The present invention provides a mobile electrocardiograph (ECG) apparatus in which: there is no need to provide a monitor or other display unit to an ECG unit, allowing the apparatus to be commensurately reduced in size and weight; the cost of operation is reduced through the use of a handheld electrode unit; and a body-surface-adhering electrode can be used in only cases when low-noise tests are required, thus promoting ease of handling. Provided is a mobile ECG apparatus for acquiring an electrocardiographic signal upon electrodes being brought into contact with a body surface, wherein the mobile ECG apparatus is characterized by comprising an ECG unit (1) and an electrode unit that includes a plurality of induction electrodes, the ECG unit (1) being configured so as to acquire an electrocardiographic signal from the body surface potential via the electrode unit, and also being configured so as to be capable of wirelessly transmitting the electrocardiographic signal to an analyzer; the ECG unit (1) and the electrode unit furthermore being provided so as to be capable of being attached to and detached from each other by a plurality of connection parts; and the plurality of connection parts being provided with induction-electrode contact points for respectively connecting to the plurality of induction electrodes.

A belt connector is provided. The belt connector is configured to electrically connect a conductor of an electrode belt to a male portion of a snap connector electrode connected to a biometric device. The belt connector includes a frame, a fastener, and an engaging member. The frame includes a receiving hole having radial flexibility. The receiving hole is configured to receive and fasten the frame to a protrusion of the male portion of the snap connector electrode. The fastener is configured to fasten the frame to a first end of the electrode belt. The engaging member is adjacent to the receiving hole and engages the conductor of the electrode belt by the conductor passing through the receiving hole. When the male portion of the snap connector electrode penetrates the receiving hole, the conductor is forced into contact with a lateral surface of the male portion of the snap connector electrode.

An instrument that utilizes body contact electrodes evaluates the quality of the connections made between the electrodes and the body. An electrode contact quality evaluation circuit performs the quality evaluation, such as by determining contact impedances for the electrodes. The corresponding contact quality of each electrode is conveyed to the user.

A method for acquiring electrical signals from a living subject, including injecting, via an injection electrode attached to the subject, a known calibration signal to the subject and measuring respective levels of output signals generated at input electrodes attached to the subject in response to the calibration signal. The method further includes deriving respective weighting factors for the input electrodes in response to the respective levels, and applying the respective weighting factors to physiological signals acquired by the input electrodes, so as to generate respective corrected physiological signals.

An apparatus and method for an electrocardiogram (ECG) cable suitable for use inside a Magnetic Resonance (MR) scanner during a Magnetic Resonance Imaging (MRI) operation. In particular, the present invention relates to a patient safe (MRI-conditional) 12-lead ECG cable capable of use inside an MR scanner during an MRI scan. The ECG cable does not heat up to a degree that would burn a patient undergoing an MRI scan, but also enables the conventional 12-lead ECG electrode placement required for diagnostic monitoring of the patient. Specifically, the ECG cable electrodes can be placed on a patient in the traditional configuration as 12-lead ECG cable designed for use outside of an MR scanner and take diagnostic level readings, during operation of an MR device or system. Additionally, the cable provides a continuous shield which maintains zero emissions while satisfying defibrillation requirements.

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for determining sleep stages and sleep events using sensor data. In some implementations, sensor data is obtained over a time period while a person is sleeping. The time period is divided into a series of intervals. Heart rate and changes in the heart rate are analyzed over the intervals. Based on the analysis of the heart rate changes, sleep stage labels are assigned to different portions of the time period. An indication of the assigned sleep stage labels is provided.

An EKG monitor and cable management system, including a carrying case type 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. Transport and use of the system is in the same upright orientation, and the front side of the housing is configured to accommodate and secure a Bluetooth enabled and network-connectable tablet computer.

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.

A physiological data collection device obtains physiological data from a subject interface on a subject. The physiological data collection device includes a data connector such as a USB connector for connecting directly to a computer. When the physiological data collection device is connected to the computer, the physiological data is uploaded to a remote data processing center for computer-based analysis and review by a medical professional. A report can be provided to the subject based on the analysis and review. When the subject interface is physically connected to the physiological data collection device, the data connector is prevented from being connected to an external device such as the computer.

A physiological data collection device obtains physiological data from a subject interface on a subject. The physiological data collection device includes a data connector such as a USB connector for connecting directly to a computer. When the physiological data collection device is connected to the computer, the physiological data is uploaded to a remote data processing center for computer-based analysis and review by a medical professional. A report can be provided to the subject based on the analysis and review. When the subject interface is physically connected to the physiological data collection device, the data connector is prevented from being connected to an external device such as the computer.