A lens module comprises a first lens group, a second lens group and a third lens group, which are arranged from an eye fundus side to an image side in sequence. The first lens group has a positive effective focal length (EFL) and includes a first lens having two convex surfaces respectively facing the eye fundus side and the image side. The second lens group has a positive or negative EFL and includes a plurality of second lenses, wherein the second lens closest to the eye fundus side has a concave surface facing the eye fundus side. The third lens group has a positive EFL and includes a plurality of third lenses, wherein at least one third lens is a cemented lens. The abovementioned lens module decreases the volume of a lens module and reduces the ghosting effect. An eye fundus camera using the abovementioned lens module is also disclosed.

A manual image-capturing device for the registration of low-cost ophthalmological images, accessible to those countries and places that do not have access to conventional high-cost devices, wherein the device of the invention allows taking and recording images of the retina using smart mobile devices such as for example smart phones, also allowing live transmission of the ophthalmological examination.

Apparatus and techniques can include using one or more of a portable or fixed optical system to obtain images of a desired anatomical target, such as the fundus region of a human eye. The optical system can include one or more of a laser-based focusing target, a laser-based fixation target, or a removable or adjustable alignment assembly. Such an alignment assembly can provide or allow user alignment based on using anatomical landmarks other than the fundus being imaged. One or more of the apparatus or techniques can be implemented in an optical assembly included as a portion hand-held fundus camera, such as including or using a consumer or commercial digital camera to capture an image.

System and method directed towards providing full and even illumination of a patient's retina through lighting integrated into a handheld fundus lens. By integrating the lighting, the method and system reduces and even eliminate many lens artifacts and reflections. By increasing the accuracy, quality, and field of view afforded during clinical examination of the retina, the method and system will allow practitioners to make more accurate diagnoses and will increase safety during retinal surgical procedures.

System and method directed towards providing full and even illumination of a patient's retina through lighting integrated into a handheld fundus lens. By integrating the lighting, the method and system reduces and even eliminate many lens artifacts and reflections. By increasing the accuracy, quality, and field of view afforded during clinical examination of the retina, the method and system will allow practitioners to make more accurate diagnoses and will increase safety during retinal surgical procedures.

Systems and methods for binocular viewing of an eye fundus, comprising a casing that includes a first section coupled to a second section, a light source coupled to a patient-facing end of the first section and configured to provide light along a light path towards the eye fundus, and a lens receiving opening formed into a practitioner-facing end of the second section of the casing. The lens receiving opening may be configured to receive and hold a lens within the second section.

A multifunctional medical optical examination instrument including a hand-holdable portion, at least an optical examination head portion mountable on the hand-holdable portion and including at least optical examination and non-digitized viewing optics and image digitization, storage and transmission circuitry included in at least one of the hand-holdable portion and the at least optical examination head portion, the image digitization, storage and transmission circuitry being arranged to receive an image from at least a portion of the at least optical examination and non-digitized viewing optics.

Apparatus and methods of non-mydriatic fundus imaging are disclosed. Fundus imaging apparatus include an infrared light unit configured to illuminate during a fundus scan. Based on fundus scanning, a first focus position is determined. Fundus images are then captured starting at the first focus position. Focus of the fundus imaging apparatus is adjusted to a plurality of sequential diopters and images captured at each adjustment.

An illumination probe may include a handle, an optic fiber, a tube, and an illumination source connector. The tube may include a tube distal end and a tube proximal end. The tube may include a tube aperture of the tube distal end. The tube proximal end may be disposed in the handle wherein the tube distal end extends out from a distal end of the handle. The optic fiber may include an optic fiber distal end and an optic fiber proximal end. The optic fiber may be disposed in the illumination source connector, the handle, and the tube wherein the optic fiber distal end is disposed in the tube. The tube aperture may be configured to modify a property of incident illumination light.

An eye imaging apparatus can include a housing, an optical imaging system in the housing, and a light source in the housing to illuminate an eye. The optical imaging system can include an optical window at a front end of the housing with a concave front surface for receiving the eye as well as an imaging lens disposed rearward the optical window. The apparatus can comprise a light conditioning element configured to receive light from the light source and direct said light to the eye. The apparatus can further include an image sensor in the housing disposed to receive an image of the eye from the optical imaging system. In various embodiments, light conditioning element includes at least one multi-segment surface. In some embodiments, the housing is provided with at least one hermitic seal, for example, with the optical window. In some embodiments, time sequential illumination is employed.