Abstract: Systems for guiding placement of surgical ports on a body include an image capture device configured to capture an image of an operating environment and generate image data based on the captured image, a display device, and a computing device configured to obtain information regarding a location of a surgical site within the body, receive the image data from the image capture device, generate graphical guidance for placing a surgical port on the body based on the location of the surgical site within the body and the image data, and cause the display device to display the generated graphical guidance.

Abstract: Systems for guiding placement of surgical ports on a body include an image capture device configured to capture an image of an operating environment and generate image data based on the captured image, a display device, and a computing device configured to obtain information regarding a location of a surgical site within the body, receive the image data from the image capture device, generate graphical guidance for placing a surgical port on the body based on the location of the surgical site within the body and the image data, and cause the display device to display the generated graphical guidance.

Abstract: A surgical robotic system includes an image processing device configured to receive an endoscopic video feed and generate a stereoscopic video feed with confidence shading overlays on display. The confidence shading is based on a level of confidence associated with uncertain regions within images making up the stereoscopic video feed.

Abstract: A surgical robotic system includes a control tower, a mobile cart, and a surgical console. The mobile cart is coupled to the control tower and includes a surgical robotic arm. The surgical robotic arm includes a surgical instrument and an image capture device. The surgical instrument is actuatable in response to a user input and configured to treat a target tissue in real-time. The image capture device for capturing at least one of images or video of the target tissue in real-time. The surgical console includes a user input device for generating a user input, and a controller. The controller is operably coupled to the user input device and configured to switch, based on the user input, from a first mode to a second mode, and from the second mode to the first mode.

Abstract: A position and tracking system for radio-based localization in an operating room, includes a receiver, a mobile cart, a processor, and a memory coupled to the processor. The mobile cart includes a robotic arm and a transmitter in operable communication with the receiver. The memory has instructions stored thereon which, when executed by the processor, cause the system to receive, from the transmitter, a signal including a position of the mobile carts in a 3D space based on the signal communicated by the transmitter and determine a spatial pose of the mobile carts based on the received signal.

Abstract: A method for mapping and fusing endoscopy images includes capturing a first image of an object within a surgical operative site, by a first imaging device; and capturing a second image of the object, by a second imaging device. The first image includes the first light radiating from the object, and a first reference point. The second image includes the second light radiating from the object, and a second reference point. The method further includes comparing a first location of the first reference point in the first image to a second location of the second reference point in the second image, determining a relative pose of the first imaging device to the second imaging device based on the comparing, generating an augmented image fusing the first image and the second image based on the determined relative pose, and displaying the augmented image on a display.

Abstract: An electromechanical robotic surgical instrument is provided and includes a flexible shaft defining a lumen therethrough; an end effector pivotally supported by the flexible shaft; at least one cable translatably disposed within the lumen of the flexible shaft, wherein a distal end of each cable is operatively connected to the end effector to affect a movement of the end effector in response to translation of the at least one cable, wherein the at least one cable includes metrical markings along an outer surface thereof, which metrical markings are located adjacent to the end effector; and at least one linear encoder supported by the flexible shaft and being in operative registration with the metrical markings of a respective one of the at least one cable, wherein the at least one linear encoder is configured to measure changes in the metrical markings.

Abstract: A tissue suturing guidance system includes an image capturing device, a display, and a processor in communication with the image capturing device and the display. The image capturing device is configured to capture a suture site. The display is configured to display an image of the suture site. The processor is configured to: determine, based on the image of the suture site, a geometric tissue representation of the suture site; access measured properties of the suture site; determine, based on the measured properties of the suture site, a biomechanical tissue representation of the suture site; and generate, based on the geometric tissue representation and biomechanical tissue representation of the suture site, a suturing configuration for the suture site.

Abstract: A position and tracking system for radio-based localization in an operating room, includes a receiver, a mobile cart, a processor, and a memory coupled to the processor. The mobile cart includes a robotic arm and a transmitter in operable communication with the receiver. The memory has instructions stored thereon which, when executed by the processor, cause the system to receive, from the transmitter, a signal including a position of the mobile carts in a 3D space based on the signal communicated by the transmitter and determine a spatial pose of the mobile carts based on the received signal.

Abstract: A system includes a robotic arm, an autosteroscopic display, a user image capture device, an image processor, and a controller. The robotic arm is coupled to a patient image capture device. The autostereoscopic display is configured to display an image of a surgical site obtained from the patient image capture device. The image processor is configured to identify a location of at least part of a user in an image obtained from the user image capture device. The controller is configured to, in a first mode, adjust a three dimensional aspect of the image displayed on autostereoscopic display based on the identified location, and, in a second mode, move the robotic arm or instrument based on a relationship between the identified location and the surgical site image.

