In certain embodiments, the systems, apparatus, and methods disclosed herein relate to robotic surgical systems with built-in navigation capability for patient position tracking and surgical instrument guidance during a surgical procedure, without the need for a separate navigation system. Robotic based navigation of surgical instruments during surgical procedures allows for easy registration and operative volume identification and tracking. The systems, apparatus, and methods herein allow re-registration, model updates, and operative volumes to be performed intra-operatively with minimal disruption to the surgical workflow. In certain embodiments, navigational assistance can be provided to a surgeon by displaying a surgical instrument's position relative to a patient's anatomy. Additionally, by revising pre-operatively defined data such as operative volumes, patient-robot orientation relationships, and anatomical models of the patient, a higher degree of precision and lower risk of complications and serious medical error can be achieved.

Surgical systems can include evacuation systems for evacuating smoke, fluid, and/or particulates from a surgical site. A surgical evacuation system can be intelligent and may include one or more sensors for detecting one or more properties of the surgical system, evacuation system, surgical procedure, surgical site, and/or patient tissue, for example.

A hybrid, direct-control and robotic-assisted surgical system may have a stabilizing apparatus configured to at least partially support the weight of the surgical device and having comprising a device attachment unit configured to removably receive a surgical device having an elongate shaft and a distal tip. The stabilizing apparatus can be configured to constrain movement of the device attachment unit about a remote centre of motion. A handle may be mechanically attached to the device attachment unit and manual, Cartesian movement of the handle may results in corresponding Cartesian movement of the distal tip of the surgical device. A robotic assist system may include a sensor assembly configured to monitor at least a first attribute of the handle and generate a corresponding sensor signal, a controller communicably linked to the sensor assembly to receive the sensor signal and generate a corresponding primary control signal and a powered actuation unit communicably linked to the controller to receive the primary control signal and configured to actuate an end effector of the surgical device received in the device attachment unit based on the primary control signal.

A system and method for determining position of a steerable assembly within tissue of an animal body utilizes an elongated body structure with an implement arranged at a distal end thereof, and a premagnetized material proximate to the distal end. A signal indicative of a length of insertion of the elongated body structure into the tissue is used with a signal indicative of (i) force, strain, shape of a sensor associated with the elongated body structure and/or (ii) directionality of magnetic field applied to the premagnetized material, to determine a three-dimensional (3D) trajectory of the steerable assembly. The 3D trajectory is superimposed on a 3D model of the tissue to determine position of the steerable assembly within the tissue.

A luminal structure calculation apparatus includes at least one processor including hardware. The processor acquires picked-up images at a plurality of points in time including a same site of an object acquired by an image pickup unit provided in an insertion section inserted into a lumen serving as the object and three-dimensional disposition including information concerning at least a part of a position or a direction of the image pickup unit and calculates a position of the same site based on the picked-up images at the plurality of points in time and the three-dimensional disposition to calculate a three-dimensional structure of the lumen.

An ultrasound transducer assembly that includes a piezoelectric layer configured to resonate and generate ultrasound signals around a predetermined ultrasound frequency in which the piezoelectric layer has a width to thickness ratio of at least about 0.6. A conductive matching layer is connected to the top surface of the piezoelectric layer to condition the ultrasound transducer for broad frequency bandwidth operation. A conductive backing layer is connected to the bottom surface of the piezoelectric layer. The ultrasound transducer assembly further includes a rigid body over which the conductive backing layer is positioned, the rigid body assembled for encompassing a central longitudinal axis of a catheter body. A signal and ground electrode may form a metallic layer over the top of or below each of the piezoelectric layers. Electrical waveguides may be connected to corresponding signal and ground electrodes of the transducers.

A system for tracking at least one object in computer-assisted surgery may include a processing unit and a non-transitory computer-readable memory communicatively coupled to the processing unit and comprising computer-readable program instructions executable by the processing unit for: obtaining orientation data from at least one inertial sensor unit on at least one object; concurrently obtaining position and orientation data for a robot arm relative to a frame of reference; registering the at least one object with the robot arm to determine a position of the at least one object in the frame of reference; and continuously tracking and outputting the position and orientation of the at least one object in the frame of reference, using the orientation data from the at least one inertial sensor unit on the at least one object and the position and orientation data for the robot arm.

A method includes tracking one or more of a plurality of vertebrae of a patient, planning a planned alignment of the plurality of vertebrae, creating an implant placement plan based on the planned alignment, and robotically preparing the plurality of vertebrae to receive an implant in accordance with the implant placement plan.

A surgical instrument holding device includes a holding body, an adapter, a separator, and a driving body. The holding body holds a surgical instrument. The adapter receives the surgical instrument and is disposed between the surgical instrument and the holding body. The separator is provided between the adapter and the holding body and receives the adapter. The driving body supplies a driving force to the holding body to drive the surgical instrument. The adapter includes a tubular portion through which the surgical instrument is received, and an arc shaped protrusion. The separator is arc shaped with a circumference extending from a first circumferential edge to a second circumferential edge. When the adapter is received in separator, the arc shaped protrusion engages the first circumferential edge and the second circumferential edge of the separator to restrict rotation of the adapter with respect to the separator.

A method, instructions for which are executed from a computer-readable medium, calibrates a robotic camera system having a digital camera connected to an end-effector of a serial robot. The end-effector and camera move within a robot motion coordinate frame (“robot frame”). The method includes acquiring, using the camera, a reference image of a target object on an image plane having an optical coordinate frame, and receiving input signals, including a depth measurement and joint position signals. Separate roll and pitch offsets are determined of a target point within the reference image with respect to the robot frame while moving the robot. Offsets are also determined with respect to x, y, and z axes of the robot frame while moving the robot through another motion sequence. The offsets are stored in a transformation matrix, which is used to control the robot during subsequent operation of the camera system.