A headrest for an ophthalmic instrument facilitates fine positioning of the instrument relative to an eye of a test subject without the need to remove a contact element of the headrest from contact with the test subject's face. The ophthalmic instrument may be, for example, a rebound tonometer or a non-contact tonometer. The headrest includes a hollow bulbous contact element formed of resiliently deformable material, for example a thermoplastic elastomer (TPE) or silicone rubber. An outer surface of the contact element may have a spherical shape or a spheroidal shape when the contact element is not deformed.

An intraocular pressure (IOP) measurement system. An ultrasound pressure sensor is implantable in an eye, wherein the sensor has a sealed cavity that changes shape as a function of IOP of the eye. An ultrasound transmitter emits an incident ultrasound beam. A receiver produces an output signal in response to receiving a reflected ultrasound beam. A spectrometer is configured to estimate the IOP of the eye based on processing the output signal of the receiver. Other aspects are also described and claimed.

An intraocular pressure (IOP) measurement system. An ultrasound pressure sensor is implantable in an eye, wherein the sensor has a sealed cavity that changes shape as a function of IOP of the eye. An ultrasound transmitter emits an incident ultrasound beam. A receiver produces an output signal in response to receiving a reflected ultrasound beam. A spectrometer is configured to estimate the IOP of the eye based on processing the output signal of the receiver. Other aspects are also described and claimed.

An injector (1) for implanting a sensor implant (2) in the human or animal eye, in particular for the suprachoroidal implantation of a pressure sensor for the wireless measurement of the intraocular pressure, is improved in terms of rapid, complication-free, low-trauma and low-wear suprachoroidal implantation in that, to accommodate the sensor implant, the injector (1) has a substantially tubular injection chamber (8), the inner wall surfaces (9, 10) of which have a non-rotationally symmetrical cross section, preferably an oval or rectangular cross section, in that, at a free end, the injection chamber (8) is provided with an injection opening (13), through which, during implantation, the sensor implant (2) can slide out and slide into a sclera incision in the eye, wherein the inner wall surfaces (9, 10) of the injection chamber (8) enclose the likewise non-rotationally symmetrical cross section of the sensor implant (8) and prevent a rotation of the sensor implant (2) about an axis of rotation extending in the direction of the injection (11).

An injector (1) for implanting a sensor implant (2) in the human or animal eye, in particular for the suprachoroidal implantation of a pressure sensor for the wireless measurement of the intraocular pressure, is improved in terms of rapid, complication-free, low-trauma and low-wear suprachoroidal implantation in that, to accommodate the sensor implant, the injector (1) has a substantially tubular injection chamber (8), the inner wall surfaces (9, 10) of which have a non-rotationally symmetrical cross section, preferably an oval or rectangular cross section, in that, at a free end, the injection chamber (8) is provided with an injection opening (13), through which, during implantation, the sensor implant (2) can slide out and slide into a sclera incision in the eye, wherein the inner wall surfaces (9, 10) of the injection chamber (8) enclose the likewise non-rotationally symmetrical cross section of the sensor implant (8) and prevent a rotation of the sensor implant (2) about an axis of rotation extending in the direction of the injection (11).

A depth detection apparatus, in particular in intracorneal dissection, provides a perforating tubular element suitable for being inserted into the cornea, a reciprocally moving air volume generator (14) connected to the perforating tubular element, a pressure sensor for detecting the pressure along the connection between the volumetric generator and the perforating element in the reciprocal movement of the volumetric generator, a microcontroller connected to the pressure sensor to detect pressure variations with the depth advancement into the cornea of the perforating element, a signaller connected to the microcontroller to signal that a preset pressure variation has been reached. The apparatus enables a correct position to be determined for performing intracorneal dissection.

A contact lens according to an embodiment of the present disclosure includes: a lens section that is worn on an eyeball; an acquisition section that is provided in the lens section and acquires biological information; and an output section that outputs the biological information acquired by the acquisition section to an external apparatus to be worn on a human body. The output section has one or a plurality of coil antennas extending along a front surface of the lens section, and a capacitor that is coupled to the one or the plurality of coil antennas in series or in parallel.

A contact lens according to an embodiment of the present disclosure includes: a lens section that is worn on an eyeball; an acquisition section that is provided in the lens section and acquires biological information; and an output section that outputs the biological information acquired by the acquisition section to an external apparatus to be worn on a human body. The output section has one or a plurality of coil antennas extending along a front surface of the lens section, and a capacitor that is coupled to the one or the plurality of coil antennas in series or in parallel.

A pneumatic esthesiometer adapted for measuring tactile sensitivity of a patient eye may include a pressurized gas supply system, a control system, and a pulse-conditioner. The pressurized gas supply system is configured to provide a flow of pressurized gases. The control system is configured to control the flow of pressurized gases.

Systems and methods are described for determining an intraocular pressure (IOP) of an eye using a contact lens with a magnet placed on the cornea of the eye. A magnetic field is exerted on the magnet of the contact lens, and the magnet is displaced by the magnetic field. The system of the present disclosure determines the deflection of the cornea based on the magnetic displacement of the magnet and determines the IOP of the eye.