Abstract: A surgical tool having an elongated shaft having a proximal end and distal end. A surgical end effector is located about the distal end. The surgical end effector has a plurality of effector mechanisms comprising a plurality of degree of freedoms. An effector body is located at the proximal end. The effector body includes a plurality of motor interfaces for driving the plurality of effector mechanisms. A transmission is coupled to the effector body.

Abstract: A surgical tool having an elongated shaft having a proximal end and distal end. A surgical end effector is located about the distal end. The surgical end effector has a plurality of effector mechanisms comprising a plurality of degree of freedoms. An effector body is located at the proximal end. The effector body includes a plurality of motor interfaces for driving the plurality of effector mechanisms. A transmission is coupled to the effector body.

Abstract: A surgical tool having an elongated shaft having a proximal end and distal end. A surgical end effector is located about the distal end. The surgical end effector has a plurality of effector mechanisms comprising a plurality of degree of freedoms. An effector body is located at the proximal end. The effector body includes a plurality of motor interfaces for driving the plurality of effector mechanisms. A transmission is coupled to the effector body.

Abstract: The present invention relates to a system and apparatus for implementing a method for identifying tube parameters of a curved tube of an active cannula for operating on a target in a patient. The method includes the step (a) of acquiring a model of the patient anatomy including the target. The method also includes the step (b) of selecting a set of parameters characterizing a curved tube. The method also includes the step (c) of computing a workspace for an active cannula having the selected curved tube parameters. The method also includes the step (d) of comparing the workspace to the anatomical model to determine the degree to which an active cannula having the selected curved tube parameters covers the target. The method also includes the step (e) of repeating steps (b) through (d) through a defined number of curved tube parameter sets. The method also includes the step (f) of identifying the curved tube parameters that provide an active cannula with an optimal degree of target coverage.

Abstract: A surgical manipulator includes an internal working end having an internal joint, and an external control interface linked to the internal working end for controlling the internal working end. The external control interface includes at least one lever defining a grip volume for a surgeon's hand when gripping and operating the at least one lever, and an external joint linked to the internal joint for controlling the internal joint. The external joint is positioned substantially within the grip volume.

Abstract: A surgical tool having an elongated shaft having a proximal end and distal end. A surgical end effector is located about the distal end. The surgical end effector has a plurality of effector mechanisms comprising a plurality of degree of freedoms. An effector body is located at the proximal end. The effector body includes a plurality of motor interfaces for driving the plurality of effector mechanisms. A transmission is coupled to the effector body.

Abstract: The present invention relates to a system and apparatus for implementing a method for identifying tube parameters of a curved tube of an active cannula for operating on a target in a patient. The method includes the step (a) of acquiring a model of the patient anatomy including the target. The method also includes the step (b) of selecting a set of parameters characterizing a curved tube. The method also includes the step (c) of computing a workspace for an active cannula having the selected curved tube parameters. The method also includes the step (d) of comparing the workspace to the anatomical model to determine the degree to which an active cannula having the selected curved tube parameters covers the target. The method also includes the step (e) of repeating steps (b) through (d) through a defined number of curved tube parameter sets. The method also includes the step (f) of identifying the curved tube parameters that provide an active cannula with an optimal degree of target coverage.

Abstract: A surgical grasper includes a first handle arm, a second handle arm pivotally coupled to the first handle arm, a tool body pivotally coupled to both the first handle arm and the second handle arm, a first jaw member pivotally coupled to the tool body, a second jaw member pivotally coupled to the tool body, a first tension element coupled to both the first handle arm and to the first jaw member, a second tension element coupled to both the second handle arm and to the second jaw member, and a lock that locks relative movement between the first and second handle arms. Rotational movement of the first and second handle arms generates correlated rotational movement of the first and second jaw members.

Abstract: An apparatus for supporting a medical device on a patient includes a mounting structure configured to be fitted onto the patient to encircle at least a portion of a body part of the patient. The mounting structure includes an inner layer and an outer layer that define a confinement. A jamming material is contained within the confmement. The jamming material is configured to flow within the confmement to conform to the shape of the body part of the patient onto which the mounting structure is fitted. The mass of jamming material is configured to harden and become rigid in its conformed shape in response to a vacuum being formed in the confinement.

Abstract: A robotic surgical apparatus includes at least two tubes having a nested, concentric configuration with an inner tube positioned in an outer tube. The tubes are configured to deliver surgical therapy. A first tube carrier connected to the outer tube and a second tube carrier connected to the inner tube. The first tube carrier and its associated outer tube and the second tube carrier and its associated inner tube form a robotic arm assembly. An actuator for actuating the robotic arm assembly is configured to receive the robotic arm assembly via a tube insertion interface into which the robotic arm assembly can be inserted.