Abstract: The present disclosure is directed to an augmented reality surgical system. The system includes an endoscope that captures an image of the region of interest of a patient and an ECG device that records an ECG of the patient. A controller receives the image and applies at least one image processing filter to the image. The image processing filter includes a decomposition filter that decomposes the image into frequency bands. A temporal filter is applied to the frequency bands to generate temporally filtered bands. An adder adds each band frequency band to a corresponding temporally filtered band to generate augmented bands. A reconstruction filter generates an augmented image by collapsing the augmented bands. The controller also receives the ECG and processes the augmented image with the ECG to generate an ECG filtered augmented image. A display displays the ECG filtered augmented image to a user.

Abstract: A computer-implemented method of object enhancement in endoscopy images is presented. The computer-implemented method includes capturing an image of an object within a surgical operative site, by an imaging device. The image includes a plurality of pixels. Each of the plurality of pixels includes color information. The computer-implemented method further includes accessing the image, accessing data relating to depth information about each of the pixels in the image, inputting the depth information to a machine learning algorithm, emphasizing a feature of the image based on an output of the neural network, generating an augmented image based on the emphasized feature, and displaying the augmented image on a display.

Abstract: A medical implant including an anchor portion including a plurality of arms adapted to engage an internal tissue wall of a body from two opposite faces, wherein the anchor portion is configured such that at least one of the arms does not have an entirely overlapping arm on the other side of the wall and an opening portion adapted to define an opening for blood flow through the internal tissue wall, when the anchor portion engages the wall.

Abstract: Systems and methods for surgical robotic collision detection in accordance with aspects of the present disclosure are disclosed. In various embodiments, a system for surgical robotic collision detection includes a robotic cart having a robotic arm, an imaging device supported by the robotic cart or the robotic arm, the imaging device captures images within a field of vision of the imaging device, and a controller in operable communication with the robotic arm and the imaging device. The controller includes a processor and a memory storing instructions which, when executed by the processor, causes the controller to: receive the images from the imaging device, generate a grid including a first plurality of spatial points from the images, and detect a potential collision within the field of vision based on the generated grid.

Abstract: A surgical cart includes a vertically-extending support column, a carriage movably coupled to the support column for carrying a robotic arm, and a damper assembly for dampening vibrations induced in the surgical cart.

Abstract: A medical implant including an anchor portion including a plurality of arms adapted to engage an internal tissue wall of a body from two opposite faces, wherein the anchor portion is configured such that at least one of the arms does not have an entirely overlapping arm on the other side of the wall and an opening portion adapted to define an opening for blood flow through the internal tissue wall, when the anchor portion engages the wall.

Abstract: A system includes a robotic arm, an autosteroscopic display, a user image capture device, an image processor, and a controller. The robotic arm is coupled to a patient image capture device. The autostereoscopic display is configured to display an image of a surgical site obtained from the patient image capture device. The image processor is configured to identify a location of at least part of a user in an image obtained from the user image capture device. The controller is configured to, in a first mode, adjust a three dimensional aspect of the image displayed on autostereoscopic display based on the identified location, and, in a second mode, move the robotic arm or instrument based on a relationship between the identified location and the surgical site image.

Abstract: The present disclosure is directed to systems and methods for amplifying a region of interest in a surgical environment. The system includes a stereo endoscope having a first camera and a second camera configured to obtain one or more images of the surgical environment. The system also includes a computer that has a central processing unit (CPU) configured to determine the region of interest in the surgical environment, a first controller configured to process the one or more images from the first camera to generate first amplified image(s), and a second controller configured to process the one or more images from the second camera to generate second amplified image(s). The first and second controllers process the one or more images based on the region of interest determined by the CPU. A display displays the one or more first amplified images and the one or more second amplified images.

Abstract: The present disclosure is directed to an augmented reality surgical system. The system includes an endoscope that captures an image of the region of interest of a patient and an ECG device that records an ECG of the patient. A controller receives the image and applies at least one image processing filter to the image. The image processing filter includes a decomposition filter that decomposes the image into frequency bands. A temporal filter is applied to the frequency bands to generate temporally filtered bands. An adder adds each band frequency band to a corresponding temporally filtered band to generate augmented bands. A reconstruction filter generates an augmented image by collapsing the augmented bands. The controller also receives the ECG and processes the augmented image with the ECG to generate an ECG filtered augmented image. A display displays the ECG filtered augmented image to a user.

Abstract: Systems, methods, and computer-readable media are provided for robotic surgical device control. A system is provided including a robotic arm, an autosteroscopic display, a user image capture device, an image processor, and a controller. The robotic arm is coupled to a patient image capture device. The autostereoscopic display is configured to display an image of a surgical site obtained from the patient image capture device. The image processor configured to identify a location of at least part of a user in an image obtained from the user image capture device. The controller is configured to, in a first mode, adjust a three dimensional aspect of the image displayed on autostereoscopic display based on the identified location, and, in a second mode, move the robotic arm or instrument based on a relationship between the identified location and the surgical site image.