A method may involve providing a conductive pattern on a bio-compatible layer. The conductive pattern may include a first conductive layer that comprises a first metal and a second conductive layer that comprises a second metal. The second conductive layer may be over the first conductive layer, and the first metal may be more malleable than the second metal. The method may also include mounting an electrical component to the conductive pattern to provide an electrochemical sensor. The electrochemical sensor may be configured for use in a body-mountable device.

An eye-mountable device includes a controller embedded in a polymeric material configured for mounting to a surface of an eye. The controller is electrically connected to an antenna included in the eye-mountable device. The controller is configured to: (i) receive an indication of an interrogation signal via the antenna, (ii) responsive to the interrogation signal, output a substantially unique identification sequence; and (iii) use the antenna to communicate the substantially unique identification sequence. The substantially unique identification sequence can then be used by external readers to associate the eye-mountable device with device-specific information without storing such information on the eye-mountable device.

A wearable device and external reader is provided for herein. In some embodiments of the present disclosure, the wearable device or the reader is configured to receive a level of radiant energy, detect a change in the received level of radiant energy, determine that the detected change in the received level of radiant energy is indicative of a predetermined pattern of received radiant energy, and responsively operate (or cause to be operated via the external reader) one or more external devices.

An analyte sensor and a method for making the analyte sensor are disclosed. In one aspect, the analyte sensor includes a crosslinked, hydrophilic copolymer in contact with a surface of an electrode, and an analyte sensing component embedded within the crosslinked, hydrophilic copolymer. The method of making the analyte sensor includes depositing a precursor mixture containing monomers and an analyte sensing component onto an electrode, exposing the deposited precursor mixture to a controlled environment for a specified period of time, and photopolymerizing the deposited exposed precursor mixture into a copolymer layer in contact with a surface of the electrode. Exposing the deposited precursor mixture to a controlled environment can increase the sensitivity of the sensor by reducing the thickness of the copolymer layer and/or by causing the analyte sensitive component within the copolymer layer to have a non-uniform concentration within the layer.

Example eye-mountable devices and methods for fabricating eye-mountable devices are described. A method may involve forming a first polymer layer, which defines an anterior side of the eye-mountable device and is configured to allow an analyte to diffuse therethrough. Further, the method may involve positioning a sensor apparatus on the first polymer layer, wherein the sensor apparatus comprises at least one sensor configured to detect the analyte, and wherein the at least one sensor is oriented relative to the first polymer layer to receive the analyte via diffusion through the first polymer layer. The sensor apparatus may have a height dimension of at least 50 micrometers. Still further, the method may involve forming a second polymer layer over the first polymer layer and the sensor apparatus, such that the sensor apparatus is fully enclosed by the first polymer layer and the second polymer layer.

A tear collection device comprises: a body attached to an eyeball; a tear inlet for allowing tear to flow into the body; a storing space formed inside the body and capable of storing the tears having flowed into the body; and a pump forming a pressure difference inside the body such that tears flow into the body through the tear inlet, wherein the pump is driven by using, as power, eye blinking movements of a wearer so as to form the pressure difference inside the body, thereby allowing the tears to flow into the body.

Described is a hemoglobin and hematocrit analyzer, and an analyzing method thereof. The method includes: scanning and taking an image signal of the palpebral conjunctiva of a subject by a scanning unit; receiving the image signal by an analyzing unit connected to the scanning unit; providing a default colorimetric scale by a database connected to the analyzing unit; inputting a clinical test result into the analyzing unit through an input unit connected to the analyzing unit. The image signal is transformed by the analyzing unit to a measured color value. The measured color value is compared with the default colorimetric scale to obtain a test result. The measured color value and the clinical test result are provided as feedback to the database.

An intraocular implant device for comprehensive intraocular vision advancement includes an intraocular implant body shaped for positioning inside a lens chamber of an eye. In some embodiments, the implant includes an optical adjustable base accommodating lens configured to provide both base adjustment and accommodation. In further embodiments, the implant includes a photoelectric sensor operable to receive incident light through the cornea and to convert the received light into electrical energy for use with one or more circuit components disposed on the body, and wherein the photoelectric sensor is also operable to convert the received light into image data. The ocular implant device may include a projector for projecting the image data onto the retina of a user. The ocular implant may additionally include an autofocusing digital camera, an autofocusing electromechanical lens array, and sensors for detecting glucose levels and/or intraocular eye pressure.

A device for placement in contact with an eye of a user. The device includes at least one detector for measuring at least one property, and a signal processor for determining, based on the at least one property, whether the eye of the user is closed.

An ocular device is disclosed along with methods for the employment thereof. In one aspect, a device for placement into a lacrimal punctum or conjunctival sac of a person includes one or more sensor materials responsive to one or more components of the chemical composition of the person's tears. Each sensor material is configured to present a tear-based color from a plurality of tear-based colors indicative of a medical condition of the person. In some embodiments, phenylboronic acid could be employed as a sensor material(s). In some embodiments, material(s) emitting radiation when excited by other radiation could be employed as a sensor material. In another aspect, methods for employing the ocular device are disclosed.