A wireless surgical loupe enables a user to use the wireless loupe to perform a procedure, transmit information acquired by the wireless loupe and display patient information on a wireless loupe display. The transmitted information is able to be used to aid the operating room procedure, enhance education and be recorded for later use.

An aesthetic treatment device uses multiple light sources, lasers or LEDs focused on the treatment area from different directions. The multiple light sources for treatment purposes could have the same wavelength or different wavelengths each optimized for a different application. Target selection is performed by a dual wavelength smart illumination system combined with an imaging system, a smart processor for target recognition and a scanning system that directs the focused light from laser sources to an automatically selected treatment area. A motorized optical system performs a dual role of: focusing the laser sources and also steering the focused light to specific locations as designated by the imaging and processing systems.

A contact lens for use with a surgical microscope may be equipped with an anti-fogging device to prevent obscuring the view of a surgeon due to condensation during ophthalmic surgery. The anti-fogging device may deliver thermal energy to a surface of the contact lens to heat the contact lens above an ambient dew point. The thermal energy may be delivered by an air duct with a fan nozzle, a fluid duct in thermodynamic contact with the contact lens circulating a heat transfer fluid, or generated with electrical energy to an electrical heating element disposed on the surface of the contact lens. The thermal or electrical energy may be delivered via a handle for supporting the contact lens during surgery.

The present invention provides compositions and methods for imaging, for example, tumor resections.

A surgical tray system is disclosed. The system includes a tray for use in an operating room environment. In various embodiments, the tray includes an indentation having a bowl shape. A vacuum sealed bag is fitted over the tray and form fitted to the tray when the air is removed from within the bag. The tray optionally includes an light source for illuminating an area under the tray, a magnification element, and pouches for storing items used during a surgical procedure. The tray is optionally substantially transparent to allow light to pass through the tray. The tray is ideally positioned over a patient bed. It may be mounted via an arm to a bed frame member, a monitor station, or a ceiling fixture.

A digital magnifier monocle may include an eyepiece, a lens, an organic light-emitting diode screen placed between the eyepiece and the lens, and a first electronic module for the generation of a digital image. The first electronic module may be placed between the screen and the lens. The monocle may also have a second electronic module placed between the screen and the first electronic module. The second electronic module may be divided into a first unit configured for the transmission of a digital image from the first electronic module to the screen, and a second unit configured for connection with an augmented reality engine and/or the transmission of said at least one digital image from the monocle to a unit outside of the monocle. The unit external to the monocle being may be designed for the storage of the image.

Stereoscopic system including a portal component, first sensor and first cable, second sensor and second cable, first display and second display. The portal component includes an axis, a first channel and second channel extending along the axis. The first sensor is secured within the first channel at a first angle with respect to the axis and directed inwardly toward a location. The first cable extends from the first sensor. The second sensor is secured within the second channel at a second angle with respect to the axis and directed inwardly toward the location. The first angle and second angle converge at the location to define a depth of perception. The second cable extends from the second sensor. The first display structure is disposed in proximity to a left aperture of an eyeframe, and the second display structure is disposed in proximity to a right aperture of the eyeframe.

The present disclosure relates generally a hand-centric controller that provides a user (e.g., surgeon) with the ability to control a number of microscope movement controls, non-movement microscope controls, image and color controls, media controls, and hyperspectral controls without having to reach beyond the space surrounding the surgical tool being used or the space surrounding the surgeon's hands. In some embodiments, the hand-centric controller is a limited button (e.g., one, two, three buttons) controller. In other embodiments, the hand-centric controller is an extended hand-centric controller. The hand-centric controller may be configured to provide microscope movement (e.g., x-y axis movement, lock-to-target movement, yaw movement, physical focus movement, and gross general movement), non-movement microscope control (e.g., zoom, focus, autofocus, and white light), image and color controls (e.g., next image and previous image modes), media controls (e.g., snapshot control, stop and start recording modes), and hyperspectral controls (e.g., DIR 800 on/off, light control, and playback, and DUV 400 on/off and light control).

The present disclosure is directed to augmented reality navigation systems and methods of their use that, inter alia, address the need for systems and methods of robotic surgical system navigation with reduced distraction to surgeons. Augmented reality navigation systems disclosed herein enable a surgeon to maintain focus on a surgical site and/or surgical tool being used in a surgical procedure while obtaining a wide range of navigational information relevant to the procedure. Navigational information can appear in the augmented reality navigation system as being presented on virtual displays that sit in a natural field of view of a surgeon during a procedure. Navigational information can also appear to be overlaid over a patient’s anatomy. Augmented reality navigation systems comprise a head mounted display comprising an at least partially transparent display screen, at least one detector connected to the head mounted display for identifying real-world features, and a computer subsystem.

A hand-held gripping device that allows a surgeon to reach interior portions of a person's anatomy, includes a gripping portion having a pair of jaws and/or nets movable relative to each other between fully clamped and fully opened positions thereof, a handle portion spaced apart from the jaw portion by a bendable central portion that is hollow and corrugated, with a cord extending therethrough.