A system and method for performing an electrocardiogram is described herein. The system may include one or more of an electrode strip, a data recorder, a connector, one or more computing platforms, and/or other components. The electrode strip may include multiple electrodes configured to provide signals conveying information associated with electrocardiograms. The multiple electrodes may be integrated into the electrode strip. The data recorder may be configured to receive and record information associated with electrocardiograms. Information associated with electrocardiograms may be communicated from the electrode strip to the data recorder via a connector. The connector may include a cableless connector. In some implementations, the information associated with electrocardiograms may be transmitted to one or more computing platforms.

An example system for monitoring and delivering therapy to a patient includes a monitor module with patient monitoring capability, and a manifold that is operable to provide an electrical connection between the monitor module and cables connecting to sensors for collecting physiologic monitoring data of a patient, and to provide a gas connection between the monitor module and tubing for delivering treatment to or collecting additional physiologic monitoring data from the patient. The manifold includes a connector for mechanically connecting the manifold to the monitor module, and the connector also for mechanically disconnecting the manifold from the monitor module while maintaining the cables and the tubing coupled to the patient. In some examples, the system can also include a cot including a second set of monitoring electronics with patient monitoring capability, the cot including a port for coupling with the connector of the manifold.

A system for electrocardiography includes a handheld device having a device housing, and a patient cable having a proximal end that connects to the device housing. A distal end of the patient cable breaks out into leads for attachment to a patient. The handheld device generates an electrocardiogram based on electrical signals received from the patient cable. The system further includes a docking station having a dock housing to support the device housing and to recharge a battery of the handheld device.

A sensor interface is configured to receive a sensor signal. A transmitter generates a transmit signal. A receiver receives the signal corresponding to the transmit signal. Further, a monitor interface is configured to communicate a waveform to the monitor so that measurements derived by the monitor from the waveform are generally equivalent to measurements derivable from the sensor signal.

A sensor interface is configured to receive a sensor signal. A transmitter generates a transmit signal. A receiver receives the signal corresponding to the transmit signal. Further, a monitor interface is configured to communicate a waveform to the monitor so that measurements derived by the monitor from the waveform are generally equivalent to measurements derivable from the sensor signal.

An example system for monitoring and delivering therapy to a patient includes a monitor module with patient monitoring capability, and a manifold that is operable to provide an electrical connection between the monitor module and cables connecting to sensors for collecting physiologic monitoring data of a patient, and to provide a gas connection between the monitor module and tubing for delivering treatment to or collecting additional physiologic monitoring data from the patient. The manifold includes a connector for mechanically connecting the manifold to the monitor module, and the connector also for mechanically disconnecting the manifold from the monitor module while maintaining the cables and the tubing coupled to the patient. In some examples, the system can also include a cot including a second set of monitoring electronics with patient monitoring capability, the cot including a port for coupling with the connector of the manifold.

Systems, devices, and methods for interfacing with biological tissue are described herein. An example electrode patch as described herein includes a flexible substrate and an electrode array arranged on the flexible substrate. The electrode array includes a plurality of electrodes, where each of the plurality of electrodes is formed of a hydrogel. Additionally, each of the plurality of electrodes defines a raised geometry. Additionally, an example system includes the electrode patch, which is configured to interface with a subject's skin, and an electronics module operably coupled to the electrode array.

An electronic device includes a housing including a first cover member, a second cover member, and a side member enclosing a space between the first cover member and the second cover member; a support member coupled to or formed integrally with the side member; a printed circuit board disposed in the space and including a biometric circuit; a first conductive portion disposed at least partially in the side member; a second conductive portion and third conductive portion disposed at least partially in the second cover member and electrically connected to the printed circuit board; and at least one conductive path disposed in the space, configured to electrically connect the biometric circuit and the first conductive portion, and formed on the support member. The biometric circuit receives a biometric signal based on the first conductive portion, the second conductive portion, the third conductive portion, and the at least one conductive path.

The invention provides systems and methods for monitoring the wellbeing of a fetus by the non-invasive detection and analysis of fetal cardiac electrical activity data.

The invention provides systems and methods for monitoring the wellbeing of a fetus by the non-invasive detection and analysis of fetal cardiac electrical activity data.