A surgical retractor has a shaft with an integral blade. The shaft and the blade are joined at an angle. The blade has an upper surface. A plurality of LED lights are embedded within the blade and are exposed at the upper surface. The blade surrounding the LED lights is opaque. The retractor may further include a camera mounted on the blade. Also disclosed is a surgical retractor kit including a mounting ring, at least one of the aforementioned surgical retractors, and a coupler for releaseably mounting the retractor to the ring.

An ophthalmic surgical system includes an imaging device configured to acquire a first image of a fundus of an eye and a hemorrhage detecting unit. The hemorrhage detecting unit includes a processor configured to receive the first fundus image from the imaging device, analyze the first fundus image to detect a hemorrhage in the eye, and in response to detecting the hemorrhage, send a signal to an intraocular pressure controller. The ophthalmic surgical system further includes the intraocular pressure controller, which includes a processor configured to receive the signal from the hemorrhage detecting unit, in response to the received signal, determine if a current intraoperative pressure of the eye is below a predetermined threshold, and in response to determining the current intraoperative pressure of the eye is below the predetermined threshold, generate a signal to increase the intraoperative pressure of the eye.

Medical software tools platforms utilize a surgical display to provide access to specific medical software tools, such as medically-oriented applications or widgets, that can assist surgeons or surgical team in performing various procedures. In particular, an endoscopic camera may register the momentary rise in the optical signature reflected from a tissue surface and in turn transmit it to a medical image processing system which can also receive patient heart rate data and display relevant anomalies. Changes in various spectral components and the speed at which they change in relation to a source of stimulus (heartbeat, breathing, light source modulation, etc.) may indicate the arrival of blood, contrast agents or oxygen absorption. Combinations of these may indicate various states of differing disease or margins of tumors, and so forth. Also, changes in temperatures, physical dimensions, pressures, photoacoustic pressures and the rate of change may indicate tissue anomalies in comparison to historic values.

Example embodiments relate to surgical devices, systems, and methods. The system may include a port assembly and instrument arm assembly. The port assembly may have first and second end sections. The first end section may include a first end channel and first gate assembly. The second end section may include a second end channel, second gate assembly, and anchor port. The first and second gate assemblies may be configurable to transition between an open position to allow access through the first and second end channels, respectively, and a closed position to prevent access to same. The instrument arm assembly may include a shoulder section securable to the anchor port, first arm section secured to the shoulder section, elbow section secured to the first arm section, second arm section secured to the elbow section, wrist section secured to the second arm section, and end effector section secured to the wrist section.

Methods and systems for performing an ophthalmic surgical procedure include pulsed illumination of target tissue. The systems may include an illumination instrument arranged to illuminate tissue at a surgical site during the ophthalmic surgical procedure. A light source provides illumination to the illumination instrument for emission from the illumination instrument toward the surgical site. A controller communicates with the light source and activates the light source to provide illumination pulses at a frequency above the flickering perception in humans and with enough light for cameral exposure and human light perception. The light source pulses to minimize phototoxicity.

A stereoscopic imaging platform includes a stereoscopic camera configured to record left and right images of a target site. A robotic arm is operatively connected to the stereoscopic camera, the robotic arm being adapted to selectively move the stereoscopic camera relative to the target. The stereoscopic camera includes a lens assembly having at least one lens and defining a working distance. The lens assembly has at least one focus motor adapted to move the at least one lens to selectively vary the working distance. A controller is adapted to selectively execute one or more automatic focusing modes for the stereoscopic camera. The controller has a processor and tangible, non-transitory memory on which instructions are recorded. The automatic focusing modes include a target locking mode. The target locking mode is adapted to maintain a focus of the at least one stereoscopic image while the robotic arm is moving the stereoscopic camera.

A digital loupe system is provided which can include a number of features. In one embodiment, the digital loupe system can include a stereo camera pair and a distance sensor. The system can further include a processor configured to perform a transformation to image signals from the stereo camera pair based on a distance measurement from the distance sensor and from camera calibration information. In some examples, the system can use the depth information and the calibration information to correct for parallax between the cameras to provide a multi-channel image. Ergonomic head mounting systems are also provided. In some implementations, the head mounting systems can be configurable to support the weight of a digital loupe system, including placing one or two oculars in a line of sight with an eye of a user, while improving overall ergonomics, including peripheral vision, comfort, stability, and adjustability. Methods of use are also provided.

Systems and methods used to perform non-contact patient registration of images for surgical navigation are disclosed. In some embodiments, the systems include a 3-D scanning device to capture spatial data of a region of interest of a patient and a reference frame. A digital mesh model is generated from the spatial data. A reference frame model is registered with the digital mesh model. Anatomical features of the digital mesh model and a patient registration model are utilized to register the digital mesh model with the patient registration model. A position of a surgical instrument is tracked relative to the reference frame and the patient registration model.

The present invention relates to an ophthalmic treatment device and a method of operating same, and provides an ophthalmic treatment device and a method of operating same, the device comprising: a treatment beam generating unit for generating a treatment beam; a beam delivery unit for forming a path through which the treatment beam generated by the treatment beam generating unit travels to a treatment region disposed in a fundus; a monitoring unit for irradiating a detecting beam along the path through which the treatment beam travels, and detecting information of the state of the treatment region based on interference information on the detecting beam reflected from the treatment region; and a controller for controlling the operation of the treatment beam generating unit based on information on the state of the treatment region detected by the monitoring unit.

A system for managing a user interface comprising: a first teleoperated surgical system comprising: a communications subsystem configured to receive at the first teleoperated surgical system from a second teleoperated surgical system, an environmental variable describing operation of the second teleoperated surgical system; a video subsystem to: render a local scene at the first teleoperated surgical system, the local scene representing a state of operation of the first teleoperated surgical system; render a remote scene at the first teleoperated surgical system, the remote scene representing a state of operation of the second teleoperated surgical system and the remote scene based at least in part on the environmental variable; composite the local scene and the remote scene to produce a composite scene; and present the composite scene to a user of the first teleoperated surgical system.