Provided is a connector including a connector terminal to which a mating terminal pin is connected and a connector housing configured to house the connector terminal therein. The connector housing has a tubular inner surface surrounding the connector terminal. The connector terminal includes elastic contact pieces arranged at intervals around a central axis of the tubular inner surface. Each elastic contact piece includes a contact portion extending along the central axis and being curved and a distal end portion located outward in a direction orthogonal to the central axis of the contact portion. The contact portion, when subjected to a pressing force from the mating terminal pin toward the tubular inner surface, is shaped into a flat form as a result of the distal end portion moving along the tubular inner surface. Also provided are an electric wire with the connector and a medical device sensor.

An electrode padset and a method of using the electrode padset are disclosed herein. The electrode padset is a single unit, consisting of multiple patient-contacting conductive pads arranged on a single piece of material. The padset is comprised of a plurality of conductive pads, at least one conductive pad adapted to emit an electrical signal and at least one other conductive pad adapted to receive an electrical signal, and an electrically conductive material coupling the conductive pads.

The disclosed invention relates generally to various embodiments of garments for use with electrocardiographs. In particular, the invention relates to a garment with a lead placement layer or precordial patch with incorporated ECG leads and a support layer configured to support the breasts of a user while a patient undergoes an exercise stress electrocardiograph. Various portions of the garment are easily and quickly removable.

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.

A wearable device configured to measure physiological parameters of a subject is described. The wearable device can include a dock having a plurality of prongs, a dock circuit layer having a plurality of conductive strips positioned along the plurality of prongs, and a plurality of electrodes in electrical communication with the dock circuit layer. The wearable device can also include a hub configured to be removably secured to the dock, the hub having a housing with a plurality of openings, and a hub circuit layer arranged within the interior of the housing. When the hub and dock are secured to one another, the plurality of prongs of the frame extend towards the plurality of openings of the housing of the hub and cause the plurality of conductive strips to contact portions of the hub circuit layer to facilitate electrical communication between the plurality of electrodes and the hub circuit layer.

A wearable device configured to measure physiological parameters of a subject is described. The wearable device can include a dock having a plurality of prongs, a dock circuit layer having a plurality of conductive strips positioned along the plurality of prongs, and a plurality of electrodes in electrical communication with the dock circuit layer. The wearable device can also include a hub configured to be removably secured to the dock, the hub having a housing with a plurality of openings, and a hub circuit layer arranged within the interior of the housing. When the hub and dock are secured to one another, the plurality of prongs of the frame extend towards the plurality of openings of the housing of the hub and cause the plurality of conductive strips to contact portions of the hub circuit layer to facilitate electrical communication between the plurality of electrodes and the hub circuit layer.

Systems, devices and methods for advanced electrode management in neurological monitoring applications include receiving sockets configured to receive connectors having groups of electrodes. The physician is not required to manually map each electrode with its corresponding input channel. Electrodes are coupled to the corresponding input channels in groups through connectors having a unique identification (ID). The system is configured to read the unique ID of each connector and establish its identity. Based on the ID, the system configures itself to automatically correlate or associate each electrode with its corresponding input channel when the connectors are first inserted into the receiving sockets, and again if the connectors are removed and re-inserted into different positions in the receiving sockets, to insure the electrodes are always mapped to the same input channels.

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 apparatus comprising a plurality of electrically conductive elements for transmitting an electrical signal from a sensor to a medical device is described, wherein the electrically conductive elements are moveable between a first stored position and a second in use position. In this manner the apparatus provides an interface between the sensor and the medical device such that the length of each of the electrically conductive elements can be varied and adjusted such that the excess amount of the elements is minimized and the functionality of the sensors and/or medical device maximized.

Devices and methods for remote monitoring of heart activity are disclosed. In some embodiments, a wearable heart monitoring devices for monitoring heart activity comprises one or more acoustic sensors, including at least one microphone configured to operate in a frequency range related to human hearing, and at least one accelerometer configured to operate in the range of low or sub-audible frequencies.