A drape includes a first drape portion configured to receive a manipulator arm of a surgical system and a pocket coupled to a distal portion of the first drape portion. The pocket is configured to receive a manipulator of the surgical system. The pocket includes a flexible membrane positionable between an output of the manipulator and an input of a surgical instrument mountable to the manipulator. In some embodiments, the flexible membrane is located at a distal end of the pocket. In some embodiments, the flexible membrane is configured to allow an actuating force to be transmitted from the output of the manipulator to the input of the surgical instrument. In some embodiments, the pocket provides a sterile barrier between the manipulator and the surgical instrument. In some embodiments, the drape further includes a rotatable seal configured to couple a proximal opening of the pocket to the first drape portion.

A carrier arm joint device for a carrier arm of a stand device for arranging in the operating room and for displacing a medical device held on the carrier arm is configured for setting a payload corresponding to a weight of the medical device to be taken up by the carrier arm. The device includes at least one pivot axis for mounting at least one strut of the carrier arm, respectively; and a support axis for supporting a lever configured to transmit forces holding the carrier arm between the strut and the carrier arm joint device A distance between the axes is adjustable within an adjustment range in order to set the payload; the size and/or the extent of the adjustment range is independent of the position of the pivot axis. It is possible to maximize the adjustment range and therefore the payload spectrum in a comparatively compact and structurally rigid joint. A carrier system and a stand device can include at least one such carrier arm joint device.

A surgical robot comprising: a surgical robot arm comprising: a series of joints extending from a base to a terminal end for attaching to a surgical instrument for inserting through a port into a patients body to a surgical site, the series of joints comprising a first set of joints, wherein for each joint of the first set of joints, there is a configuration of the surgical robot arm for which that joint experiences a gravitational torque or force and a movement of that joint complying with the gravitational torque or force would cause the surgical instrument to advance into the patients body towards the surgical site; and joint motors for driving the series of joints; and a robot arm controller configured to send drive signals to drive the joint motors, wherein the surgical robot arm controller is configured to, in response to detecting a power loss, send drive signals to drive the joint motors so as to hold the position of each joint of the first set ofjoints against gravity, thereby preventing the surgical instrument from advancing into the patients body towards the surgical site due to movement of one or more joints of the first set of joints under gravity.

Systems and methods for maneuvering an endoscope are disclosed. The system includes: at least one first pivoting support that is pivotally attached to the endoscope and that permits the endoscope to pivot around at least one first axis of rotation; at least one second pivoting support that is in communication with the at least one first pivoting support and that is adapted to rotate around at least one axis that is substantially orthogonal to said first axis so as to permit the endoscope to rotate around an insertion point into a body in at least two orthogonal axes; and at least one controller attached to either the first or the second pivoting. The controller is adapted to provide a constant dynamic equilibrium between said endoscope and at least one of the pivoting supports.

A load balancing arm for a medical device support system. The load balancing arm includes a proximal hub, an adjustable bearing element, a support arm, a spring and a link. A distal end of the support arm is configured to support a medical device load and a proximal end is pivotably mounted to a main bearing element for pivotable movement about a main pivot axis. The spring extends within a cavity of the support arm and is mounted to exert a biasing force between the main pivot axis and a distal end of the spring. The link has a proximal end pivotably mounted to the adjustable bearing element for pivotable movement about an adjustable pivot axis, and a distal end pivotably mounted to the distal end of the spring such that the biasing force exerted by the spring is transmitted through the link to the adjustable bearing element.

When the mass of the first moving body is defined as M1, the mass of the second moving body is defined as M2, the distance between a first intersection point of a perpendicular line from a rotation center of the rotation axis to the first moving body and a first gravity center of the first moving body when the distance between the first intersection point and the first gravity center in the first moving body is the shortest is defined as L1, and the distance between a second intersection point of a perpendicular line from the rotation center of the rotation axis to the second moving body and a second gravity center of the second moving body when the distance between the second intersection point and the second gravity center in the second moving body is the shortest is defined as L2, M2=(L1/L2)×M1 is satisfied.

A medical waste management system including a boom secured to a fixed structure of a medical facility. A waste container defines a waste volume sized to collect liquid waste material received through a suction line under the influence of a vacuum provided by a vacuum pump. The system may include a service head coupled to the boom and including the waste container. A vacuum port is in fluid communication with the waste volume, and discharge and/or cleaning ports also in communication with the waste volume may be provided. The vacuum pump may be integrated with the medical facility, and the system may include an offload pump Integrated with the medical facility and in communication with the discharge port. The waste container may be supported on a mobile cart configured to be removably coupled with the boom. The system may further include a liquid measuring system coupled to the waste container.

A control device for a capsule endoscope is provided. The control device includes a balance arm device, a permanent magnet, a 2-DOF rotary platform and an examination bed. The bottom of the balance arm device is fixed, and the active end of the balance arm device connects with a boom. The 2-DOF rotary platform is fixed below the boom and the permanent magnet is located in the 2-DOF rotary platform. The examination bed is put below the 2-DOF rotary platform, and the area between the examination bed and the 2-DOF rotary platform is an examination area.

Various embodiments provide systems and methods for controlling a catheter with a catheter positioning device by using a remote controller. As the catheter is advanced by the catheter positioning device, a counterweight may be adjusted to balance the catheter positioning system. In further embodiments, the counterweight may be configured to move to balance a sled member such that any total moment exerted on a sled base remains constant. In further embodiments, the counterweight may be controlled by a control system based on one or more sensors coupled with the catheter positioning system.

A method of operating a manipulator arm comprising a manipulator interface configured to removably couple with and transmit actuation force to a medical instrument includes mounting a cannula to a cannula mount coupled to the manipulator arm; mounting a medical instrument to the manipulator interface; inserting a shaft of the medical instrument through an entry guide mounted to the cannula; rotating the manipulator interface and the medical instrument relative to the cannula mount; and rotating the entry guide relative to the cannula mount about a longitudinal axis of the cannula.