System and methods are provided for adaptively and intraoperatively 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.

Apparatuses and methods described herein relate to arm carts for transporting and securing a robotic arm to a surgical table. In some embodiments, an arm cart may include an arm support having two joints that can be manipulated to move an arm into a position in which a coupler of the arm is engageable with a coupling site of a surgical table. In some embodiments, an arm cart may include an arm support that is rotatable and translatable to permit movement of an attachment area for receiving and attaching a coupling site of a surgical table to a coupler attached to an arm. In some embodiments, an arm cart may include an arm support that releasably couples to a middle segment of the arm positioned at least two segments away from an end of the arm having a coupler for coupling to a coupling site of a surgical table.

A medical system including a support structure including a proximal link and a distal link, and a base joint coupling the proximal link of the support structure to a base, wherein the proximal link is configured to rotate about a first axis associated with the base joint. The system also includes a linkage mechanism coupling the proximal link to the distal link. The system also includes an instrument support coupled to the distal link, wherein the instrument support has an orientation relative to the base in a first configuration of the support structure, and wherein the linkage mechanism maintains the orientation of the instrument support relative to the base as the support structure is moved into a second configuration in which the support structure is rotated relative to the base about the first axis and the distal link is extended from the proximal link.

A head strap (120) for medical loupe glasses is provided, comprising two tubes (130, 132) of flexible wipe-clean material and a magnet (134, 136) located on each tube, the magnets (134, 136) being connectable by magnetic forces to effect securement.

This invention relates to a surgical microscope comprising an optical body (100) connected to a holder (110) by a hinge (50), and a balancing device, characterized in that it comprises a counterweight (203), connected in at least one connection point (204) to the optical body (100) of the surgical microscope through a support (201) which allows the free rotation of said counterweight (203) around said connection point (204), so as to balance the weight distribution of the optical body (100) with respect to said hinge (50) and prevent unwanted rotations of said optical body (100).

A support structure for supporting an instrument manipulator comprises a proximal link and a distal link configured to extend from the proximal link. The support structure further comprises a base joint coupling the proximal link of the support structure to a base, and the proximal link is configured to rotate about a first axis associated with the base joint. The support structure further comprises a counterbalance mechanism comprising a counterweight block configured to move linearly within the support structure. The counterweight block has a counterweight mass to counterbalance a combined mass of the support structure and the instrument manipulator as the distal link extends from the proximal link.

A medical device holding apparatus having a first arm with a holding portion to hold a medical device; a second arm connected to the rotatable first arm; a base connected to the rotatable second arm and having a support shaft standing in a vertical direction; and a first counterweight portion connected to the second arm, wherein the second arm has a fulcrum around which the second arm is rotatable, and the first counterweight has a slit being connected to the proximal end portion of the second arm for guiding the proximal end portion of the second arm when the second arm is rotated around the fulcrum; and a guide for moving the first counterweight in the vertical direction after the guide receives a force generated when the proximal end portion of the second arm is guided and moved in the slit.

A medical observation device that includes a microscope that images a surgical site, a holding section that holds the microscope, a base section to which the holding section is connected, and an operation section that receives operating input, the operation section being provided at the base section, the holding section being configured as a balance arm provided with a counterweight, when the base section is viewed from an upper side of the medical observation device, the base section having a first area inside a movable range of the counterweight and a second area outside the movable range of the counterweight, the base end of the holding section being connected to the base section at a location in the first area, and the operation section being arranged at another location in the second area.

Systems and methods for adaptively and intraoperatively 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 support structure for supporting an instrument manipulator comprises a proximal link and a distal link configured to extend from the proximal link. The support structure further comprises a base joint coupling the proximal link of the support structure to a base, and the proximal link is configured to rotate about a first axis associated with the base joint. The support structure further comprises a counterbalance mechanism comprising a counterweight block configured to move linearly within the support structure. The counterweight block has a counterweight mass to counterbalance a combined mass of the support structure and the instrument manipulator as the distal link extends from the proximal link.