A surgical device includes a polyaxial surgical screw that includes an internally hollow tulip. The tulip includes two elongated rods which are parallel and mutually spaced apart, each elongated rod protruding from a side wall of the tulip and extending away from a first end of the tulip in a direction opposite to a second end of the tulip. The rods define a channel in communication with the first end for accessing the interior of the tulip. A locking unit can be reversibly mounted on the polyaxial surgical screw. The locking unit includes a tubular body which has an inner cavity and is adapted to be fitted about the elongated rods during a configuration of use of the surgical device. The tubular body has two mutually opposite protrusions which project into the inner cavity that are configured to face the channel and be mutually interposed.

Methods and apparatus for retracting the dura away from a cutting tool during a laminectomy procedure. The method includes inserting a memory shape surgical sponge (patty) into an initial epidural space between the dura and the tool used to decompress (e.g., drill) the lamina. As the lamina is further decompressed, the patty tends to spring back toward its nominal position, urging the dura away from the decompression and isolating the dura from the drill.

A gearbox assembly and surgical instrument including the same. The gearbox assembly includes a drive gear including a round gear and a lead screw such that a rotational input to the round gear rotates the lead screw. A first hub is threadingly engaged about the lead screw such that rotation of the lead screw translates the first hub. A second hub is spaced-apart from the first hub and engaged with a drive rod. A compression spring is disposed between the hubs. When a force acting against the drive rod is below a threshold, the rotational input translates the first hub, compression spring, second hub, and drive rod. When the force is equal to or above the threshold, the rotational input translates the first hub and compresses the compression spring against the second hub to maintain the second hub and drive rod in position.

A surgical instrument includes an end effector, a shaft assembly, an actuation driver, and an actuation assembly. The end effector includes first and second jaws. At least one of the first and second jaws is configured to move relative to the other of the first and second jaws to compress tissue therebetween. The shaft assembly extends proximally from the end effector. The shaft assembly includes a closure member extending along a longitudinal axis. The actuation driver is configured to configured to receive a motor output from a motor. The actuation assembly is operatively coupled with the actuation driver and the closure member. The actuation assembly includes a translating member configured to translate together with the closure member along the longitudinal axis a predetermined distance using the actuation driver such that the closure member applies a predetermined closure force to the first and second jaws corresponding to the predetermined distance.

An ultrasonic surgical instrument including an end effector having an ultrasonic blade, a shaft assembly that defines a longitudinal axis proximally extending from the end effector and an ultrasonic transducer assembly proximally extending from an acoustic waveguide in communication with the ultrasonic blade. The ultrasonic surgical instrument also includes a housing proximally projecting from the shaft assembly such that the ultrasonic transducer assembly is positioned within the housing and a carrier moveably supports the ultrasonic transducer assembly along the longitudinal axis. The carrier collectively moves the ultrasonic transducer assembly, the acoustic waveguide, and the end effector relative to the housing from a proximal, retracted position to a distal, extended position, for inserting the ultrasonic blade into a patient. The ultrasonic surgical instrument also includes an electrical cable extending through the housing at a cable port that transmits electrical communication with the ultrasonic transducer assembly.

A medical device support system including a shaft, an extension arm, and a hub mounted to the shaft for pivotable movement of the extension arm about a rotation axis of the shaft. The hub includes a cavity including first and second contact faces, and at least one floating stop movably disposed in the cavity. The hub is pivotably mounted for a range of at least 360-degrees rotation about the rotation axis. The at least 360-degrees rotation range is based on a compound of a first rotation range and a second rotation range. The first rotation range is defined by a first movable amount of the at least one floating stop between first and second stop surfaces fixed relative to the shaft. The second rotation range is defined by a second movable amount of the at least one floating stop between the first and second contact faces of the hub.

A cervical cup includes a body having a flange and a vacuum port so that application of a vacuum to the port will secure the cervical cup to a cervix disposed inside of the body of the cup. Example of the disclosed methodology to treat preterm birth includes inserting of a cervix into a cervical cup and applying a vacuum to a vacuum port of the cervical cup so as to secure the cervical cup to the cervix.

The present invention relates to a method for designing an implant comprising designing a contour curvature of the implant so that an articulating surface of the implant is designed to correspond to a simulated healthy articulating surface of a damaged articulating surface of a joint. The implant is provided with at least one positioning mark designed to be used for determining the orientation in which the implant is to be placed in a recess made in a damaged articulating surface of a joint. Further, the present invention relates to methods for positioning and inserting a medical implant in a recess.

Retraction systems, assemblies, and devices for retracting an end unit are provided. A retraction assembly may be configured to move the end unit of a robot between a first state and a second state. A first signal may be received indicating a working condition. A first instruction may be generated to move the end unit from the second state to the first state. The retraction assembly may be caused to move the end unit from the second state to the first state based on receiving the first signal and the first instruction. The end unit may be held in the first state when the first signal is being received and the retraction assembly may move the end unit from the first state to the second state when the first signal is not received.

Systems, methods, and devices for drilling and imaging an anatomical element are provided. An image may be received from an imaging device coupled to a housing. The image may depict hard tissue and/or soft tissue and the image may be processed using image processing to identify the hard tissue and/or soft tissue. A thickness of the hard tissue may be determined and instructions to perform a surgical step on the hard tissue when the thickness is less than a predetermined threshold may be transmitted.