A device for prosthetic vision rehabilitation, which includes a scleral explant with a shape that is suitable for being in contact with at least one portion of the sclera of an eye, and at least one inducer arranged on the scleral explant.

Intraocular apparatus is provided for be implantation entirely in a subject's eye. The intraocular apparatus includes a photosensor array including a plurality of photosensors configured to receive an ambient image, and a power source, for powering the apparatus. The intraocular apparatus additionally including a flexible 0.4-3 mm electrical connector, connecting the photosensor array to the power source. Other applications are also described.

An electrode system for treating dry eye, including at least one electrode having a portion intended to be applied in contact with the eye, the eye orbit, the temple, the eyelid areas or a part of them that respectively imitates the shape of the eye surface, the eye orbit, the temple, the eyelid areas or a part of them or wherein the portion of the intended to be applied in contact with the eye, the eye orbit, the temple, the eyelid areas or a part of them has a flexible and adaptable shape so that a form-fit is achievable between the portion of the electrode and the surface shape of the eye, the eye orbit, the temple, the eyelid areas or a part of them. The portion of the electrode is fed with an electromagnetic wave of distorted sinusoidal current with a resonance frequency which includes the related harmonics.

Apparatus is provided that includes a retinal stimulator, which includes an electrode array including electrodes, which are configured to be coupled to a retina of a subject's eye; and driving circuitry, configured to drive the electrodes to apply currents to the retina. The retinal stimulator further includes an elastic anchor that is coupled to the retinal stimulator and is configured to anchor the electrodes to the retina without the elastic anchor penetrating the retina. Other embodiments are also described.

Implantable devices, such as artificial organs, increasingly incorporate hardware, software, firmware, and/or wireless communication capabilities. For example, such implantable devices can utilize wireless technology to allow for efficient configuration, maintenance, and operational analysis. As these implantable devices become more connected, electronic security will become more important. This disclosure relates to implantable devices that may utilize a secure boot process and secure communication, both between artificial devices in the human body and between these devices and the external world. This disclosure provides secure communication approaches for maintaining the digital privacy and integrity of artificial devices, for protecting the individual from malicious hacking of data, and for controlling of such implantable devices.

A system and method for electrical stimulation of the human body, and in particular, to systems and methods for electrode systems and signal delivery used in electrical-stimulation treatment, testing and monitoring of vision problems of a patient, analyzing the results of the treatments, and monitoring to determine, for example, whether a medical treatment for the patient needs to be continued and/or altered, wherein the design and placement of the electrode systems and adjustment of signals delivered to the electrodes facilitate adjustment of the geometry of signal flow through the tissues of the patient.

The present disclosure is related to a treatment probe and method for treating dry eye. The treatment probe may include a thin stainless steel tip, a spacer to ensure proper contact and protect the skin of a patient, a sensor to provide temperature feedback to the power supply providing RF energy to the treatment probe. The treatment focuses on a patient's temple and periorbital area.

Described here are stimulation systems and methods for stimulating one or more anatomical targets in a patient for treatment conditions such as dry eye. The stimulation system may include a controller and a microstimulator. The components of the controller and microstimulator may be implemented in a single unit or in separate devices. When implemented separately, the controller and microstimulator may communicate wirelessly or via a wired connection. The microstimulator may generate pulses from a signal received from the controller and apply the signal via one or more electrodes to an anatomical target. In some variations, the microstimulator may include a passive generation circuit configured to generate a pulse based on a signal received from the controller.

The present invention is a new configuration for the external portion of a visual prosthesis in the form of a visor or glasses, including a frame supported by a user's nose and ears. The video processing unit is adapted to be connected by temple portions of the visor and rest on the user's upper back behind the user's neck, or behind the user's head. Controls for the video processor are on one or both temple portions of the visor.

A method, electrical tissue stimulation system, and programmer for providing therapy to a patient are provided. Electrodes are placed adjacent tissue (e.g., spinal cord tissue) of the patient, electrical stimulation energy is delivered from the electrodes to the tissue in accordance with a defined waveform, and a pulse shape of the defined waveform is modified, thereby changing the characteristics of the electrical stimulation energy delivered from the electrode(s) to the tissue. The pulse shape may be modified by selecting one of a plurality of different pulse shape types or by adjusting a time constant of the pulse shape.