A translatable end effector for a surgical robot includes a pair of linkage arms, an anchor adapted to be mounted to an arm of the surgical robot and a tool holder connected to the anchor through the pair of arms. The hinges at the anchor are pivotally and slidably coupled to the pair of arms to allow the arms to pivot and slide relative to the anchor hinges. The tool holder is configured to hold a surgical tool and has a pair of hinges that pivotally couple to the ends of the linkage arms. The hinges and the linkage arms are configured such that a longitudinal trajectory defined by the surgical tool is maintained as the tool holder translates upwardly and downwardly relative to the surgical robot arm.

A robotic surgery system includes an orienting platform, a manipulator, and a set-up linkage. The manipulator includes an instrument holder, a pitch linkage, and a yaw linkage. The instrument holder is operable to translate the surgical instrument along an insertion axis to insert the surgical instrument through a remote center of manipulation (RC). The pitch linkage is operable to rotate the instrument holder around a pitch axis that intersects the RC. The yaw linkage is operable to rotate the pitch linkage around a yaw axis. The set-up linkage is connected between the yaw linkage and the orienting platform. The set-up linkage is operable to reposition the manipulator relative to the orienting platform with a motion that maintains the RC in a fixed position relative to the orienting platform.

Knuckle joint assembly for a medical device support system. The knuckle joint assembly includes a cartridge assembly that includes a cartridge housing and a rotary bearing. The cartridge housing includes a bore having a central axis and a bearing mount in the bore. The rotary bearing is press fitted in the bearing mount and configured to receive axially therethrough a spindle to rotatably support the spindle about the central axis. The knuckle joint assembly includes a retaining clip and a retaining pin. The retaining clip is selectively movable to disengage and engage a groove in a spindle to respectively support or release the spindle along a central axis. The retaining pin is movable between a first position to allow movement of the retaining clip between positions but prevent removal of the retaining clip, and a second position to block movement of the retaining clip from the engaged position.

A medical holding device includes: an arm configured by coupling a plurality of links to each other by joints, the arm having at least seven or more degrees of freedom by rotational operations on rotation axes, and being configured to support a medical instrument; and an arm controller configured to control an operation of the arm. The arm has six degrees of freedom realized by rotational operations of six passive rotation axes that passively rotate and one or more degrees of freedom realized by rotational operations of one or more active rotation axes that actively rotate, and the arm controller is configured to rotate the active rotation axis so as to avoid a predetermined state of a posture of the arm.

A system includes a base, and an actuator having a first end and a second end. The system also includes a shaft configured to rotate relative to the base, and a drive link fixed to the shaft. The system further includes a support arm. A first end of the support arm being fixed to the shaft such that rotation of the shaft causes commensurate rotation of the support arm. The system also includes a timing link having a first end pivotably connected to the base and a second end opposite the first end. Additionally, the system includes a mount coupled to the second end of the timing link. The mount is configured to maintain a substantially constant orientation relative to the base as the support arm transitions between a raised position and a lowered position.

Examples relate to a system, a method and a computer program controlling a recording device of a surgical microscope system, and to a corresponding surgical microscope system. The system comprises one or more processors and an interface. The system is configured to obtain input data from one or more sensors or actors of the surgical microscope system via the interface. The system is configured to detect a start or an end of a surgery based on the input data. The surgery involves a use of the surgical microscope system. The system is configured to provide a control signal to the recording device of the surgical microscope system via the interface based on the detected start or end of the surgery. The input data may be used to detect the start or the end of a surgical procedure, which may in turn trigger the activation or deactivation of the recording being performed by the recording device.

Method and system allowing more accurate detection and identification of unwanted arcing include novel processing of signal voltage representing recovered power-line current. In one implementation, arc-faults are detected based on numerical analysis where individual cycles of line voltage and current are observed and data collected during each cycle is processed to estimate likelihood of presence of arc-event within each individual cycle based on pre-defined number of arc-events occurring within pre-defined number of contiguous cycles. In another implementation, fast transient current spikes detection can be done by: computing difference values between consecutive line-current samples collected over a cycle, average of differences, and peak-to-peak value of line-current; comparing each difference value to average of difference; comparing each difference value to peak-to-peak value; and, based on calculation of composite of two comparisons, using thresholds to determine if arcing is present within processed cycle.

The various inventions relate to robotic surgical devices, consoles for operating such surgical devices, operating theaters in which the various devices can be used, insertion systems for inserting and using the surgical devices, and related methods.

Apparatus and methods are described for performing intraocular surgery on a patient using a tool. A robotic unit includes a tool mount configured to securely hold the tool thereupon and configured to insert the tool into the patient's eye such that entry of the tool into the patient's eye is via an incision point, and the tip of the tool is disposed within the patient's eye. One or more multi-jointed arms are disposed on a single side of the tool mount and moveably support the tool mount. A computer processor drives the robotic unit to perform at least a portion of a procedure by moving the tip of the tool in a desired manner with respect to the eye, while entry of the tool into the patient's eye is maintained fixed at the incision point. Other applications are also described.

Various embodiments concern locking release mechanisms that allow an articulated support arm to be moved between various vertical orientations. A locking release mechanism may include a handle release mechanism positioned within the handle of the articulated support arm, and a gas spring release mechanism positioned within the body of the articulated support arm. The articulated support arm can include a gas spring that remains locked until the handle release mechanism is activated, e.g. by applying pressure to a grip actuator. Other embodiments concern cable management techniques for articulated support arms. Oftentimes, an articulated support arm will include cables routed through the arm that are configured to support an attachment. For example, the cable(s) may be adapted for audio signals, video signals, power, etc. The cable(s) can be readily cleaned and/or serviced when routed through an articulated support arm composed of one or more removable pieces.