A surgical handheld instrument for grasping an object includes two lever elements, each lever element having a grip portion and a jaw portion. A lever joint connects the two lever elements rotatably to each other between their grip portion and their branch portion. Each of the two grip portions is adjoined by a respective spring portion for connecting the two grip portions such that the two lever elements are held resiliently in an open position. To create an easily manageable, elegant and releasable connection for spring ends on surgical instruments, the handheld instrument includes a hinge pin at a free end of one spring portion and a bearing eye at a free end of the other spring portion. The bearing eye has a longitudinal slit for radial insertion of the hinge pin into the bearing eye.

Medical devices for operating an end effector including a housing, a drive shaft, a drive body and a drive link. The drive shaft is moveable relative to the housing to actuate the end effector. The drive body is operably coupled to the drive shaft. The drive body includes a proximal collar and a distal collar. The drive link includes a proximal cam surface and distal cam surface, and the drive link is operatively coupled to the housing and actuatable to translate the drive shaft with respect to the housing. The proximal cam surface is configured to interface with the proximal collar when the drive link displaces proximally to translate the drive body in a proximal direction, and the distal cam surface is configured to interface with the distal collar when the drive link displaces distally to translate the drive shaft in a distal direction.

A combination medical includes a first arm and a second arm interconnected to the first arm. The first arm and the second arm are biased towards each other by a closing force. A biasing member is disposed between the first arm and the second arm. The biasing member has a first position that biases the first arm and the second arm away from each other against the closing force and a second position that does not oppose the closing force. The combination medical device may be an electrosurgical device with a mono-polar and bi-polar configuration.

A surgical forceps includes a first shaft member including a proximal portion having a handle at a proximal end thereof and a distal portion having a jaw member at a distal end thereof. The proximal and distal portions are pivotable between an aligned position and an angled position. A second shaft member includes a jaw member at a distal end thereof and a handle at a proximal end thereof. The shaft members are pivotable relative to one another between a spaced-apart position and an approximated position for moving the jaw members relative to one another between an open position and a closed position to grasp tissue therebetween. The proximal portion of the first shaft member is pivoted relative to the distal portion of the first shaft member from the aligned position to the angled position upon movement of the first and second shaft members towards the spaced-apart position.

A surgical instrument includes a first shaft, a second shaft, and a hinge. The first shaft includes a proximal handle and a distal jaw member. The second shaft includes a first segment that has a proximal handle and a second segment that has a distal jaw member. One of the first and second shafts is pivotal relative to the other to pivot the jaw members between an open configuration where the jaw members are spaced relative to one another and an activatable configuration where the jaw members are closer to one another and suitable for applying electrosurgical energy to tissue disposed therebetween. The hinge couples the first and second segments to one another. The first and second segments have a straight configuration where the first and second segments align with a longitudinal axis and a pivoted configuration where the second segment is disposed at an angle relative to the longitudinal axis.

The disclosed technology includes improved microsurgical tools providing multiple degrees of freedom at the wrist level, including roll, pitch, and grasp DOFs, a tight articulation bending radius, low radial offset, and improved stiffness. Some implementations include an end effector platform moveable along a fixed trajectory on a fictional axle so as not to interfere with a central-axis aligned working channel; a crossed-arm mechanical linkage for articulating an end-effector platform throughout a pitch DOF with an amplified pitch angle; and a partial pulley system to articulate the arms while maximizing pulley radius to shaft diameter, and permitting a constant transmission efficiency to the arms throughout the range of articulation. In some implementations, a tool shaft outer diameter may be smaller than 3 mm; a pitch DOF range may be 90, a roll DOF range may be 180, and a grasp DOF range may be 30.

The patent is relative to a new instrument for single access laparoscopy that tries to overcome the limits of the present instrumentation used in this technique, that usually allows to use only one forceps, which does not allow to keep the tissues tenses to work with the surgical instrument. To overcome this limitation, the proposed instrument presents two arms, arranged in parallel presenting a diameter equal to half of the main body in the opening direction of the same, while in the direction perpendicular to this these arms can have an higher diameter, provided its shape be entirely circumscribed by the external dimension of the initial body, and each bearing at the tip a forceps, which may be mounted directly on the arms or on two auxiliary arms. The internal mechanism allows opening the two arms, not necessarily in the plane of rotation of the control rings, while the forceps bend toward the inside, keeping their configuration, being all this controlled by a single command. Two additional commands allow then to open and close the forceps individually, and each command can be locked in any position. The forceps can be opened in any direction relative to the plane of the arms, which can also be adjustable in a particular version, as well as it is possible that one or both of the forceps are replaced by a tool of a different type. The instrument can also be made with curvature of the body opposite to that of the arms, the latter being also controlled with a further command. Finally, there are versions of different pliers with robotic motion control and implementation.

A surgical instrument includes a body, an ultrasonic blade, a clamp arm, and a resilient member. The body includes an electrical conductor and defines a longitudinal axis. The clamp arm is pivotably coupled with the body at a pivot assembly. The clamp arm is operable to compress tissue against the ultrasonic blade. The clamp arm includes an electrode operable to apply RF energy to tissue, wherein the clamp arm is configured to be loaded onto and removed from the body at the pivot assembly along a path that is transverse to the longitudinal axis defined by the body. The resilient member is located within the pivot assembly. The resilient member is configured to provide electrical continuity between the electrode of the clamp arm and the electrical conductor of the body.

A surgical instrument includes a body, an ultrasonic blade, a clamp arm assembly, and a detent assembly. The clamp arm assembly includes a clamp arm pivotably coupled with the body at a pivot assembly. The clamp arm is operable to compress tissue against the ultrasonic blade. The detent assembly is configured to provide tactile resistance to pivotal movement of the clamp arm relative to the body beyond a predefined pivot angle. The detent assembly is configured to permit pivotal movement of the clamp arm relative to the body beyond a predefined pivot angle upon application of a force sufficient to overcome the tactile resistance

A first subassembly includes a body and an ultrasonic blade. A second subassembly is configured to removably couple with the first subassembly and includes a first clamp arm and a first clamp arm actuator. The first clamp arm is configured to be located on a first side of the longitudinal axis of the body, and the first clamp arm actuator is configured to be located on a second side of the longitudinal axis, when the second subassembly is coupled with the first subassembly. The third subassembly is similar to the second subassembly except that the second clamp arm of the third subassembly is configured to be located on the second side of the longitudinal axis of the body when the third subassembly is coupled with the first subassembly.