An ophthalmic image processing apparatus that processes pieces of image data of a subject eye which are acquired by a plurality of ophthalmic examination apparatuses including a first ophthalmic examination apparatus obtaining first image data of the subject eye and a second ophthalmic examination apparatus obtaining second image data of the subject eye includes: a processor; and memory storing computer readable instructions, when executed by the processor, causing the ophthalmic image processing apparatus to execute: setting process of setting image types for the first image data and the second image data that form a registration image; and image processing process of generating the registration image in which the first image data and the second image data which correspond to the image types set in the setting process are superimposed on each other, and outputting the generated registration image.

An ophthalmologic apparatus includes a device body having an eye information acquisition unit including an objective optical system configured to acquire information of a subject's eye, a drive unit configured to move the eye information acquisition unit relative to the subject's eye in upward-downward, rightward-leftward, and forward-rearward directions, and a control unit configured to control the eye information acquisition unit and the drive unit and a casing covering the device body and having an opening provided with a cover configured to cover the opening, and the cover includes a first cover portion movable to the casing in the upward-downward and rightward-leftward directions, being disposed in the opening not to move in the forward-rearward direction and a second cover portion attached to an outer periphery of the objective optical system and inserted into the first cover portion, being movable to the first cover portion in the forward-rearward direction.

An ophthalmologic apparatus includes a device body having an eye information acquisition unit including an objective optical system configured to acquire information of a subject's eye, a drive unit configured to move the eye information acquisition unit relative to the subject's eye in upward-downward, rightward-leftward, and forward-rearward directions, and a control unit configured to control the eye information acquisition unit and the drive unit and a casing covering the device body and having an opening provided with a cover configured to cover the opening, and the cover includes a first cover portion movable to the casing in the upward-downward and rightward-leftward directions, being disposed in the opening not to move in the forward-rearward direction and a second cover portion attached to an outer periphery of the objective optical system and inserted into the first cover portion, being movable to the first cover portion in the forward-rearward direction.

Implementation of a patient display in ophthalmic procedures, such as diagnostics and surgery, is disclosed herein. In an exemplary aspect, the present disclosure may be directed to an ophthalmic system. The ophthalmic system may include a patient display, a medical device, a memory, and a processor. The memory may be configured to store one or more video files that include information for a patient relating to the medical device. The processor may be configured to execute instructions to perform the following steps: receive input from an operator of a selection of at least one of the one or more video files; and display the selected at least one of the one or more video files on the patient display.

In accordance with one aspect of the present invention, an optical coherence tomography-based ophthalmic testing center system includes an optical coherence tomography instrument comprising an eyepiece for receiving at least one eye of a user or subject; a light source that outputs light that is directed through the eyepiece into the user's or subject's eye, an interferometer configured to produce optical interference using light reflected from the user's/subject's eye, an optical detector disposed so as to detect said optical interference; and a processing unit coupled to the detector. The ophthalmic testing center system can be configured to perform a multitude of self-administered functional and/or structural ophthalmic tests and output the test data

In accordance with one aspect of the present invention, an optical coherence tomography-based ophthalmic testing center system includes an optical coherence tomography instrument comprising an eyepiece for receiving at least one eye of a user or subject; a light source that outputs light that is directed through the eyepiece into the user's or subject's eye, an interferometer configured to produce optical interference using light reflected from the user's/subject's eye, an optical detector disposed so as to detect said optical interference; and a processing unit coupled to the detector. The ophthalmic testing center system can be configured to perform a multitude of self-administered functional and/or structural ophthalmic tests and output the test data

A method is provided that includes discriminating an autofluorescence (AF) response of a lens tissue of an eye due to a current level of 2-(2-furoyl)-4(5)-furanyl-1H-imidazole (FFI) in the lens tissue by interrogating a lens tissue of an eye along a visual axis of the eye by activating an illuminator for a select time to produce interrogating irradiation having a peak wavelength of 425 nm to 460 nm, the illuminator comprising at least one light source and a focal lens positioned with respect to the light source. The method also includes obtaining at least one image of the autofluorescence response of the lens tissue from a detector, the detector including a digital camera unit, analyzing the at least one image to determine a total autofluorescence index of the lens tissue, and determining a current level of FFI in the lens tissue based, at least in part, on the total autofluorescence index.

An ophthalmic and associated methods are disclosed. In one example a plurality of ophthalmic tools are located on a single cart for collecting ophthalmic data. Data may be recorded in a standardized format to aid in comparison between records in a database. In one example the standardized format facilitates fast and more accurate diagnoses of ophthalmic conditions.

An ophthalmic and associated methods are disclosed. In one example a plurality of ophthalmic tools are located on a single cart for collecting ophthalmic data. Data may be recorded in a standardized format to aid in comparison between records in a database. In one example the standardized format facilitates fast and more accurate diagnoses of ophthalmic conditions.

The eye examination kiosk and method may comprise a structure for rotating and/or translating ophthalmologic examination devices such as an auto-refractor, an auto-keratometer, a corneal topographer, a fundus camera, an external photo camera, a perimeter, a lensmeter, a specular microscope, a retinal and external eye imager, an Optical Coherence Tomographer (OCT), or a non-contact tonometer into a position such that they may be used for examination of a patient. The kiosk outer shell may comprise an opening allowing the ophthalmologic examination equipment to perform eye examinations of a patient. Eye examination results are transmitted to a remote location where they are read by a physician, who transmits examination findings and recommendations for follow up treatment to the patient. The results may include the identity of qualified physicians who practice geographically near the patient, or who are qualified to treat a patient for a specific condition indication.