A retinal imaging system includes an image sensor for acquiring a retinal image and a dynamic illuminator for illuminating a retina to acquire the retinal image. The dynamic illuminator includes a center baffle along with first and second illumination arrays. The center baffle extends from and surrounds an aperture through which an image path for the retinal image passes before reaching the image sensor. The first illumination array extends out from first opposing sides of the aperture along a first linear axis. The second illumination array extends out from second opposing sides of the aperture along a second linear axis that is substantially orthogonal to the first linear axis.

A mobile communication device-based corneal topography system includes an illumination system, an imaging system, a topography processor, an image sensor, and a mobile communication device. The illumination system is configured to generate an illumination pattern reflected off a cornea of a subject. The imaging system is coupled to an image sensor to capture an image of the reflected illumination pattern. A topography processor is coupled to the image sensor to process the image of the reflected illumination pattern. The mobile communications device includes a display, the mobile communications device is operatively coupled to the image sensor. The mobile communications device includes a mobile communications device (MCD) processor. A housing at least partially encloses one or more of the illumination system, the imaging system, or the topography processor.

A headrest for an ophthalmic instrument facilitates fine positioning of the instrument relative to an eye of a test subject without the need to remove a contact element of the headrest from contact with the test subject's face. The ophthalmic instrument may be, for example, a rebound tonometer or a non-contact tonometer. The headrest includes a hollow bulbous contact element formed of resiliently deformable material, for example a thermoplastic elastomer (TPE) or silicone rubber. An outer surface of the contact element may have a spherical shape or a spheroidal shape when the contact element is not deformed.

Ophthalmic imaging devices and related methods employ self-alignment of a user with an optical axis of the imaging device. An ophthalmic imaging device includes a retinal imaging assembly, a housing assembly, and a viewer assembly. The retinal imaging assembly has an optical axis. The retinal imaging assembly is attached to the housing. The housing assembly is configured to rest on a horizontal surface during operation of the retinal imaging assembly. The optical axis is oriented at an angle from the horizontal surface when the housing assembly rests on the horizontal surface. The viewer assembly is coupled with the housing assembly. The viewer assembly includes an interface surface shaped for engagement with each head of a plurality of different user's and to accommodate repositioning of the head to align a pupil of the user with the optical axis.

An integrated medical equipment for supporting medical equipment and a patient during a medical procedure. The integrated medical equipment includes a base, an adjustable chair operatively connected to the base, and an equipment support operatively connected to the base and spaced from the adjustable chair by a predetermined distance. The equipment support includes a column at the base and a tower extending generally vertically from the column. A medical device arm is operatively connected to the tower, wherein the medical device arm is motor driven to move along the generally vertical tower. A platform support arm is operatively connected to the column, wherein the platform support arm is motor driven to move generally vertically along the column.

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.

A method is disclosed for using a precision ultrasound scanning device to image the anterior segment of the human eye, automatically locate the scleral spur, and, using the scleral spur as a fiduciary, to automatically make measurements in front of and behind the iris. The scleral spur can be used as a fiduciary to make measurements that characterize the normal and abnormal shapes of components within this region of the anterior segment of the eye. One or more of the measurements of the iridocorneal angle and the anterior chamber depth can be related to other measurements behind the iris including the iris lens contact distance, the iris zonule distance and the trabecular ciliary process distance. Over a period of time, these measurements can change and can indicate a change, or be a precursor for a change, of intraocular pressure (IOP), and therefore can determine an earlier onset of glaucoma.

In the device and method, the angle of incidence of slit light onto an eye to be examined is determined from its Purkinje reflection recorded in an image by measuring the offset from the reflection to the apex of the image of the cornea. In another embodiment, Purkinje reflections of light sources arranged around the optical axis of the microscope are correlated with a reference pattern of radial stripes in order to determine the offset between the optical axis and the apex of the eye.

A perimeter, including two types: one is a fixation forcing perimeter, and the other is an objective perimeter combined with electro-physiology under forced fixation; the perimeter comprises a fixation forcing device, a display conduction device, a perimetry display device, a feedback device for recording feedback information, and a control center for controlling the perimetry display device and collecting feedback information; the fixation forcing device comprises a negative pressure ring (2) and a negative pressure tube (3), and is adsorbed to the eyeball by negative pressure; when the eyeball moves, the fixation forcing device moves synchronously, and the fixation is forced at the same position, thereby eliminating the influence of a fixation point on the examination results of the perimeter; in the objective perimeter, an electro-physiological signal after forced fixation is automatically recorded by an electro-physiological instrument, so that the subjective response of a patient is eliminated, and the examination results are objective; and the change in the field of view can be early discovered using the electro-physiological signal as an analysis indicator.

An ophthalmological topographer is disclosed. The ophthalmological topographer includes a corneal topographer and a scleral measurement device including one or more scleral projection systems. Methods of determining topography are also disclosed.