Abstract: Systems and methods for controlling a robotic arm are provided. A breathing pattern of a patient may be controlled and a sample of the breathing pattern may be obtained. A pattern of movement of an anatomical element based on the sample may be determined. A trajectory of a robotic arm may be adjusted based on the pattern of movement.

Abstract: A system according to at least one embodiment of the present disclosure includes a processor; and a memory storing instructions thereon that, when executed by the processor, cause the processor to: receive, from an inertial sensor disposed proximate an anatomical element, a reading indicative of a first movement of the anatomical element; determine a second movement of a fiducial marker being positioned with a known physical relationship to the inertial sensor; and determine, based on the first movement and the second movement, a change in pose of the anatomical element.

Abstract: Provided herein is an insert chip and a cell culture system including the same, adapted for culturing a plurality of cell populations under various flow patterns.

Abstract: A robotic surgical system according to at least one embodiment of the present disclosure includes a first robot arm coupled to a second robot arm, where a surgical tool is attached to the first robot arm and an ultrasonic sensor is attached to the second robot arm. Accordingly, when the first robot arm is moved to position the surgical tool adjacent a target site of a patient, the second robot arm is also moved to position the ultrasonic sensor adjacent the surgical tool and the target site. In some examples, images generated by the ultrasonic sensor may be used to determine layers of fascia of the patient at the target site. Subsequently, the surgical tool may move through the layers of fascia while continuing to receive real-time images of the tissue displacement instrument relative to the target site from the ultrasonic sensor.

Abstract: Systems, methods and devices for performing a surgical procedure using a virtual guide are provided. The system may include a display configured to display an augmented image in an environment. A surgical landmark may be tracked and a parameter of the surgical landmark may be determined. A virtual guide for presentation within the augmented image may be generated and the display may present the virtual guide within the augmented image.

Abstract: A system comprises a robotic arm in a robotic arm coordinate system, a camera in a fixed pose in a navigation coordinate system, at least one processor, and memory including instructions that when executed by the at least one processor, cause the at least one processor to determine a pose of the robotic arm within the navigation coordinate system, map the robotic arm coordinate system to the navigation coordinate system based on the pose of the robotic arm, and control, based on output of the camera, the robotic arm in the navigation coordinate system.