Methods and systems for performing a surgery within an internal cavity of a subject are provided herein. An example method for controlling a robotic assembly of a surgical robotic system includes, while at least a portion of the robotic assembly is disposed in an interior cavity of a subject, receiving a first control mode selection input from an operator and changing a current control mode of the surgical robotic system to a first control mode in response to the first control mode selection input; while the surgical robotic system is in the first control mode, receiving a first control input from hand controllers; in response to receiving the first control input, changing a position and/or an orientation of: at least a portion of the camera assembly, of at least a portion of the robotic arm assembly, or both, while maintaining a stationary position of instrument tips of the end effectors disposed at distal ends of the robotic arms.

Connectors for connecting or linking one instrument or object to one or more other instruments or objects are disclosed herein. In some embodiments, a connector can include a first arm with a first attachment feature for attaching to a first object, such as a surgical access device, and a second arm with a second attachment feature for attaching to a second object, such as a support. The connector can have an unlocked state, in which the position and orientation of the access device can be adjusted relative to the support, and a locked state in which movement of the access device relative to the support is prevented or limited. Locking the connector can also be effective to clamp or otherwise attach the connector to the access device and the support, or said attachment can be independent of the locking of the connector.

Example embodiments relate to robotic arm assemblies. Embodiments of the robotic arm assembly include a shoulder segment and upper arm segment having a motor drive portion. Embodiments also include a shoulder coupling joint assembly connecting the upper arm segment to the shoulder segment. Shoulder coupling joint assembly includes a distal shoulder joint subassembly connected to the upper arm segment. The distal shoulder joint subassembly includes a distal shoulder joint forming a first axis. The distal shoulder joint subassembly includes a shoulder planetary gear assembly. Embodiments include an elbow coupling joint assembly connecting the upper arm segment to the forearm segment. The elbow coupling joint assembly includes a proximal elbow joint subassembly connected to the upper arm segment. The proximal elbow joint subassembly includes a proximal elbow joint forming a second axis. The proximal elbow joint subassembly includes an elbow planetary gear assembly.

A stereo microscope includes a stand, two optical image acquisition units configured to connect to the stand to capture a stereoscopic image, which define an imaging plane using two optical axes of the image acquisition units, a pair of video glasses including two optical image reproduction units, each having an optical axis and a display for reproducing an image, which together define an image plane, wherein the optical image reproduction units are arranged to produce a stereoscopic image impression, and two optical axes of the optical image reproduction units define an image reproduction plane, a detection device configured to determine spatial orientation of the video glasses, the image reproduction plane, the image plane and the imaging plane, and a control unit configured to pivot the stand so that the intersection lines of the image plane and the imaging plane on the image reproduction plane are made parallel. Methods are also disclosed.

The present invention relates to the field of medical monitoring, and in particular non-contact monitoring of one or more physiological parameters in a region of a patient during surgery. Systems, methods, and computer readable media are described for generating a pulsation field and/or a pulsation strength field of a region of interest (ROI) in a patient across a field of view of an image capture device, such as a video camera. The pulsation field and/or the pulsation strength field can be generated from changes in light intensities and/or colors of pixels in a video sequence captured by the image capture device. The pulsation field and/or the pulsation strength field can be combined with indocyanine green (ICG) information regarding ICG dye injected into the patient to identify sites where blood flow has decreased and/or ceased and that are at risk of hypoxia.

A medical observation apparatus including: an arm including a plurality of links connected to each other via a joint, the arm having at least three or more degrees of freedom implemented by a rotation operation about a rotation axis; an imaging device supported by the arm; and an arm controller that controls an operation of the arm. When a posture of the arm is in a predetermined state, and when a predetermined input for moving the arm about a rotation axis orthogonal to a second axis that is a second rotation axis from a side of the arm on which the imaging device is supported and a third axis that is a third rotation axis from the side of the arm on which the imaging device is supported is detected, the arm controller makes one of the links corresponding to the third axis rotate about the third axis.

A surgical system includes an XR headset and an XR headset controller. The XR headset is configured to be worn by a user during a surgical procedure and includes a see-through display screen configured to display an XR image for viewing by the user. The XR headset controller is configured to receive a plurality of two-dimensional (“2D”) image data associated with an anatomical structure of a patient. The XR headset controller is further configured to generate a first 2D image from the plurality of 2D image data based on a pose of the XR headset. The XR headset controller is further configured to generate a second 2D image from the plurality of 2D image data based on the pose of the XR headset. The XR headset controller is further configured to generate the XR image by displaying the first 2D image in a field of view of a first eye of the user and displaying the second 2D image in a field of view of a second eye of the user.

The disclosed technology relates to closed-loop medical imaging for a medical environment. Various embodiments provide for a surgical camera, such as an endoscopic camera, comprising one or more image sensors. The image sensors may be configured to capture multispectral image data including one or more images of biological tissue (e.g., surfaces), and may be specifically configured to capture imagery within a surgical environment. For some embodiments, different biological tissues may be visible when illuminated by different wavelengths of a multispectral light source. The wavelength setting for the multispectral light source may be determined based upon a first wavelength setting associated with a first set of multispectral image data and a second wavelength setting associated with a second set of multispectral image data.

A system includes a console assembly, a trocar assembly operably coupled to the console assembly, a camera assembly operably coupled to the console assembly having a stereoscopic camera assembly, and at least one rotational positional sensor configured to detect rotation of the stereoscopic camera assembly about at least one of a pitch axis or a yaw axis. The console assembly includes a first actuator and a first actuator pulley operable coupled to the first actuator. The trocar assembly includes a trocar having an inner and outer diameter, and a seal sub-assembly comprising at least one seal and the seal sub-assembly operably coupled to the trocar. The camera assembly includes a camera support tube having a distal and a proximal end, the stereoscopic camera operably coupled to the distal end of the support tube and a first and second camera module having a first and second optical axis.

A method, apparatus and computer readable medium for schematically representing a spatial position of an instrument used in a robotic surgery system is disclosed. The instrument includes an end effector coupled to a positioning device for spatially positioning the end effector in a surgical workspace in response to input signals generated by movement of a hand controller of an input device in an input device workspace. The method involves causing a processor circuit to calculate a current three-dimensional spatial position of the instrument within the surgical workspace for current input signals received from the input device. The method also involves causing the processor circuit to generate display signals for displaying a graphical depiction of the surgical workspace on a display in communication with the processor circuit, the graphical depiction including a planar representation includes an instrument movement region having a boundary indicating limitations to transverse movement of the instrument within the surgical workspace, and a two-dimensional projection of the current spatial position of the positioning device and the end effector onto the planar representation.