System and methods are provided for adaptively and interoperatively configuring an automated arm used during a medical procedure. The automated arm is configured to position and orient an end effector on the automated arm a desired distance and orientation from a target. The end effector may be an external video scope and the target may be a surgical port. The positions and orientations of the end effector and the target may be continuously updated. The position of the arm may be moved to new locations responsive to user commands. The automated arm may include a multi-joint arm attached to a weighted frame. The weighted frame may include a tower and a supporting beam.

A system and a device are provided for counterbalancing a surgical robotic system that include a rail assembly having a shaft that engages a first carriage and a second carriage via threaded mechanism. A manipulatable arm carries a movable effector; the manipulatable arm is supported by the first carriage. A counter weight is supported by the second carriage with a single actuator. A simplified robotic surgery system results.

The stand base is for a surgical microscope. The stand base is for setting up on a floor configured as a planar surface and includes at least a first weight module; a base body defining an underside and accommodating the first weight module; a support arrangement connected to the base body and supporting the stand base with at least three support points in contact engagement with the floor to permit setting up the stand base; the support points conjointly defining a support plane whereat the support points are in contact engagement with the floor; the underside of the base body facing toward the support plane; an ancillary body; the base body having a receiving arrangement in the underside for releasably accommodating the ancillary body; and, the underside of the base body and the support plane conjointly defining a smallest spacing therebetween which is greater than 10 cm.

This document provides surgical retractor devices and systems. For example, this document provides a weighted surgical retractor system. In one example embodiment, this document provides a weighted Deaver retractor system that includes a selectable amount of weight that can be releasably coupled to a shaft of the retractor. The surgical retractors provided herein can be used during a variety of surgical procedures, including surgical procedures performed on the abdomen, thoracic regions, limbs, and so on. In some embodiments, the surgical retractors provided herein are well-suited for retraction of the vaginal canal for hysterectomy surgery, and for other procedures for which vaginal retraction is necessary.

An endoscope holding apparatus includes: a base section; a support column; a first link and a second link that rotate around a first linking portion; a third link that rotates around a second linking portion; a fourth link capable of holding an endoscope; a fifth link including a first counter weight; a second counterweight linked to the second linking portion; a sixth link including one arm linked to the fifth link; and a seventh link including a first end configured to rotate around a fifth linking portion and a second end configured to rotate around a sixth linking portion, wherein the first, fifth, sixth, and third linking portions form a parallelogram.

A support structure comprises a base joint coupling a proximal link of the support structure to a base. The proximal link is configured to rotate about a first axis associated with the base joint. The support structure further comprises a linkage mechanism. The linkage mechanism maintains an orientation of an instrument support relative to the base as the support structure is moved from a first configuration to a second configuration. In the second configuration, the support structure is rotated relative to the base about the first axis.

Described herein are systems and devices for counterbalancing a surgical robotic system using a counterbalanced Z-axis drive. The counterbalanced Z-axis drive includes a self-centering ball screw assembly having a linear actuator and a counter weight. The counter weight is configured to substantially support a load associated with an arm of the robotic system when the driving portion is engaged or disengaged. In some embodiments, the counterbalanced Z-axis drive controls the arm and a movable effector mounted on the arm. Also disclosed herein are systems and devices for direct drive actuation of rotary axes of the arm which reduce the size and weight of the arm.

Provided is an arm device. The arm device includes: a first gimbal portion configured to rotatably support an instrument about a first rotational axis extending along an axis line of the instrument; a second gimbal portion configured to rotate the instrument about a second rotational axis extending along a direction intersecting the first rotational axis; a distal portion configured to rotate the instrument about a third rotational axis extending to intersect a plane including the first rotational axis and the second rotational axis. The third rotational axis has an inclination angle greater than 0 degree and less than 90 degrees when a horizontal direction is defined as 0 degree and an upper vertical direction is defined as 90 degrees.

A counterbalance mechanism in an ophthalmic laser system balances the weight of the laser beam delivery head and provides small, precise and repeatable variations in the net load exerted by the laser head on the patient's eye over a defined distance of travel. The counterbalance mechanism includes a balance beam pivotably mounted on a support block, with the laser head and a counterweight mounted on its two ends. The counterweight is movable along the balance beam via a linear motion bearing. A mechanical link links the counterweight to the support block; the link has a predefined length and is pivotable around its respective connection points on the support block and the counterweight. When the balance beam pivots, the link causes the counterweight to move along the balance beam, thereby changing the mechanical advantage of the counterweight and varies the counterbalancing force to provide variations in the net load.

A surgical microscope having an optical body connected to a holder by a hinge, and a balancing device. The device includes a counterweight, connected in at least one connection point to the optical body of the surgical microscope through a support which allows the free rotation of the counterweight around the connection point so as to balance the weight distribution of the optical body (with respect to the hinge and prevent unwanted rotations of the optical body.