Abstract: Systems and methods for controlling a robotic device to perform a tissue modification task are disclosed. The methods include receiving a task plan relative to a patient's image data. The task plan includes information relating to an entry point of a surgical tool into a tissue and a planned trajectory of the surgical tool inside the tissue for performing the tissue modification task. The methods also include controlling the robotic device to autonomously or semi-autonomously execute the tissue modification task by identifying datum point as the entry point of the surgical tool into the tissue, activating the surgical tool to perform the tissue modification task along the planned trajectory from the datum point, determining whether the surgical tool has reached an end of the planned trajectory, and retracting the surgical tool from the tissue upon determining that the surgical tool has reached the end of the planned trajectory.

Abstract: A system and method is provided for estimating orientation and position of surgical instrumentation or tools relative to a patient's bone structure. The system and/or method may include registering an axis and/or plane associated with a patient's bone. The system and/or method may further include receiving, from magnetic and orientation sensors, information indicative of orientation and position of the surgical instrument or tool relative to the registered axis and/or plane.

Abstract: A system and method is provided for estimating orientation and position of surgical instrumentation or tools relative to a patient's bone structure. The system and/or method may include registering an axis and/or plane associated with a patient's bone. The system and/or method may further include receiving, from magnetic and orientation sensors, information indicative of orientation and position of the surgical instrument or tool relative to the registered axis and/or plane.

Abstract: A system and method is provided for estimating orientation and position of surgical instrumentation or tools relative to a patient's bone structure. The system and/or method may include registering an axis and/or plane associated with a patient's bone. The system and/or method may further include receiving, from magnetic and orientation sensors, information indicative of orientation and position of the surgical instrument or tool relative to the registered axis and/or plane.

Abstract: A knee balancing system for measuring performance parameters associated with an orthopedic articular joint comprises a force sensing module and one or more inertial measurement units. The force sensing module comprises a housing that includes an articular surface having a medial portion and a lateral portion, each of which is substantially mechanically isolated from the other. The force sensing module also includes first and second sets of sensors disposed within the housing. The first set of sensors is mechanically coupled to the medial portion of the articular surface and configured to detect information indicative of a first force incident upon the medial portion of the articular surface. The second set of sensors is mechanically coupled to the lateral portion of the articular surface and configured to detect information indicative of a second force incident upon a lateral portion of the articular surface.

Abstract: A joint monitoring system for measuring performance parameters associated with an orthopedic articular joint comprises a force sensing module and an inertial measurement units. The sensing module comprises a housing that engages with the joint articular surface having a medial portion and a lateral portion. The sensing module also includes a first and second set of sensors disposed within the housing. The first set of sensors are mechanically coupled to the medial portion of the particular surface and configured to detect information of a force incident upon the medial portion of the articular surface. The second set of sensors are mechanically coupled to the lateral portion of the articular surface and configured to detect information a force incident upon a lateral portion of the articular surface. The inertial measurement unit is configured to detect an orientation of at least one of a first and second bone of a knee joint.

Abstract: A force sensing module for measuring performance parameters associated with an orthopedic articular joint is disclosed. The force sensing module includes a housing having a substantially concave articular surface and an implant surface, the substantially concave articular surface and the implant surface defining a compartment therebetween. The force sensing module also includes a first set of sensors disposed within the compartment, which are mechanically coupled between the substantially concave articular surface and the implant surface. The first set of sensors is configured to detect information indicative of a first portion of a force present at a first area of the substantially concave articular surface. The force sensing module also includes a second set of sensors disposed within the compartment, which are mechanically coupled between the substantially concave articular surface and the implant surface.

Abstract: A knee balancing system for measuring performance parameters associated with an orthopedic articular joint comprises a force sensing module and one or more inertial measurement units. The force sensing module comprises a housing that includes an articular surface having a medial portion and a lateral portion, each of which is substantially mechanically isolated from the other. The force sensing module also includes first and second sets of sensors disposed within the housing. The first set of sensors is mechanically coupled to the medial portion of the articular surface and configured to detect information indicative of a first force incident upon the medial portion of the articular surface. The second set of sensors is mechanically coupled to the lateral portion of the articular surface and configured to detect information indicative of a second force incident upon a lateral portion of the articular surface.

