a fired position. The staples are deployed from the staple cartridge based on the firing member being moved toward the fired position. The motor is configured to drive the firing member toward the fired position. The sensing array is configured to sense compression of the tissue, properties of the tissue, and a presence of metallic elements within the tissue.

The present disclosure provides a heart valve repair method, comprising: advancing a distal end of a suture implanting apparatus from an outside of a body through a transapical approach into a left ventricle or a right ventricle of a heart; holding each leaflet of a heart valve with the distal end of the suture implanting apparatus; implanting at least one suture into the leaflet; withdrawing the suture implanting apparatus from the body; advancing a distal end of a suture locking apparatus from the outside of a body through a transapical approach into the corresponding left ventricle or the corresponding right ventricle; using the suture locking apparatus to lock the plurality of sutures; and withdrawing the suture locking apparatus from the body. The heart valve repair method has a simple surgical procedure, a low degree of patient trauma, and a high success rate of surgery.

A surgical device includes a forceps device, driven portions to which a driving force is transmitted from outside the surgical device, plural wires, each being fixed to one of the driven portions and transmitting respective movements of the driven portions to the forceps device. The forceps device includes grasping portions that may be opened and closed by a movement of a first wire of the plural wires, and a joint portion that may be bent by a movement of one or more second wires of the plural wires.

A surgical device comprising: (1) a handpiece having a distal end portion; (2) a tubular member extending from the distal end portion, the tubular member having a lumen therethrough, the lumen comprising: (a) a proximal lumen portion, (b) a distal lumen portion, (c) a first central lumen portion, and (d) a second central lumen portion, the second central portion being located between the proximal lumen portion and the first central lumen portion, wherein the distal lumen portion diverges as the distal lumen portion extends away from the first central lumen portion in a distal direction, and the second central lumen portion diverges as the second central lumen portion extends away from the first central lumen portion in a proximal direction and: wherein the tubular member has wall with a substantially uniform thickness about the first central lumen portion.

A surgical instrument comprising a staple firing drive and an articulation drive is disclosed. The articulation drive is selectively engageable with said firing drive such that the articulation drive is driveable by the staple firing drive. The surgical instrument further comprises a sensor system configured to assess whether the articulation drive is engaged with the staple firing drive.

A minimally invasive surgical device characterized by comprising: a manipulable handle (2) manipulated by a user inside a body cavity, a treatment part (3) that holds a specific swappable surgical instrument that is inserted into the body cavity and manipulated using the manipulable part, and a linking part (4), provided between the manipulable handle and the treatment part, for disposing the surgical instrument held by the treatment part in a desired orientation at a desired position within the body cavity. The linking part comprising: two or more connecting parts (7a, 7b, 8a, 8b) that are connected in series in the longitudinal direction of the linking part, and form a joint (7, 8) that enables rotation around the longitudinal axis or an axis orthogonal to the longitudinal axis; and a linking part control mechanism that moves the two or more connecting parts toward or away from each other to open or constrict the angle of the joint around the longitudinal axis and/or the angle thereof around an axis orthogonal to the longitudinal axis, thereby disposing the treatment part at the desired position and in the desired orientation within the body cavity.