Apparatus for evoking and sensing ophthalmic physiological signals in an eye, the apparatus comprising: an elongated light pipe having a longitudinal axis, a distal end and a proximal end, the distal end terminating in a spheroidal recess; and an electrode having a distal end and a proximal end, the electrode being mounted to the elongated light pipe and extending proximally along the elongated light pipe so that the distal end of the electrode terminates at the spheroidal recess at the distal end of the elongated light pipe.

A training apparatus has an input device and a wearable computing device with a bio-signal sensor and a display to provide an interactive virtual reality (“VR”) environment for a user. The bio-signal sensor receives bio-signal data from the user. The user interacts with content that is presented in the VR environment. The user interactions and bio-signal data are scored with a user state score and a performance scored. Feedback is given to the user based on the scores in furtherance of training. The feedback may update the VR environment and may trigger additional VR events to continue training.

Disclosed is electrical stimulation apparatus and an associated method for delivering therapy to an eye of a patient is disclosed, the apparatus comprising: an implantable device comprising one or more electrodes for delivering therapeutic electrical stimulation to the eye, the implantable device being configured for implanting in a suprachoroidal space between the sclera and choroid layers of the eye. Also disclosed is electroretinography (ERG) apparatus for monitoring an eye of a patient, the apparatus comprising: an implantable device comprising one or more electrodes for monitoring properties of the eye, the implantable device being configured for implanting in a suprachoroidal space between the sclera and choroid layers of the eye. Also disclosed are implantable devices, apparatuses and methods for the eye.

Disclosed is electrical apparatus for stimulating and/or monitoring an eye of a patient, comprising an implantable electrode device and a lead extending outwardly from the implantable device, the lead including a section that locates externally to the eye having at least one pre-formed bend. Also disclosed is a lead connected to an implantable electrode device, the lead having one or more stripes that extend along at least a portion of the lead. Also disclosed is an implantable device having a substrate and at least one electrode, the electrode having at least one aperture through which material of the substrate extends to anchor the electrode to the substrate. Other disclosed features relate to a foldable anchor device, a curved electrode substrate and depth markers, for example.

A multi-organ imaging system including a camera lens, a stationary, multi-examination illumination unit (SMEIU), and an attachment holder is provided. An industrial camera unit (ICU) for imaging multiple organs, for example, ear, nose, throat, and skin, is housed in a camera body. The camera lens has a fixed focal length and an iris for optimizing examination and imaging of the organs. The SMEIU is integrated to the camera body and includes illuminators arranged in a geometrical configuration. The attachment holder accommodates an organ examination attachment selected for examining an organ. The illuminators, in optical communication with one or more reflective surfaces in the organ examination attachment, produce shadowless illumination during examination and imaging of each organ, without requiring replacement of the SMEIU for examining each organ. A display unit, accommodated in a display holder detachably attached to the camera body, assists in aiming the camera lens and visualizing each organ.

The Present invention is a measuring system including a measuring device 10 that is attached to a living body, the measuring device 10 being configured to store information about an amount of electric power generated using sugars in a body fluid or bodily secretion of a living body, and a container device 15 for storing the measuring device 10, the container device 15 receiving the information about the amount of electric power generated, which is stored in the measuring device 10, using a near-field wireless communication method when the measuring device 10 is stored in the container device 15.

Disclosed herein is a contact lens. Some disclosed embodiments comprise a lenticular aspect. In some instances the lenticular aspect varies in at least one of thickness, distance from the edge of the contact lens, or lenticular height along its length. In one aspect, a superior portion of the lenticular aspect attaches to an upper eyelid of a wearer by at least a portion of the lenticular aspect interacting with an upper tarsal plate of the upper eyelid of a wearer.

A modular system can be used with commercial eyeglasses to interface with an electronic eye-mounted ocular device and used to control and/or actuate the electronic eye-mounted ocular device, exchange data with the electronic eye-mounted ocular device, and/or charge the electronic eye-mounted ocular device. The modular system includes an electroactive stick-on component attachable to a portion of an eyeglasses lens; and an electronic system attachable to an eyeglass frame in electrical communication with the electroactive stick-on component.

A device (10) configured to detect the presence of metal artifacts in a patient's eye includes a head mount (14) configured to receive at least a portion of the patient's head. At least one inductor coil (12) is disposed on or in the head mount and positioned to inductively couple with at least one eye of the patient's head received into the head mount. An inductance meter (18) is operably connected to the at least one inductor coil to measure an inductance as a change of frequency of the at least one inductor coil. A processor (22) is programmed to: determine whether the inductance is greater than an inductance threshold value; and generate an indication of at least one metal artifact when the inductance is greater than the inductance threshold value. A display component (24) is configured to display the indication.

In an embodiment, a data processing method comprises receiving, from a portable physiological measuring device configured for temporary attachment to a human body, data representing one or more physiological metrics or parameters of the body; receiving, from one or more Doppler vascular sensors configured for temporary attachment to peripheral artery locations of the body and a portable Doppler vascular signal measuring device coupled to the Doppler vascular sensors, vascular function information for the body; inputting the data representing the physiological metrics or parameters and vascular function data, to a plurality of algorithms; analyzing and correlating the data representing the physiological metrics or parameters with the vascular function data based on the plurality of algorithms; generating and providing output records specifying one or more recommendations of response treatment, reports, animations, or figures based on the plurality of algorithms; and wherein the method is performed by one or more computing devices.