Abstract: A surgical robot system includes a support structure for positioning relative to a patient. The support structure includes a plurality of mounting structures. One or more robotic tool cassettes that are configured to interchangeably connect with any of the mounting structures. Each tool cassette includes a concentric tube manipulator and a transmission for operating the concentric tube manipulator. The support structure also includes a tube collector including a tube assembly associated with each of the mounting structures. The tube assemblies are configured to receive the concentric tube manipulators and guide the manipulators to extend along predetermined trajectories relative to each other.

Abstract: Systems and method are described for counterbalancing the force required to deform a flexure joint. The system includes an elastically deformable flexure joint, a control joint, and an energy balance system. The control joint is mechanically linked to the flexure joint such that movement of the control joint causes a corresponding deformation of the flexure joint. The energy balance system provides a spring force to aid movement of the control joint and to overcome an elastic force required to deform the flexure joint.

Abstract: A surgical manipulator includes an internal working end having an internal joint, and an external control interface linked to the internal working end for controlling the internal working end. The external control interface includes at least one lever defining a grip volume for a surgeon's hand when gripping and operating the at least one lever, and an external joint linked to the internal joint for controlling the internal joint. The external joint is positioned substantially within the grip volume.

Abstract: A surgical manipulator includes an internal working end having an internal joint, and an external control interface linked to the internal working end for controlling the internal working end. The external control interface includes at least one lever defining a grip volume for a surgeon's hand when gripping and operating the at least one lever, and an external joint linked to the internal joint for controlling the internal joint. The external joint is positioned substantially within the grip volume.

Abstract: A movement dampening system for a surgical tool. The system includes a height-adjustable base positionable adjacent to a surgical site on a patient. An elastic damper is disposed adjacent to the height-adjustable base, A channel extends through the elastic damper and the height-adjustable base to the surgical site. A portion of the channel extending through the elastic damper is sized to receive the surgical tool and to restrict movement of the surgical tool.

Abstract: A surgical tool having an elongated shaft having a proximal end and distal end. A surgical end effector is located about the distal end. The surgical end effector has a plurality of effector mechanisms comprising a plurality of degree of freedoms. An effector body is located at the proximal end. The effector body includes a plurality of motor interfaces for driving the plurality of effector mechanisms. A transmission is coupled to the effector body.

Abstract: A surgical grasper includes a first handle arm, a second handle arm pivotally coupled to the first handle arm, a tool body pivotally coupled to both the first handle arm and the second handle arm, a first jaw member pivotally coupled to the tool body, a second jaw member pivotally coupled to the tool body, a first tension element coupled to both the first handle arm and to the first jaw member, a second tension element coupled to both the second handle arm and to the second jaw member, and a lock that locks relative movement between the first and second handle arms. Rotational movement of the first and second handle arms generates correlated rotational movement of the first and second jaw members.

Abstract: A surgical robot system includes a support structure for positioning relative to a patient. The support structure includes a plurality of mounting structures. One or more robotic tool cassettes that are configured to interchangeably connect with any of the mounting structures. Each tool cassette includes a concentric tube manipulator and a transmission for operating the concentric tube manipulator. The support structure also includes a tube collector including a tube assembly associated with each of the mounting structures. The tube assemblies are configured to receive the concentric tube manipulators and guide the manipulators to extend along predetermined trajectories relative to each other.

Abstract: A robotic surgical apparatus includes at least two tubes having a nested, concentric configuration with an inner tube positioned in an outer tube. The tubes are configured to deliver surgical therapy. A first tube carrier connected to the outer tube and a second tube carrier connected to the inner tube. The first tube carrier and its associated outer tube and the second tube carrier and its associated inner tube form a robotic arm assembly. An actuator for actuating the robotic arm assembly is configured to receive the robotic arm assembly via a tube insertion interface into which the robotic arm assembly can be inserted.

Abstract: An apparatus for supporting a medical device on a patient includes a support structure adapted to be fitted to the patient's body. The medical device is connectable to the support structure. At least one mounting pad is connected to the support structure and is adapted to engage the patient's anatomy. The at least one mounting pad includes a frictional jamming structure configured so that, in a non-actuated condition of the mounting pad, the mounting pad conforms to the patient's anatomy and, in an actuated condition of the mounting pad, the mounting pad becomes rigid in its conformed shape.