A method of assessing post SARS infection based neurological injuries using a quantitative, noninvasive, clinical objective, oculomotor, vestibular, reaction time, and cognitive response assessment protocol for evaluating post SARS infection based neurological injuries. The method comprises the steps of: coupling a VOG/VNG system to a subject wherein the VOG/VNG system is configured to present a plurality of Oculomotor, vestibular, reaction time, and cognitive tests to the subject; presenting a plurality of Oculomotor, vestibular, reaction time, and cognitive tests to the subject on the VOG/VNG system; obtaining objective physiologic responses of the patient from the plurality of Oculomotor, vestibular, reaction time, and cognitive tests to the subject via the VOG/VNG system; and using a plurality of the objective physiologic responses of the patient to assess post SARS infection based neurological injuries in the subject.

One embodiment is directed to a system comprising a head-mounted member removably coupleable to the user's head; one or more electromagnetic radiation emitters coupled to the head-mounted member and configured to emit light with at least two different wavelengths toward at least one of the eyes of the user; one or more electromagnetic radiation detectors coupled to the head-mounted member and configured to receive light reflected after encountering at least one blood vessel of the eye; and a controller operatively coupled to the one or more electromagnetic radiation emitters and detectors and configured to cause the one or more electromagnetic radiation emitters to emit pulses of light while also causing the one or more electromagnetic radiation detectors to detect levels of light absorption related to the emitted pulses of light, and to produce an output that is proportional to an oxygen saturation level in the blood vessel.

A method and apparatus of early-stage detection of glaucoma and other optic nerve or retinal diseases employs dynamic images that are processed differently by Y-like cells and X-like cells to provide a sensitive detection of early Y-like cell impairment which provides early indications of glaucoma isolated from non-specific information from X-like cells.

A target presenting apparatus includes: a display for emitting a target light flux; a concave mirror for receiving the target light flux in such a manner as to displace the target light flux from an optical axis thereof; a housing for accommodating the concave mirror and the display therein; and an optical member, placed in the housing, for guiding the target light flux from the inside to the outside of the housing to present a target to an examinee.

The multi-scale scanning imaging system (200) of the retina comprises according to an example a lighting and detection module (210) configured for emitting a lighting beam and for detecting a beam reemitted by the retina, a first scanning module (231) of the lighting beam and the reemitted beam, a first optical path, referred to as a “wide field” path, and a second optical path, referred to as a “small field” path, for focusing the lighting beam on the retina and for receiving the beam reemitted by the retina. The “wide field” path comprises a first optical system (205, 201) configured to conjugate a plane located near a plane of rotation of the scanning module and the plane (17) of the entrance pupil of the eye (10). The “small field” path comprises a wavefront correction device (250), a second optical system (257, 256, 253) configured to conjugate a plane located near a plane of rotation of the at least one first scanning module and the effective surface of the wavefront correction device, a third optical system, comprising at least part of the first optical system, configured to conjugate said effective surface (251) of the correction device and the plane of the entrance pupil of the eye. The multi-scale scanning imaging system further comprises a first optical deflection element (241) configured to send the beam reemitted by the retina on one and/or the other of the first and second imaging paths and intended to be positioned on the first imaging path, between the common part (201, 205) of the first and third optical systems and the scanning module (210), and on the second imaging path, between the common part of the first and third optical systems and the wavefront correction device.

A method implemented by computer means for calculating a lens optical system of a spectacle ophthalmic lens for a wearer. The method includes providing an aberration target lens fulfilling the requirements of: a first set of aberration data of the aberration target lens, a first set of wearing parameters of the aberration target lens, and a first set of lens parameters of the aberration target lens. The method further includes providing a distortion target consisting of target distortion values where the target distortion values are reduced or enhanced in at least a modified distortions zone when compared to the distortion values of the aberration target lens, and calculating the lens optical system by using an optimization method which jointly uses the aberration target lens and the target distortion values.

A method and system for determining visual related physical conditions of a user of a display device, determined from the user's responses to a selection of visual-tasks. A dataset is provided for correlating the user's responses with the corresponding scores, so that by measuring the degree of correlation between the user's scores and a predetermined combination of the corresponding scores, the user's visual physical condition can be determined. A system is also provided, including a user device as well as a remote server for providing visual acuity and related testing to detect certain vision deficiencies and visual related physical conditions. In addition, a user device application is provided.

A device and a method used for self-detection of eye opacities. The novel device utilizes a light source, which illuminates an orifice, to self-detect, measure, and locate an opacity's shadow projected on the retina using a grid sheet. This device monitors the early onset of eye disorders, such as cataracts, as well as post-operative detection of opacities after cataract surgery or capsulotomy. It is also portable, inexpensive, and does not require special training to utilize it.

A device and a method used for self-detection of eye opacities. The novel device utilizes a light source, which illuminates an orifice, to self-detect, measure, and locate an opacity's shadow projected on the retina using a grid sheet. This device monitors the early onset of eye disorders, such as cataracts, as well as post-operative detection of opacities after cataract surgery or capsulotomy. It is also portable, inexpensive, and does not require special training to utilize it.

In exemplary implementations of this invention, a bi-ocular apparatus presents visual stimuli to one eye of a human subject in order to relax that eye, while measuring refractive aberration of the subject's other eye. Alternately, a monocular device presents stimuli to relax an eye while testing the same eye. The apparatus induces eye relaxation by displaying virtual objects at varying apparent distances from the subject. For example, the apparatus may do so by (i) changing distance between a backlit film and a lens; (ii) using extra lenses; (iii) using an adaptive lens that changes power; (v) selecting distinct positions in a progressive or multi-focal length lens; (vi) selecting distinct optical depths by fiber optical illumination; (vii) displaying a 3D virtual image at any given apparent depth; or (viii) display both a warped version of the real world and a test image at the same time.