A pediatric electrocardiogram electrode and cover are provided. The pediatric electrocardiogram electrode and cover includes an electrode. The electrode includes an interface that is designed to connect to an electrocardiogram machine. The electrode also includes a gel surface that conducts electrical currents through the electrode. A cover is sized to cover the electrode. The electrode includes an adhesive surface to secure the cover thereon. The cover includes a pair of arms that can overlap to secure the cover to the electrode.

An electronic device includes a housing forming an enclosed chamber. The housing has a top portion and a bottom portion. One or more sensors is provided within the chamber and configured to interface with a user to generate physiological data associated with the user. A set of electrodes is provided on the bottom portion of the housing. Each electrode in the set of electrodes is a single member having a corresponding inner electrode portion within the chamber and an outer electrode portion outside the housing. A set of magnets is provided on the bottom portion of the housing.

An electronic device includes a housing forming an enclosed chamber. The housing has a top portion and a bottom portion. One or more sensors is provided within the chamber and configured to interface with a user to generate physiological data associated with the user. A set of electrodes is provided on the bottom portion of the housing. Each electrode in the set of electrodes is a single member having a corresponding inner electrode portion within the chamber and an outer electrode portion outside the housing. A set of magnets is provided on the bottom portion of the housing.

An electrode connector adapted for attachment to a biomedical patient electrode by either pinch or snap connection includes a pair of pivotally connected members including a connector body and a jaw pivotally connected to said connector body, with the jaw defining a beveled lower surface that functions to urge the jaw open by engagement of the top surface of an ECG stud thereby allowing the connector to be attached by snap engagement. An electrically conducting plate is disposed at the bottom of the connector to maximize electrical contact with the electrode stud. The jaw member further includes a lip functioning to engage a lower portion of the head of the stud and urge the radially enlarged base of the stud into electrical contact with the bottom surface of said electrically conducting member. An ECG electrode connector in accordance with the present invention may further be fabricated of radiolucent materials.

An electrode connector adapted for attachment to a biomedical patient electrode by either pinch or snap connection includes a pair of pivotally connected members including a connector body and a jaw pivotally connected to said connector body, with the jaw defining a beveled lower surface that functions to urge the jaw open by engagement of the top surface of an ECG stud thereby allowing the connector to be attached by snap engagement. An electrically conducting plate is disposed at the bottom of the connector to maximize electrical contact with the electrode stud. The jaw member further includes a lip functioning to engage a lower portion of the head of the stud and urge the radially enlarged base of the stud into electrical contact with the bottom surface of said electrically conducting member. An ECG electrode connector in accordance with the present invention may further be fabricated of radiolucent materials.

A seal portion 24 is arranged between a first fixing surface 222 and a second fixing surface 311. A biasing member 25 comes into contact with a tapered surface 332 of a male terminal 331 received in a female terminal 231 and applies a force in a direction in which the male terminal 331 and the female terminal 231 are moved closer to each other. In a state where the male terminal 331 is received in the female terminal 231, the seal portion 24 is compressed by being sandwiched between the first fixing surface 222 and the second fixing surface 311, and a periphery of the male terminal 331 and the female terminal 231 becomes in a state of being sealed by the seal portion 24.

A seal portion 24 is arranged between a first fixing surface 222 and a second fixing surface 311. A biasing member 25 comes into contact with a tapered surface 332 of a male terminal 331 received in a female terminal 231 and applies a force in a direction in which the male terminal 331 and the female terminal 231 are moved closer to each other. In a state where the male terminal 331 is received in the female terminal 231, the seal portion 24 is compressed by being sandwiched between the first fixing surface 222 and the second fixing surface 311, and a periphery of the male terminal 331 and the female terminal 231 becomes in a state of being sealed by the seal portion 24.

A patch housing for receiving an electronic device is provided. The patch housing includes a flat substrate having a first surface and a second surface with adhesive on at least one of the first or second surfaces. The substrate further includes an opening. The patch housing further includes a set of electrodes included in the substrate. The patch housing further includes a set of connectors provided on the first surface of the substrate. Each connector in the set of connectors is configured to mechanically couple the electronic device to the substrate.

A patch housing for receiving an electronic device is provided. The patch housing includes a flat substrate having a first surface and a second surface with adhesive on at least one of the first or second surfaces. The substrate further includes an opening. The patch housing further includes a set of electrodes included in the substrate. The patch housing further includes a set of connectors provided on the first surface of the substrate. Each connector in the set of connectors is configured to mechanically couple the electronic device to the substrate.

An electrode includes a backing. The backing includes a first backing side and a second backing side. The backing has a planar surface and a portion of the backing forms a raised section on the first backing side and an indented section on the second backing side opposite the raised section. The indented section forms a cavity therein. Further, the backing is not electrically conductive. The electrode also includes an electrically conductive gel disposed at least partially within the cavity. The electrode further includes an eyelet penetrating the backing and electrically coupled with the electrically conductive gel. The electrode includes a stud adapted to detachably couple the electrode to a lead wire and configured to attach to the eyelet.