A method for checking vital parameters. A quantitative determination of distance and/or thickness of components of the eye is performed on the basis of data of a laser feedback interferometry measurement of a human eye. A change of at least one vital parameter is ascertained in the ascertainment of a change over time of a determined distance and/or of a determined thickness of a component of the eye. The components of the eye comprising at least a cornea and/or an iris and/or a pupil and/or a lens and/or a vitreous body and/or a retina. The vital parameter comprising an eye pressure and/or a high blood pressure and/or an arteriosclerosis and/or a metabolism and/or an abnormality of the retina in terms of color or topography and/or a blood clot. A device for checking vital parameters is also described.

The invention relates to a method and a computer program for automatic shape quantification of an optic nerve head from three-dimensional image data (1) acquired with optical coherence tomography, comprising the steps of: a) Providing (100) three-dimensional image data (1) of the retina, the image data comprising at least a portion of the optic nerve head, wherein the image data comprises pixels with associated pixel values; b) In the three-dimensional image data (1) identifying (200, 300) anatomic portions of the optic nerve head, the anatomic portions comprising a retinal pigment epithelium (RPE) portion (3) and an inner limiting membrane (ILM) portion (2); c) Determining an RPE polygon mesh (30) for a lower boundary of the retinal pigment epithelium portion (3), wherein the RPE polygon mesh (30) extends along the lower boundary of the retinal pigment epithelium portion (3); d) Determining an ILM polygon mesh (20) for the inner limiting membrane portion (2), wherein the ILM polygon mesh (20) extends along the inner limiting membrane portion (2); e) Determining a morphologic parameter (10) of the optic nerve head from the RPE polygon mesh (30) and the ILM polygon mesh (20); f) Displaying the morphologic parameter (10) of the optic nerve head and/or a representation of at least a portion of the RPE polygon mesh (30) and/or a representation of at least a portion of the ILM polygon mesh (20).

Described herein are an apparatus, system, and method for detecting light. An apparatus can include means for modulating an input beam of light wherein the input beam of light is obtained from an optical coherence tomography arrangement; means for dispersing the modulated beam of light; and means for detecting the dispersed beam of light and converting the detected beam of light into an electrical output signal. An apparatus can include a modulator configured to spatially modulate light; a dispersing element configured to disperse modulated light, and a detector configured to detect dispersed light and convert the detected light into electrical output signals. A method can include spatially modulating a beam of light, dispersing the modulated beam of light, detecting the dispersed beam of light, converting the detecting beam of light into electrical output signals, and providing a three-dimensional image of at least a part of an object.

Systems and methods for providing surface contrast to display images for microsurgical applications are disclosed. According to an aspect, an imaging system includes an OCT apparatus configured to capture OCT data of an eye. The OCT image data can include depth-resolved images of reflected light intensity over a period of time. The imaging system also includes a controller configured to determine movement of the eye relative to the OCT imaging field-of-view. The controller may also determine a location within the imaged portion of the eye which tracks with the eye movement. Further, the controller may apply a color gradient to render OCT images of the eye based on a position relative to the determined location of the eye tracking location. The controller may also control a display to display the OCT images with the applied color gradient.

A system for preventing motion sickness resulting from virtual reality or augmented reality is disclosed herein. In one embodiment, the system includes a virtual reality or augmented reality headset configured to be worn by a user, the virtual reality or augmented reality headset configured to create an artificial environment and/or immersive environment for the user; at least one fluidic lens disposed between an eye of the user and a screen of the virtual reality or augmented reality headset; and a fluid control system operatively coupled to the at least one fluidic lens. In another embodiment, the system includes at least one tunable prism disposed between an eye of the user and a screen of the virtual reality or augmented reality headset, the at least one tunable prism configured to correct a convergence problem associated with the eye of the user.

An OCT system for measuring a retina as part of an eye health monitoring and diagnosis system. The OCT system includes an OCT interferometer, where the interferometer comprises a light source or measurement beam and a scanner for moving the beam on the retina of a patient's eye, and a processor configured to execute instructions to cause the scanner to move the measurement beam on the retina in a scan pattern. The scan pattern is a continuous pattern that includes a plurality of lobes. The measurement beam may be caused to move on the retina by the motion of a mirror that intercepts and redirects the measurement beam. The mirror position may be altered by the application of a drive signal to one or more actuators that respond to the drive signal by rotating the mirror about an axis or axes.

A method for differentiating between papilledema and pseudopapilledema involves identifying a subject with an elevated optic nerve, and detecting in the subject a retinal nerve fiber layer (RNFL) thickness at each of twelve clock-hour positions using optical coherence tomography (OCT).

Handheld optical imaging devices and methods are disclosed herein. In an embodiment, an optical coherence tomography (OCT) system includes an OCT probe that is configured as a hand-held probe for imaging an eye of a patient, the OCT probe includes: an OCT optical system configured to direct a source OCT signal to the eye and configured to capture OCT scan signal returning from the eye; and an on-probe display carried by a handle, wherein the on-probe display is configured to display imaging data of the eye of a patient to an operator during OCT imaging.

An OCT apparatus includes an OCT optical system that has a light splitter splitting light from an OCT light source to light travelling to a measurement light path and light travelling to a reference light path and a detector detecting a spectrum interference signal of measurement light guided to a subject eye through the measurement light path and reference light from the reference light path, and a processing unit that processes the spectrum interference signal to generate OCT data. The processing unit performs at least complementary processing on an overlapping region of a real image and a virtual image in OCT data based on a plurality of OCT data obtained with different optical path lengths when detecting the spectrum interference signal, and generates OCT data subjected to the complementary processing.

Improved optical coherence tomography systems and methods to measure thickness of the retina are presented. The systems may be compact, handheld, provide in-home monitoring, allow the patient to measure himself or herself, and be robust enough to be dropped while still measuring the retina reliably.