Disclosed are an implantable sensor driven by an alignment key, an implantable device comprising the implantable sensor, and a biometric data measurement system comprising the implantable device. The implantable device according to the present embodiment may comprise an implantable sensor forming a magnetic dipole moment in one direction from the inside to the outside of the body, and may be inserted into the body to measure biometric data by means of the implantable sensor.

An electronic device includes a housing sidewall defining an opening and a display component, such as a display cover, disposed in the opening to form a gap between the housing sidewall and the display component. In at least one example, the cavity is defined by the sidewall and the display cover with the cavity in fluid communication with an external environment through the gap. In at least one example, an epoxy component at least partially defines the cavity and can be in direct contact with the housing sidewall.

An oximetry device sealed in a sheath directs a user to allow the oximetry device to make oximetry readings at a number of different tissue locations of a patient and average two or more of the oximetry readings by directing the lifts and placements of the oximetry device and sheath to and from the different tissue locations and detecting the lift and placements. The averages are generated and displayed on a display of the device for the oximetry readings if the lifts are made while use directions for the lifts are displayed on a display of the oximetry device. The averages are not generated if the lifts are not made while the user directions for the lifts are not displayed. The averages are simultaneously displayed with the oximetry readings which are instantaneous measurement for patient tissue.

Example headsets and electrodes are described herein. Example electrode units described herein include a housing having a cavity defined by an opening in a side of the housing and an electrode. In some such examples, the electrode includes a ring disposed in the opening and an arm, where the arm has a first portion extending outward from the opening away from the housing and a second portion extending from an end of the first portion toward the housing and into the cavity, and the first and second portions connect at a bend.

A tip electrode of a catheter includes an outer wall and a temperature sensor assembly. The outer wall includes a thermally conductive multilayer printed circuit board (TCM-PCB) that includes a void. The temperature sensor assembly, which is fitted in the void of the TCM-PCB, includes a temperature sensor, one or more thermally insulating layers that surround a volume of the temperature sensor excluding one facet of the volume, and a heat conductive layer covering the excluded facet.

A health and wellness tracking ring that can be worn by a user at all times, that is unobtrusive and that collects health and wellness data about the user providing a means for the wearer to access and utilize the collected data for continuous monitoring and improvement of the wearer's health and wellness. The ring includes a control mechanical button that is easily accessible to the user while wearing. The ring includes replaceable outer shells and includes hardware and software that allow the user to communicate with software in a computer device such as a cell phone, cloud provider, table, personal computer or AI assistant.

Methods, systems, and devices for wearable devices are described. A wearable device may include a first annular member forming the frame of the wearable device. The first annular member may include one or more deformable features that are configured to structurally weaken the frame of the wearable device and the one or more deformable features may be located along a portion of the frame. In some cases, the wearable device may include a first annular member and a second annular member to form a frame of the wearable device. The second annular member may include a non-metal material. The first annular member, the second annular member, or both, may include one or more deformable features that are configured to structurally weaken the frame of the wearable device and the one or more deformable features may be located along a portion of the frame.

An electronic device is provided. The electronic device includes a housing, a printed circuit board disposed inside the housing and including a first face and a second face that faces away from the first face, a connection member disposed on the first face and electrically connected to the printed circuit board, a switch member disposed on the first face and at least partially overlaps the connection member when viewed from above the first face, and a button member including an electrically conductive member, and disposed to be capable of operating the switch member. The electrically conductive member is electrically connected to the connection member.

A medical device includes a hybrid circuitry assembly and a core circuitry support structure. The core circuitry support structure includes a frame defining a cavity configured to receive at least a portion of the hybrid circuitry assembly. An outer surface of the frame is shaped to correspond to an inside surface of a core assembly housing configured to enclose the hybrid circuitry assembly and the core circuitry support structure.

A wearable biofluid volume and composition system includes a microfluidic flexible fluid capture substrate having a microfluidic channel configured as a sweat collection channel and is configured to be worn on a human body and to collect and analyze biofluid. The microfluidic flexible fluid capture substrate further has a plurality of conductive traces and electrodes. An electronic module is attached to the microfluidic flexible fluid capture substrate and is configured to measure and analyze data from the biofluid collected by the microfluidic flexible fluid capture substrate and to transmit the analyzed data to a smart device.