The present disclosure relates to an enhanced intrauterine device. Some aspects may involve a body, at least one arm, at least one connector, a communication circuit, and a removal mechanism. The body may be inserted in a uterus. The at least one arm may in a first position extend radially from the body and in a second position be detached from the body. The at least one connector may link the at least one arm to the body such that the at least one arm remains linked to the body in both the first position and second position. The communication circuit may couple to at least one of the body and the at least one arm for responding to a first signal by transmitting a second signal. The removal mechanism may couple to body and may include a magnetic portion for removing the intrauterine device from the uterus.

Disclosed are analyte monitoring systems and methods for calibrating an analyte sensor using one or more reference measurements. These systems and methods may include using a conversion function and first sensor data to calculate a first sensor analyte level, weighting a first reference analyte measurement (RM1) and one or more previous reference analyte measurements according to a weighted average cost function, updating the conversion function using the weighted RM1 and the one or more weighted previous reference analyte measurements as calibration points, and using the updated conversion function and second sensor data to calculate a second sensor analyte level. In some aspects, the systems and methods may include updating one or more of lag parameters used to calculate the sensor analyte levels.

A system and method is outlined for a wearable external device that communicates with a fully implantable miniaturized biosensor platform providing fast spatial detection and accurate assessment of the position and orientation of the implant within highly scattering tissue. The device and method provides spatial (x, y) position, depth (z) and rotational (φ) state of the implantable biosensor platform. The spatial (x, y) position allows the ability to turn-on only one out of an entire array of LEDs that is in line-of-sight with the implant in order to conserve power. Similarly, the depth and rotational coordinates information is used to adjust the output light intensity of the selected light emitters to compensate the power delivered to the implant. The above attributes render the system compatible for usage during intense physical activity and for added user comfort through improved skin ventilation.

The invention relates to an apparatus for charging a remote feedable circuit bioelectronic implanted in a patient or in a laboratory animal, said apparatus comprising a composable container configured to define a closed environment suitable to receive a patient or a laboratory animal, said container comprising a plurality of composable walls made of a nonmagnetic material and connected to each other so as to define said closed environment, said container comprising at least one first winding whose axis is arranged in a first direction (Z) and at least one second winding whose axis is arranged in a second direction (Y) perpendicular to said first direction (Z). The apparatus further comprises a system for powering and driving the windings of the composable container, said system comprising a switching power driver for each winding, a plurality of phase locked loop circuits respectively connected to each switching power driver and connected to a programmable logic circuit of the powering and driving system, said programmable logic circuit being configured to perform a phase comparison, the programmable logic circuit being in turn connected to a microprocessor of the powering and driving system, said microprocessor being configured to provide driving signals to the windings for generating inside the container a rotating magnetic field.

The present disclosure describes aspects of injected conductive tattoos for powering implants. In some aspects, a system comprises a conductive tattoo used to efficiently transfer power wirelessly received from a transmitter outside a body to an electronic device in the body. The conductive tattoo is formed from a conductive material injected into an outermost permanent layer of the body. The conductive tattoo is configured to wirelessly receive and relay the power from the transmitter to the electronic device. In particular, the conductive tattoo may transfer the power to the electronic device over a coupling between the conductive tattoo and the electronic device.

Expandable fusion devices, systems, and methods. The expandable fusion device includes one or more integrated deployable retention spikes configured to resist expulsion of the device when installed in the intervertebral disc space. The implant may include upper and lower main endplates, an actuator assembly configured to cause an expansion in height of the upper and lower main endplates, and a sidecar assembly including a sidecar carrier, an upper carrier endplate pivotably coupled to an upper spike, and a lower carrier endplate pivotably coupled to a lower spike such that forward translation of the sidecar carrier pushes against the upper and lower carrier endplates, thereby deploying the upper and lower spikes.

A neural interface arrangement comprising: a plurality of probes for subdural implantation into or onto a human brain, each probe including at least one sensing electrode, a coil for receiving power via inductive coupling, signal processing circuitry coupled to the sensing electrode(s), and means for wirelessly transmitting data-carrying signals arising from the sensing electrode(s); an array of coils for implantation above the dura, beneath the skull, the array of coils being for inductively coupling with the coil of each of the plurality of probes, for transmitting power to the probes; and a primary (e.g. subcutaneous) coil connected to the array of coils, the primary coil being for inductively coupling with an external transmitter device, for receiving power from the external transmitter device; wherein, in use, the primary coil is operable to receive power from the external transmitter device by inductive coupling and to cause the array of coils to transmit power to the plurality of probes by inductive coupling; and wherein, in use, the plurality of probes are operable to wirelessly transmit data-carrying signals arising from the sensing electrodes.

Implantable transponders comprising no ferromagnetic parts for use in medical implants are disclosed herein. Such transponders may assist in preventing interference of transponders with medical imaging technologies. Such transponders may optionally be of a small size, and may assist in collecting and transmitting data and information regarding implanted medical devices. Methods of using such transponders, readers for detecting such transponders, and methods for using such readers are also described.

An implantable biliary or pancreatic stent for implanting in the gastrointestinal tract having a first end for placing in the bile duct or the pancreatic duct and a second end for placing in the duodenum, the first end including a pressure sensor arranged to measure bile duct or pancreatic duct pressure, respectively, and the second end including a pressure sensor arranged to measure duodenal pressure. Each pressure sensor can include an electronic circuit with electronic components and a substrate for receiving the electronic circuit and electronic components, wherein said substrate is a flexible membrane. The flexible membrane can be a sleeve surrounding the stent, or the flexible membrane can be a flexible tube that is part of a thin tube that forms the stent, in particular the flexible membrane can have a thickness of 80-150 μm. A manufacturing method is disclosed for providing said implantable biliary or pancreatic stent.

Remote measuring and sensing. Some example embodiment related to optical energy harvesting by identification device, such as infrared identification device GRID devices). Other embodiments relate to RFID device localization using low frequency source signals. Yet still other embodiments related to energy harvesting by RFID in electric fields in both conductive and non-conductive environments.