In various examples, a component for a medical device is described. The component includes a conductor wire including a connection portion. An electrode is formed from a conductive tube. The conductive tube is compressed at least partially around the connection portion of the conductor wire to at least partially surround and couple to the connection portion.

A real-time applicator position monitoring system (RAPS) measures brachytherapy applicator displacement in real-time by computing the relative displacement between two infrared reflective targets, one attached to the applicator and the other to the patient's skin. In an aspect, RAPS can be used with any brachytherapy application. RAPS measures the applicator motion during HDR brachytherapy treatment, as well as during the transfer of the patient from the imaging room (e.g., where the CT and MR scanners are located) to the HDR BT operating/treatment room.

A medical device system for concurrent power and data transfer comprises an elongated conductive member. At least a portion of the elongated conductive member is configured for insertion within an intraluminal space. One or more sensors that are in electrical connection with the elongated conductive member. The medical device system uniquely allocates each of the plurality of unique contiguous segments within a signal space to one of (i) one or more power channels or (ii) one or more signal channels. The medical device system then sends the electrical signals, via the elongated conductive member, to one or more sensors that are in electrical connection with the elongated conductive member. The medical device harvests energy from the electrical signals. The medical device system isolates transmitted data signals within at least one of the one or more signal channels the data signals generated by the one or more sensors.

In an example, this document discloses an apparatus for insertion into a body lumen, the apparatus comprising an optical fiber pressure sensor. The optical fiber pressure sensor comprises an optical fiber configured to transmit an optical sensing signal, a temperature compensated Fiber Bragg Grating (FBG) interferometer in optical communication with the optical fiber, the FBG interferometer configured to receive a pressure and modulate, in response to the received pressure, the optical sensing signal, and a sensor membrane in physical communication with the FBG interferometer, the membrane configured to transmit the received pressure to the FBG interferometer.

An intravascular sensor delivery device for measuring a physiological parameter of a patient, such as blood pressure, within a vascular structure or passage. In some embodiments, the device can be used to measure the pressure gradient across a stenotic lesion or heart valve. For example, such a device may be used to measure fractional flow reserve (FFR) across a stenotic lesion in order to assess the severity of the lesion. The sensor delivery device has a distal sleeve configured to pass or slide over a standard medical guidewire. Some distance back from the sensor and distal sleeve, the device separates from the guidewire to permit independent control of the sensor delivery device and the guidewire. The sensor delivery device can be sized to pass over different sizes of guidewires to enable usage in coronary and peripheral arteries, for example.

Devices and systems for obtaining conductance data and methods of manufacturing and using the same. In at least one embodiment of a device of the present disclosure, the device is an elongated body with at least one groove defined therein, the at least one groove configured to receive one or more conductor wires therein. In another embodiment, the device is an elongated core body having a plurality of conductive elements positioned thereon and a coating to result in a device having an overall round-cross section.

The present invention relates to a minimally invasive medical instrument (100) having a proximal end (100b) and a distal end (100a) and comprising a sensor arrangement (10) arranged at the distal end (100b) of the medical instrument (100). The sensor arrangement (10) comprises a sensor (20) configured to generate sensor data in the form of an electrical sensor signal, and a data conversion device (40) configured to convert the electrical sensor signal into an optical signal and comprising an electrical input (41) for receiving the electrical sensor signal and an optical output (42) for transmitting the optical signal. The sensor arrangement (10) further comprises an optical fiber (50) configured to transmit the optical signal from the distal end (100a) to the proximal end (100b), the optical fiber (50) coupled to the output of the data conversion device (40) for receiving the optical signal, the optical fiber (50) extending from the distal end (100a) to the proximal end (100b) of the instrument (100). The present invention further relates to a method of manufacturing such a minimally invasive medical instrument (100).

A system includes: an aortic pressure sensor configured to measure aortic blood pressure of an individual; a distal sensor configured to measure a parameter in a blood vessel; a receiver configured to receive both (i) a signal representing the measured aortic blood pressure value, and (ii) a signal representing the parameter, the receiver comprising a display configured to display data that is based on at least the measured aortic blood pressure value and the measured parameter; and a communication interface configured to (i) receive a signal representing the measured aortic blood pressure value from the aortic pressure sensor via a wired connection, (ii) provide a signal representing the measured aortic blood pressure value to a monitoring device via a wired connection, and (iii) send a signal representing the measured aortic blood pressure value to the receiver via a wireless connection.

A position sensor includes a flexible substrate formed into a three-dimensional (3D) shape. At least first and second field-sensing coils are formed in first and second respective layers of the flexible substrate, such that in the 3D shape the first and second field-sensing coils have first and second respective axes that are not parallel to one another.

An eavesdropping arrangement for acquiring a measured physiological variable of an individual includes a receiver and a communication interface in a housing separate from the receiver. The communication interface is positioned along a communication link between a first sensor, which is configured to measure aortic blood pressure and to provide a signal representing measured aortic blood pressure, and a central monitoring device configured to monitor the measured aortic blood pressure. The communication interface includes a connection to the communication link that permits the communication interface to eavesdrop on the signal representing measured aortic blood pressure such that information representing measured aortic blood pressure is sent to the receiver while allowing the central monitoring device to receive and use the signal representing measured aortic blood pressure.