Abstract: A force sensing module for measuring performance parameters associated with an orthopedic articular joint is disclosed. The force sensing module includes a housing having a substantially concave articular surface and an implant surface, the substantially concave articular surface and the implant surface defining a compartment therebetween. The force sensing module also includes a first set of sensors disposed within the compartment, which are mechanically coupled between the substantially concave articular surface and the implant surface. The first set of sensors is configured to detect information indicative of a first portion of a force present at a first area of the substantially concave articular surface. The force sensing module also includes a second set of sensors disposed within the compartment, which are mechanically coupled between the substantially concave articular surface and the implant surface.

Abstract: A force sensing module for measuring performance parameters associated with an orthopedic articular joint is disclosed. The force sensing module includes a housing having a substantially concave articular surface and an implant surface, the substantially concave articular surface and the implant surface defining a compartment therebetween. The force sensing module also includes a first set of sensors disposed within the compartment, which are mechanically coupled between the substantially concave articular surface and the implant surface. The first set of sensors is configured to detect information indicative of a first portion of a force present at a first area of the substantially concave articular surface. The force sensing module also includes a second set of sensors disposed within the compartment, which are mechanically coupled between the substantially concave articular surface and the implant surface.

Abstract: A knee balancing system for measuring performance parameters associated with an orthopedic articular joint comprises a force sensing module and one or more inertial measurement units. The force sensing module comprises a housing that includes an articular surface having a medial portion and a lateral portion, each of which is substantially mechanically isolated from the other. The force sensing module also includes first and second sets of sensors disposed within the housing. The first set of sensors is mechanically coupled to the medial portion of the articular surface and configured to detect information indicative of a first force incident upon the medial portion of the articular surface. The second set of sensors is mechanically coupled to the lateral portion of the articular surface and configured to detect information indicative of a second force incident upon a lateral portion of the articular surface.

Abstract: A knee balancing system for measuring performance parameters associated with an orthopedic articular joint comprises a force sensing module and one or more inertial measurement units. The force sensing module comprises a housing that includes an articular surface having a medial portion and a lateral portion, each of which is substantially mechanically isolated from the other. The force sensing module also includes first and second sets of sensors disposed within the housing. The first set of sensors is mechanically coupled to the medial portion of the articular surface and configured to detect information indicative of a first force incident upon the medial portion of the articular surface. The second set of sensors is mechanically coupled to the lateral portion of the articular surface and configured to detect information indicative of a second force incident upon a lateral portion of the articular surface.

Abstract: A knee balancing system for measuring performance parameters associated with an orthopedic articular joint comprises a force sensing module and one or more inertial measurement units. The force sensing module comprises a housing that includes an articular surface having a medial portion and a lateral portion, each of which is substantially mechanically isolated from the other. The force sensing module also includes first and second sets of sensors disposed within the housing. The first set of sensors is mechanically coupled to the medial portion of the articular surface and configured to detect information indicative of a first force incident upon the medial portion of the articular surface. The second set of sensors is mechanically coupled to the lateral portion of the articular surface and configured to detect information indicative of a second force incident upon a lateral portion of the articular surface.

Abstract: A force sensing module for measuring performance parameters associated with an orthopedic articular joint is disclosed. The force sensing module includes a housing having a substantially concave articular surface and an implant surface, the substantially concave articular surface and the implant surface defining a compartment therebetween. The force sensing module also includes a first set of sensors disposed within the compartment, which are mechanically coupled between the substantially concave articular surface and the implant surface. The first set of sensors is configured to detect information indicative of a first portion of a force present at a first area of the substantially concave articular surface. The force sensing module also includes a second set of sensors disposed within the compartment, which are mechanically coupled between the substantially concave articular surface and the implant surface.