Embodiments may provide improved visual prosthesis to restore functional vision in those with partial or total blindness. In an embodiment, a system for artificial vision may comprise a camera adapted to obtain visual information corresponding to a field of view of a person, processing circuitry adapted to transform the obtained visual information to control signals for controlling artificial visual stimulation, communication circuitry adapted to transmit the control signals to an implanted device to perform artificial visual stimulation, and an implant device adapted to be implanted within a body of the person for interacting with brain tissue to perform artificial visual stimulation, wherein the implant device is adapted to receive the control signals, generate stimulation signals based on the control signals, and apply the stimulation signals to neural tissue, wherein the implant device is further adapted to apply stimulation to at least 100,000 sites of the neural tissue..

Systems and methods for psycho-signal processing. According to an aspect, a method includes receiving a visual representation of a subject. The method also includes performing a structured motion operation on the received visual representation to generate a modified visual representation of the subject. The method further includes presenting, via a user interface, the modified visual representation.

Systems and methods for data-compressive sensing in accordance with embodiments of the invention are illustrated. In one embodiment, a sensor array includes an array of sensor circuitries including a sensor and a comparator. Sensor circuitries in the array are connected via wires which form a series of wired-OR circuits. Readouts can be used to measure the signal on the wires and a decoder in communication with the readouts can be used to resolve signals sensed by particular sensors in the array and their locations.

A system comprising a biomimetic electrochemical eye (EC-EYE) and a computing device is provided. The EC-EYE comprises: an ionic liquid device; a nanowire (NW) device that comprises the plurality of NWs; and a connection device configured to provide a plurality of currents associated with the plurality of NWs to a computing device. The computing device comprises one or more processors and a display device. The one or more processors are configured to: receive the plurality of currents from the plurality of NWs via the connection device; determine a plurality of pixel characteristics associated with a plurality of pixels based on the plurality of currents from the plurality of NWs; generate an image comprising the plurality of pixels based on the plurality of pixel characteristics; and provide the image to a display device. The display device is configured to display the image.

An orbital implant includes a bladder configured to be implanted between an orbit and an eyeball of a patient. The bladder defines at least one port and at least one compartment in fluid communication with each other. The at least one compartment defines an interior volume and is configured to hold a fill material so as to be adjustable responsive to injection of fill material into the at least one compartment through the at least one port as well as removal of fill material from the at least one compartment through the at least one port. Adjustment of the interior volume is configured to reposition the eyeball.

The present invention generally relates to novel preparations of mesenchymal stromal cells (MSCs) derived from hemangioblasts, methods for obtaining such MSCs, and methods of treating a pathology using such MSCs. The methods of the present invention produce substantial numbers of MSCs having a potency-retaining youthful phenotype, which are useful in the treatment of pathologies.

The Nucleo-reticular Multi-cell Dual-system Eye Implant consists of a spherical structure with calculated and variable axial length depending on the needs required by the orbital eye socket, composed of a cell mesh with alternative designs that in turn, makes up the MMM System, in which suturing is provided in any technique, either in cases of evisceration or enucleation. Thanks to its multi-cell structural design, it favors its placement and reduces the risk of migration, extrusion, exposure and extraction. As it is an arrangement with structural holes, it provides a higher percentage of the volume for its vascularization; it also houses inside a Reticular Fibrovascular Core System, which has a structure based on multilevels equipped with micro-reticular tissue and an intra-level communication based on filaments; with the capacity to contain medicines and/or technology by presenting a dual-system of two screw-on pieces, being able to manufacture in different structural designs and biocompatible materials.

The C100 model made of polylactic acid (PLA), an ideal material for implants, consists of 100 oval cells. Since it is a light eye implant, it prevents depressure due to settlement or gravity and it can be manufactured in any size.

An orbital implant adapted for attachment to the very thin bone at the orbit rim (502), such as the zygomatic and frontal bone margin at the supero-lateral aspect (501) of the orbit (503), for the attachment of an eye prosthesis directly to distal ends of inwardly convergently orientated transdermal abutments. The orbital implant has a baseplate (100) having an orbit radius curvature and an orbit rim curvature and a plurality of microfixation apertures therethrough and the plurality of transdermal abutments are located at an inner edge of the baseplate (100).

A method and an apparatus for image recognition based on a retina prosthesis. The method includes: recognizing meaning of an image captured; and converting the meaning of the image into a corresponding meaning prompt signal and transmitting the meaning prompt signal to a corresponding retina prosthesis electrode in connection with a retina. The method can effectively improve the problem that the existing retina prosthesis cannot recognize colors or complex scenes, enhance the recognition function of the retina prosthesis, and improve the quality of life of blind patients.

An ocular prosthesis includes a display device visible at an anterior portion of the ocular prosthesis. The display device is configured to present a changeable image that represents a natural appearance and movement for a visible portion of an eyeball of a subject. A system includes, besides the ocular prosthesis, an implant marker configured to move with an orbital implant disposed in an eye socket of a subject. A method includes determining a change in orientation of an orbital implant in a subject and determining an update to a natural appearance for a visible portion of an eyeball for the subject based on the change in orientation of the orbital implant. The method also includes rendering an update to an image of the natural appearance for a display device disposed in an ocular prosthesis configured to be inserted in the subject anterior to the orbital implant.