An apparatus for measuring patient data includes a frame having a plurality of electrode hubs. Each hub can include one or more electrode members. The frame can be configured to receive a head of a patient. Each of the electrode hubs can have a single electrode member or a plurality of electrode members that extend from or are connected to an outer member for contacting a scalp of the head of the patient. The outer member can have at least one circuit configured to transmit data received by at least one of the electrode members to a measurement device via a wireless communication connection (e.g. Bluetooth, near field communication, etc.) or a wired communication connection.

The present disclosure discloses a textile-type multi-channel high-sensitivity sensing dry electrode plate including a body, a conductive cloth and at least one electrode connection part. The body is a sheet-shaped body. The conductive cloth is arranged on one side of the body. The conductive cloth includes at least one electrode part. The electrode connection part is arranged on the body, through the body and electrically connected to the electrode part of the conductive cloth. Moreover, the electrode connection part transmits currents onto the conductive cloth, so that the electrode part of the conductive cloth generates an effect of an electrotherapy or a thermotherapy, or both the electrotherapy and the thermotherapy simultaneously. The electrode part receives physiological electric signals transmitted by a human body and transmits the physiological electric signals back to an apparatus through the electrode connection part to perform a physiological measurement.

Diagnostic apparatus includes a plurality of antennas, which are configured to be disposed at different, respective locations on a thorax of a living body so as to direct radio frequency (RF) electromagnetic waves from different, respective directions toward a heart in the body and to output RF signals responsively to the waves that are scattered from the heart. Processing circuitry is configured to process the RF signals over time so as to provide a multi-dimensional measurement of a movement of the heart.

Diagnostic apparatus includes a plurality of antennas, which are configured to be disposed at different, respective locations on a thorax of a living body so as to direct radio frequency (RF) electromagnetic waves from different, respective directions toward a heart in the body and to output RF signals responsively to the waves that are scattered from the heart. Processing circuitry is configured to process the RF signals over time so as to provide a multi-dimensional measurement of a movement of the heart.

An electrode system for neurological monitoring is disclosed, including a housing with a recess dimensioned to hold an electrode. A conductive gel is applied to said electrode to limit direct contact by said electrode to a patient's skin. The recess defines a wall in said housing that engages the patient's skin. A thin bead of adhesive applied to the top surface of the wall secures the housing, and therefore the electrode, to the patient. Finer electrical conductor wires in a more flexible insulator lead from the electrode to a connector that fits into a neurological monitoring amplifier. The electrode system further comprising a template structure for precisely locating and adjusting to a patient's dimensions.

A brush electrode includes an electrode base that is connectable to an external device that is configured to generate an electrical signal or receive an electrical signal. A plurality of strand electrodes extend outward from the electrode base. A distal end of each strand electrode is configured to contact a skin surface. The strand electrodes are configured to hold an electrolyte to facilitate ionic conduction of the electrical signal to or from the skin surface.

An electrode device for aEEG is disclosed. The electrode device includes a housing mounted on an adhesive element to adhere the electrode device to a skin surface of a patient; an electrode plate placed in the housing; and a wire connection for the electrode plate. The housing has a first protruding part that includes a conical-shaped hole for injecting and removing an electroconductive gel and that is disposed in the housing inclined outwardly at an angle between 50 degree and 80 degree with respect to the longitudinal direction of the skin surface. The housing also has a second protruding part that includes a hole for the introduction of the wire connection in order to be attached to the electrode plate. The second protruding part is disposed on the axis of the housing

The present disclosure relates to a wearable device with a bridge portion and systems/methods relating to the device. Preferred embodiments may include two flexible wings and a bridge connecting the two wings. In some embodiments, the upper surface of the bridge can be non-adhesive and uncoupled to the flexible wing such that the flexible wing can be decoupled from the bridge when the adhesive is adhered to the surface of a user. The bridge can be narrower in some portions, and extend around the housing of the monitor. The bridge can extend beneath the housing and bisect the two flexible wings.

A system for providing an electrical interface between a transducer and a transducer support device, the system comprising: a body mounted to the transducer support device, the body comprising an interface-to-transducer coupling region; a interface-to-electronics subsystem coupling region coupled to the body and contiguous with the interface-to-transducer coupling region, the system defining a fluid sealing region surrounding at least one of the interface-to-transducer and the interface-to-electronics subsystem coupling region; the system comprising an operation mode defining a sealed electrical pathway between the transducer and the transducer support device, wherein: the fluid sealing region is coupled to a complementary transducer sealing region, and the elastically deformable coupling region is biased against an electrical contact of the transducer with the fluid sealing region preventing fluid from reaching the electrical contact of the transducer.

Various aspects of the disclosure relate to evaluating the electromagnetic impedance characteristics of a material under test (MUT) over a range of frequencies. In particular aspects, a system includes: an electrically non-conducting container sized to hold the MUT, the electrically non-conducting container having a first opening at a first end thereof and a second opening at a second, opposite end thereof; a transmitting electrode assembly at the first end of the electrically non-conducting container, the transmitting electrode assembly having a transmitting electrode with a transmitting surface; and a receiving electrode assembly at the second end of the electrically non-conducting container, the receiving electrode assembly having a receiving electrode with a receiving surface, wherein the receiving electrode is approximately parallel with the transmitting electrode, and wherein the transmitting surface of the transmitting electrode is larger than the receiving surface of the receiving electrode.