A device (1) for measuring, processing and transmitting implant parameters in osteosynthesis, the device (1) comprising: a biocompatible sterilizable housing (2); a strain sensor (3); an electronic unit (4) to process electrical signals provided by the strain sensor (3), wherein the housing (2) comprises (i) a measurement portion (5) of the height H5 comprising a cavity (51); and (ii) a compartment portion (6) of the height H6 with a cavity (61), and wherein the measurement portion (5) comprises at least two affixing means (7) for affixing the device (1) to an implant and wherein the electronic unit (4) is positioned in the cavity of the compartment portion (6).

A measuring apparatus (100a, 1a) includes a light source (110) configured to emit probe light; a total reflection member (16) in contact with a to-be-measured object and configured to cause total reflection of the probe light that is incident; a light intensity detector (17) configured to detect light intensity of the probe light exiting from the total reflection member (16); an output unit (2) configured to output a measurement value obtained on the basis of the light intensity; a first support (31) supporting the light source (110) and the light intensity detector (17); and a second support (32) provided to the first support (31), detachable from the first support (31), and supporting the total reflection member (16).

A medical device capable of transmitting a radiofrequency signal to and/or receiving a radiofrequency signal from an external device is provided. The medical device comprises at least one component that contains a polymer composition that exhibits a dielectric constant of about 6 or less at a frequency of 2 GHz, wherein the polymer composition includes a liquid crystalline polymer.

An analytical toilet is disclosed with a bowl adapted to receive excreta, a conduit for transporting a liquid excreta sample from the bowl, and a liquid reagent source. The analytical toilet also includes a microfluidic chip that has a sensor configured to detect at least one property of the excreta sample. The microfluidic chip also has an excreta sample path in fluid communication with the conduit and the sensor and a reagent path in fluid communication with the liquid reagent source and the sensor. The length of and number of channels in the sample path and the reagent path are selected so as to control the respective fluid resistance of the excreta sample and the reagent to thereby optimize the mixing and flow rates of the excreta sample and reagent into the sensor. There is also disclosed analytical toilet with a microfluidic chip having reagent path that includes a first and a second channel. The second channel is longer than the first channel. A valve, which is controllable so as to cause the reagent to flow through either the first channel, the second channel or both channels. As such, the fluid resistance of the reagent is controlled, to thereby optimize the flow rate of the reagent into the sensor.

A device for detection of the tactile sensitivity of a user includes a base frame and a mechanical system joined to the base frame, the mechanical system being movable relative to the base frame and having a resting area for the fingertip of at least one finger of the user. The mechanical system includes a plurality of movable plate-shaped members arranged side by side to each other so that the resting area is defined by the thicknesses of at least part of the upper edges of the plate-shaped members. Each plate-shaped member is connected to an actuator, which can be operated to independently move each plate-shaped member from a minimum height position to a maximum height position, a control unit being further provided, which is adapted to operate the actuators.

The present disclosure relates to a wearable device with a bridge portion and systems/methods relating to the device. Preferred embodiments may include two flexible wings and a bridge connecting the two wings. In some embodiments, the upper surface of the bridge can be non-adhesive and uncoupled to the flexible wing such that the flexible wing can be decoupled from the bridge when the adhesive is adhered to the surface of a user. The bridge can be narrower in some portions, and extend around the housing of the monitor. The bridge can extend beneath the housing and bisect the two flexible wings.

An electrode patch is disclosed. The electrode patch includes a substrate of which one surface has an adhesive force and extending in a first direction, a conductive first electrode disposed on one side of the substrate, and a conductive second electrode disposed on another side of the substrate and configured to be electrically separated from the first electrode. The first electrode includes a cut surface extending from a first contact portion contacting a first clamp to an inside of the first electrode, and the second electrode includes a cut surface extending from a second contact portion contacting a second clamp to an inside of the second electrode.

Devices associated with on-body analyte sensor units are disclosed. These devices include any of packaging and/or loading systems, applicators and elements of the on-body sensor units themselves. Also, various approaches to connecting electrochemical analyte sensors to and/or within associated on-body analyte sensor units are disclosed. The connector approaches variously involve the use of unique sensor and ancillary element arrangements to facilitate assembly of separate electronics assemblies and sensor elements that are kept apart until the end user brings them together.

A deep intracranial electrode which comprises a conducting wires, an electrode contact, a connector and a nonelastic sleeve is provided, one end of the conducting wires connected to the electrode contact, the other end connected to the connector; the nonelastic sleeve sheathes around the conducting wires, and one end of the nonelastic sleeve is capable of being connected to the connector, the other end connected to the fixing nut which is fixed to a skull. When the deep intracranial electrode is under a pulling force, the fixing nut may avoid the nonelastic sleeve from moving, thereby avoiding the deep intracranial electrode from being pulled out.

Implementations described and claimed herein provide systems and methods for managing animal patient during a veterinary procedure. In one implementation, a base has an interior surface, an exterior surface, and an opening. An electrode is disposed in the opening. The electrode is configured to communicate with medical device(s) for monitoring vital(s) of the patient during the procedure. A thermal insulator extends from the base. The thermal insulator forms a housing. An internal cavity is defined within the housing. The foot of the patient is receivable into the internal cavity. The thermal insulator regulates the body temperature of the animal patient during the veterinary procedure by retaining heat within the internal cavity.