Abstract: A keratometer for intra-surgery measurements mounted under a surgical microscope includes a Placido ring illuminating a patient's eye; a video camera; a beamsplitter directing a Purkinje image of the Placido ring to the video camera; a fixation light directing a beam for patient eye fixation, fixation confirmation or creating a red reflex effect to enhance IOL imaging and cataract visualization; a processor configured to determine the refractive characteristics and keratometer parameters of the patient's eye and to execute a digital image enhancement method to outline IOL features to help IOL alignment; and a digital display displaying the keratometer parameters and surgical guidance information for a surgeon.

Abstract: A surgical laser capsulorhexis system includes a laser source, configured to generate a laser cutting beam; a beam guidance system, configured to guide the laser cutting beam from the laser source; a beam focuser, configured to guide the laser cutting beam from the laser source and to generate a focused laser cutting beam, the focused laser cutting beam having a two-dimensional beam pattern; a beam coupler, configured to redirect the focused laser cutting beam; and a patient interface lens, configured to guide the redirected focused laser cutting beam to a tissue surface of a procedure eye.

Abstract: A keratometer for intra-surgery measurements mounted under a surgical microscope includes a Placido ring illuminating a patient's eye; a video camera; a beamsplitter directing a Purkinje image of the Placido ring to the video camera; a fixation light directing a beam for patient eye fixation, fixation confirmation or creating a red reflex effect to enhance IOL imaging and cataract visualization; a processor configured to determine the refractive characteristics and keratometer parameters of the patient's eye and to execute a digital image enhancement method to outline IOL features to help IOL alignment; and a digital display displaying the keratometer parameters and surgical guidance information for a surgeon.

Abstract: A method of manufacturing an optical probe for use in ophthalmic procedures can comprise: positioning a ferrule within a proximal portion of a cannula, wherein an optical fiber extends at least partially through the ferrule towards an optical element disposed within a distal portion of the cannula; and coupling the cannula to the ferrule by applying laser energy to the cannula. An optical probe can be provided that includes a cannula including a proximal portion and a distal portion; a ferrule disposed within the proximal portion of the cannula, the cannula and the ferrule coupled together by engaged deformations in the cannula and the ferrule; and an optical fiber positioned at least partially within the optical probe, the optical fiber configured to receive a light from a light source and guide the light to an optical element positioned within the distal portion of the cannula.

Abstract: This invention describes a method and device for big data approach in integrated patient care. It combines breath and saliva chemical analysis with physical signs analysis to use big data analysis for diagnosing a disease state based on the determined concentration of the group of gas compounds and physical parameters.

Abstract: A method of manufacturing an optical probe for use in ophthalmic procedures can comprise: positioning a ferrule within a proximal portion of a cannula, wherein an optical fiber extends at least partially through the ferrule towards an optical element disposed within a distal portion of the cannula; and coupling the cannula to the ferrule by applying laser energy to the cannula. An optical probe can be provided that includes a cannula including a proximal portion and a distal portion; a ferrule disposed within the proximal portion of the cannula, the cannula and the ferrule coupled together by engaged deformations in the cannula and the ferrule; and an optical fiber positioned at least partially within the optical probe, the optical fiber configured to receive a light from a light source and guide the light to an optical element positioned within the distal portion of the cannula.

Abstract: An intraocular lens injection device comprises a tubular housing with a passageway extending along its longitudinal axis and a plunger shaft disposed within and moveable along the passageway. The tubular housing and the plunger shaft have frictional engaging features that are configured to produce a varying plunging friction as the plunger is moved along its operating range, to offset changes in the plunging resistance that arise from injecting the IOL into the eye. The variable plunging friction may include one or more step changes in unloaded plunging friction, or a curved variation in plunging friction, or both, along at least a portion of the operating range of the plunger shaft. In some embodiments, a slot of varying width in the housing frictionally engages a tab extending transversely from the plunger shaft. In others, a contoured surface on the plunger shaft frictionally engages an orifice in the tubular housing.

Abstract: Embodiments of the present invention provide a system and method for shaping an annular focal spot pattern to allow for more efficient optical coupling to a small gauge optical fiber. An embodiment of the present invention can include an illumination source operable to transmit an optical beam along an optical path, an optical fiber, and a correcting element positioned in the optical path between the illumination source and the optical fiber, the correcting element configured to reshape the optical beam to increase an amount of light received by the optical fiber.

Abstract: Embodiments of the present invention provide a system and method for shaping an annular focal spot pattern to allow for more efficient optical coupling to a small gauge optical fiber. An embodiment of the present invention can include an illumination source operable to transmit an optical beam along an optical path, an optical fiber, and a correcting element positioned in the optical path between the illumination source and the optical fiber, the correcting element configured to reshape the optical beam to increase an amount of light received by the optical fiber.

Abstract: An intraocular lens injection device comprises a tubular housing with a passageway extending along its longitudinal axis and a plunger shaft disposed within and moveable along the passageway. The tubular housing and the plunger shaft have frictional engaging features that are configured to produce a varying plunging friction as the plunger is moved along its operating range, to offset changes in the plunging resistance that arise from injecting the IOL into the eye. The variable plunging friction may comprise one or more step changes in unloaded plunging friction, or a curved variation in plunging friction, or both, along at least a portion of the operating range of the plunger shaft. In some embodiments, a slot of varying width in the housing frictionally engages a tab extending transversely from the plunger shaft. In others, a contoured surface on the plunger shaft frictionally engages an orifice in the tubular housing.