An electrical connector having a main support with a front and back, top and bottom, and left and right opposite the left. Fingers extend forwardly from the front of the main support to a tip. The fingers each have a top and bottom and are arranged from left to right of the main support with gaps defined between them. A flexible circuit board has inner and outer surfaces with electrical leads on the outer surface. Openings are defined through the flexible circuit board between the electrical leads. The flexible circuit board is wrapped around the fingers such that the outer surface of the flexible circuit board is supported on both the top and the bottom of the fingers and the openings in the flexible circuit board are aligned with the gaps between the fingers.

A fiberoptic waveguide connectable to an optical receiver, and a plurality of electro-optical elements optically coupled to the waveguide. The electro-optical elements each have a first electrode with a first polarity, and a second electrode with a second polarity. A light-emitting diode is linked to the first electrode and configured for illuminating the waveguide responsively to an electrical potential between the first electrode and the second electrode at a respective wavelength. The waveguide may be incorporated into a catheter for insertion into a subject, such as a cardiac catheter.

A system includes a conformable biopotential sensor that withstands a defibrillation pulse. The conformable biopotential sensor includes a polymer substrate, a plurality of electrodes printed on the polymer substrate, a signal trace printed on the polymer substrate, and one or more resistors printed on the polymer substrate and in electrical communication with an electrode of the plurality of electrodes via the signal trace. One or both of the one or more resistors and the polymer substrate withstand a defibrillation pulse. The conformable biopotential sensor further includes a coating layer applied to the one of both of the one or more resistors, wherein the coating is more thermally conductive than the polymer substrate.

Circuits are provided for detecting an electrosurgical unit signal. An example circuit includes: a filter configured to process a floating ground signal associated with measuring a bio potential signal of a patient, and a detector configured to output a sensing signal based at least in part on the floating grounding and the Earth ground for detecting an electrosurgical unit signal.

In the present invention, a configuration system for an electrophysiology (EP) study system provides the physician with the ability to input or select the particular procedure to be performed utilizing the EP system, such as performing an ablation procedure, a pacing procedure, or a diagnostic procedure, among others based on the clinical objective of the procedure. Based on the selection of the procedure to be performed, the EP system can handle the selection and switching of different filter selections for a physiological signal to achieve an optimal signal profile having a clinically acceptable display regardless of acquisition conditions with the minimum of user intervention, or knowledge. These selections may be automatically derived, or manually selected, or over-ridden by the user as needed within any typically, or atypical procedural workflow.

Provided is a physiological information detection sensor capable of implementing miniaturization by substantially securing a creepage distance and an air distance (e.g., implementing defibrillation protection).

The physiological information detection sensor includes: a plurality of first substrates arranged in multiple tiers; a second substrate; a first connecting portion that electrically connects adjacent first substrates to each other among the plurality of first substrates; and an insulating member. Each of the plurality of first substrates has a defibrillation protection resistor mounted thereon and electrically connected to a physiological information detection unit. The second substrate has a circuit mounted thereon to process physiological information input from the physiological information detection unit via the defibrillation protection resistor. The insulating member is disposed between adjacent first substrates among the plurality of first substrates.

The present disclosure facilitates capture (e.g., bipolar capture) of differentially-acquired wide-band phase gradient signals (e.g., wide-band cardiac phase gradient signals, wide-band cerebral phase gradient signals) that are simultaneously sampled. Notably, the exemplified system minimizes non-linear distortions (e.g., those that can be introduced via certain filters such as phase distortions) in the acquired wide-band phase gradient signals so as to not affect the information therein that can non-deterministically affect analysis of the wide-band phase gradient signal in the phase space domain. Further, a shield drive circuit and shield-drive voltage plane may be used to facilitate low noise and low interference operation of the acquisition system.

An overvoltage protection device protects an electronic medical device in the event of a transient overvoltage on one or more patient lines of the device. A current limiting device is placed in series in a patient line between electronic components of the medical device and a patient interface. A biasing voltage generating device has at least one biasing element located in a line extending off the patient line and at least one additional circuit element connected in series with the biasing element. The biasing voltage generating device is configured to apply a predetermined biasing voltage to the current limiting device via the biasing element in response to a transient overvoltage on the patient line, whereby the current limiting device is switched off and limits current flow through the patient line.

A low input current amplifier has a voltage spectral density curve to operate at 50 Hz or less and is connected to dielectric materials to receive a signal irrespective of ground reference. The amplifier outputs a first output. A multi-stage amplifier includes a stage connected in series with the low input current amplifier to amplify the first signal to distinguish the incidence, traverse and physiological condition of a living human. The resulting signal is then processed by an algorithm and displayed as human specific motion, heart rate and respiratory rate.

A basket-type EP catheter is described. The EP catheter comprises a catheter proximal end that is electrically connected to a controller by an electrical cable having a single voltage-out (Vout) conductor and a catheter distal end supporting a distal connector that is detachably connectable to a basket-shaped configuration of a plurality of splines. Each spline supports an array of electrodes. By sampling the voltage signal on each of the plurality of electrodes sequentially or consecutively, only one Vout conductor is needed to transmit the voltage sample to the controller. In comparison to conventional EP catheters, this greatly reduces the number of conductors extending along the catheter shaft. The use of a Vout conductor is implemented by connecting a polling circuit or a one-shot circuit and a signal pass-transistor or transmission gate to each electrode.