Devices and methods for treating rhinitis are described where the devices are configured to ablate a single nerve branch or multiple nerve branches of the posterior nasal nerves located within the nasal cavity. A surgical probe may be inserted into the sub-mucosal space of a lateral nasal wall and advanced towards a posterior nasal nerve associated with a middle nasal turbinate or an inferior nasal turbinate into a position proximate to the posterior nasal nerve where neuroablation of the posterior nasal nerve may be performed with the surgical probe. The probe device may utilize a visible light beacon that provides trans-illumination of the sub-mucosal tissue or an expandable structure disposed in the vicinity of the distal end of the probe shaft to enable the surgeon to visualize the sub-mucosal position of the distal end of the surgical probe from inside the nasal cavity using, e.g., an endoscope.

Example embodiments relate to surgical systems having end-effector assembly, first and second arm assemblies, and elbow joint assembly. End-effector assembly includes instrument assembly and wrist assembly. Instrument assembly includes a first instrument. First arm assembly includes a body, first and second instrument drive assemblies, wrist drive assembly, and first arm drive assembly. First instrument drive assembly is configurable to move first instrument relative to first axis. Wrist drive assembly is configurable to move instrument assembly relative second axis. First arm drive assembly is configurable to rotate end-effector assembly relative to third axis. Elbow joint assembly includes elbow pitch joint portion configurable to be driven to move first arm assembly relative to fourth axis. Elbow joint assembly also includes elbow sway joint portion configurable to be driven to move first arm assembly relative to fifth axis.

Various aspects of a system and method to process an image for generation of a three-dimensional (3D) view of an anatomical portion are disclosed herein. The system includes an image-processing device configured to receive a plurality of two-dimensional (2D) images associated of an anatomical portion, each with a first field-of-view (FOV) value. A first 3D view of the anatomical portion with a second FOV value, is generated from a 3D reconstruction of the anatomical portion. The 3D reconstruction is obtained by use of a set of 2D image frames selected from the received plurality of 2D images. The second FOV value is greater than the first FOV value of each of the plurality of 2D images of the anatomical portion. A second 3D view is generated, based on the alignment of the generated first 3D view with 3D data associated with a pre-operative state of the anatomical portion.

A surgery assisting device using augmented reality includes: a camera configured to record an affected area or a surgical site of a patient; wireless transmission equipment configured to receive and transmit an image recorded by the camera in real time; smart glasses configured to display the image transmitted by the wireless transmission equipment to a wearer; and an Augmented Reality (AR) server configured to add augmented reality to the image and provide the wearer with the augmented reality.

A method of operating a fluorescent imaging system during an open surgery procedure includes concurrently illuminating a tissue with NIR excitation light and visible light, wherein NIR fluorescent light is emitted from the tissue and collecting the NIR fluorescent light and reflected visible light that is reflected from the tissue. The method also includes blocking at least a portion of the NIR excitation light reflected from the tissue and attenuating the reflected visible light. The method further includes imaging, using a camera, the NIR fluorescent light and the attenuated reflected visible light.

Provided are systems and methods for weight-based registration of location sensors. In one aspect, a system includes an instrument and a processor configured to provide a first set of commands to drive the instrument along a first branch of the luminal network, the first branch being outside a path to a target within a model. The processor is also configured to track a set of one or more registration parameters during the driving of the instrument along the first branch and determine that the set of registration parameters satisfy a registration criterion. The processor is further configured to determine a registration between a location sensor coordinate system and a model coordinate system based on location data received from a set of location sensors during the driving of the instrument along the first branch and a second branch.

As an expert gives instructions to cause movements of their own hands transferred directly as tactile force sense while perceiving surrounding information of a collaborator on a real-time basis and watching the collaborator's line-of-sight end and movements of the collaborator's hands, the collaborator indirectly receives the instructions of the expert's manual skills, which are the expert's tacit knowledge, on a real-time basis while sharing realistic sensations with the expert who is at a remote location when the collaborator performs an act of working with their own hands.

Provided is a medical video switcher more easily operable by the user, wherein a medical video switcher 100 designates one or a plurality of input frames and one or a plurality of output frames in response to a pointing operation made on a first operation screen on which a plurality of input frames that individually correspond to a plurality of input channels and a plurality of output frames that individually correspond to a plurality of output channels are displayed; correlates one input frame to any of the output frames, in response to a pointing operation made on a second operation screen on which the input frame and the output frame designated in response to a pointing operation made on the first operation screen are displayed; and connects the input channel that corresponds to the correlated input frame and the output channel that corresponds to the output frame.

Example embodiments relate to devices and systems for performing surgical actions. The system includes an instrument arm assembly configured in a reverse configuration. The instrument arm assembly includes a securing portion, shoulder section, first arm section, second arm section, elbow joint, end effector section, and wrist joint. The shoulder section includes a first end secured to a second end of the securing portion and a second end secured to a first end of the first arm section. The elbow joint secures a second end of the first arm section to a first end of the second arm section. The reverse configuration is a configuration in which a first line drawn from the second end of the shoulder section to the first end of the first arm section is a line that points towards a first end of the securing portion.

A system and method for providing image guidance for placement of one or more medical devices at a target location. The system can determine one or more intersections between a medical device and an image region based at least in part on first emplacement data and second emplacement data. Using the determined intersections, the system can cause one or more displays to display perspective views of image guidance cues, including an intersection ghost in a virtual 3D space.