An Electrocardiography (ECG) system configured to produce an ECG output signal of a patient includes a plurality of electrodes, a monitoring circuit, a drive circuit, a lead circuit, and a control module. The electrodes form a plurality of leads. The monitoring circuit is configured to monitor a voltage differential on the leads and produce the ECG output signal. The drive circuit is configured to deliver a current to the electrodes based on a measured voltage at the electrodes. The lead fault detection system comprises one or more current sources configured to produce a current to deliver to the electrodes. The control module is configured to vary the current produced by the current sources based on a measured parameter at one or more of the electrodes.

A body worn patient monitoring device includes a flexible substrate having a plurality of electrical connections adapted to be coupled to a skin surface to measure physiological signals. The flexible substrate is adapted to be directly and non-permanently affixed to a skin surface of a patient and configured for single patient use. A communication-computation module, removably attached to an upper surface of the flexible substrate, is configured to receive physiological signals from the flexible substrate and includes a microprocessor that is configured to process and analyze the physiological signals. A series of resistive traces screened onto the flexible substrate are configured as at least one series current-limiting resistor to protect the communication-computation module.

An ECG controller for an ECG device is connectable to a base ECG lead system (e.g., a 12-lead system) whereby the ECG controller implements an ECG waveform morphology based and ECG lead redundancy based detection and classification of any cable interchange (e.g., a limb cable interchange or a precordial cable interchange) between the ECG controller and the base ECG lead system. Alternatively, the ECG controller is further connectable to a sub-base ECG lead system (e.g., a limb only-lead system or a limited precordial-lead system) whereby the ECG controller implements an ECG waveform morphology based detection and classification of any cable interchange (e.g., a limb cable interchange or a precordial cable interchange) between the electrode interface and the sub-base ECG lead system.

Systems and methods are provided for water resistant connectors. A male connector includes a rib or a draft angle that creates a seal when engaged with a female connector. A male connector includes an overmold that includes or is made of a thermoplastic elastomer. Male or female connectors include molds that include or are made of a thermoplastic polymer, such as polypropylene. A female connector includes spring contacts that fit within individual pockets of the female connector.

An electrocardiogram (ECG) system is provided. The system includes an ECG device capable of receiving ECG signals from a lead system attached to the user. The ECG device then renders the ECG signals into ECG data, and transmits the ECG data to at least one of a user device, such as a smart phone, or a cloud-based storage system. The user device is capable of rendering the ECG data into an ECG graph, and displaying the ECG graph to the user on an application (app). The system also provides for a cloud-based storage system capable storing the ECG data and providing access to the ECG data to the user and to medical personal.

A patient monitoring system includes a patient monitor and an ECG lead set coupled thereto. The patient monitor may be programmed to periodically issue interrogation signals to the ECG lead set to determine the type and connection status of the ECG lead set. The interrogation signals may be issued via a communication bus. The patient monitor may time the issuance of interrogation signals to the ECG lead set to correspond to non-critical ECG intervals, such that interference with the ECG signals by the communication bus is minimized.

Various patient monitoring systems, devices, and methods are disclosed for monitoring physiological parameters of a patient. A noninvasive blood pressure monitor can include an inflatable cuff, a pressure transducer, an air pump, and a plurality of air paths connecting the inflatable cuff, the pressure transducer, and the air pump. The monitor can also include an acoustic filter provided along at least one of the air paths. In some cases, the monitor can include first and second air pumps, as well as a processor to independently control operating characteristics of the air pumps. The processor can also control the air pumps so as to provide a first inflation rate for the inflatable cuff during a non-measurement portion of an inflation phase and a second, higher inflation rate during a measurement portion of the inflation phase.

Provided are controllers, methods and systems for monitoring cardiac data for the presence of arrhythmia. A controller as provided comprises input means arranged to receive first cardiac data corresponding to a time period, processing means and output means. The processing means is arranged to identify, within the first cardiac data, a plurality of events corresponding to ventricular contraction, and a time associated with each event; determine a plurality of intervals between the times associated with chronologically successive events; and produce second cardiac data in dependence on the determined intervals. The output means is arranged to transmit an output signal to a display means based on the second cardiac data, for displaying a beat-to-beat display plot corresponding to at least a part of the time period on the display means. A system as provided may comprise such a controller and a display means for displaying the beat-to-beat display plot corresponding to at least a part of the time period. Also provided are methods of analysing and monitoring cardiac data for the presence of arrhythmia, and non-transitory, computer-readable storage media which store instructions thereon that when executed by one or more processors causes the one or more processors to carry out such a method.

An EKG monitor and cable management system, including a housing, a plurality of retraction reels operably mounted in said housing; and a plurality of EKG leads, each including wires having electrodes disposed at a terminal end, each spooled on one of said reels. The leads deploy and retract in pairs, with the frontal leads retracting as a group of three pairs onto three separate retraction reels.

An emergency cardiac and electrocardiogram (ECG) electrode placement device is disclosed herein. The emergency cardiac and electrocardiogram (ECG) electrode placement device incorporates electrical conducting materials and elastic material into a pad that is applied to a chest wall of a patient, which places multiple electrodes in the appropriate anatomic locations on the patient to quickly obtain an ECG in a pre-hospital setting.