A bio-signal measurement apparatus comprises tool-less connectors, coupling targets, a controllable coupling selection arrangement, and a control arrangement. The tool-less connectors are for an electric contact with a separate docking apparatus or an electrode arrangement. The coupling targets include a battery and a data communication unit that performs electrically a plug-and-play data transfer with the separate docking apparatus. The tool-less connectors, the number of which is three, are electrically coupled with the controllable coupling selection arrangement, which electrically couples all the tool-less connectors with only one of the coupling targets at a time in response to control from the control arrangement. The battery receives electricity from the tool-less connectors for charging the battery through the electric coupling caused by the coupling selection arrangement under control of the control arrangement during a first time window when the bio-signal measurement apparatus is connected with the docking apparatus. The data communication unit sends and/or receives data through the tool-less connectors using the plug-and-play data transfer based on the electric coupling caused by the coupling selection arrangement under control of the control arrangement during a second time window when the bio-signal measurement apparatus is connected with the docking apparatus.

An patch and sensor assembly for use in an EP mapping system has two portions: a reusable portion and a disposable portion. The reusable portion houses the biosensors used in magnetic based location and mapping systems and the electrical lead necessary to communicate between the biosensor and the mapping system. The reusable portion may also contain a portion of the electrode necessary to receive electrical signals from the body of the patient. The disposable portion of the patch and sensor assembly contains an adhesive covered flexible patch having at least a portion of the electrode used to receive electrical signals form the body of the patient and may contain the electrical lead necessary to communicate such an electrical signal to the mapping system. The disposable portion contains a receptacle adapted to receive and mechanically secure the reusable portion to the disposable portion of the assembly. Such a patch and sensor assembly is useful in hybrid magnetic and impedance based location and mapping systems such as those used in electrophysiology.

Disclosed is an ECG electrode lead wire connector which provides improved electrical and mechanical coupling of the ECG electrode press stud to the lead wire and is suitable for use during imaging procedures such as, without limitation, CT scans or MRI. The connector assembly includes a housing having. An engagement member is pivotably disposed within the housing to retain the connector on an ECG electrode fixed to a patient's body, an arcuate stiffener is deposed between the engagement member and a pivot member and a radiolucent resilient member configured to bias the engagement member.

An electric conductive sensing device is provided. A front sheet of a sensing pad has several openings. A sensing electrode is a conductive ink electrode aligned with and exposed through each opening. Several first terminals are formed on an insert portion of the sensing pad and are connected to sensing electrodes. Each opening covered by a conductive gel is electrically connected to the corresponding sensing electrode. The insert portion is integrated in a connector. The present invention can be used as electrode patches of ECG devices or electric stimulators. In use, the connector is plugged into the devices to transmit tiny electrical currents to the ECG device from human skin surface, or to transmit electrical currents generated from the stimulator to human. The sensing electrodes are formed by conductive ink printing thereby simplifying the manufacturing process and lowering the manufacturing cost compared to conventional soldered structures.

An envelope is comprised of two sheets of material that are placed one on top of each other with their interior sides facing each other with their edges sealed to each other with an adhesive to form an airtight enclosure. The envelope has at least one medical patch inside it that is attached to the interior side of at least one of the sheets and a layer of medical grade pressure sensitive adhesive surrounding the at least one medical patch. The pressure sensitive adhesive is applied to a part of the surface of the interior side of the sheet in order to attach the sheet of material and the at least one medical patch to the body of a patient. The medical patch can be an electrode for measuring a patient's vital signs or delivering an electric shock or a transdermal patch for delivering a drug to a patient.

An envelope is comprised of two sheets of material that are placed one on top of each other with their interior sides facing each other with their edges sealed to each other with an adhesive to form an airtight enclosure. The envelope has at least one medical patch inside it that is attached to the interior side of at least one of the sheets and a layer of medical grade pressure sensitive adhesive surrounding the at least one medical patch. The pressure sensitive adhesive is applied to a part of the surface of the interior side of the sheet in order to attach the sheet of material and the at least one medical patch to the body of a patient. The medical patch can be an electrode for measuring a patient's vital signs or delivering an electric shock or a transdermal patch for delivering a drug to a patient.

An electrode includes an electrically non-conductive support. A protruding, electrically conductive attachment element with an attachment site for the releasable attachment of a signal conductor is on an upper face of the support. A conductor is on the underside of the support, and is electrically connected to the attachment element and to a contact medium. The conductor and the contact medium are arranged on the underside of the support. An imaginary normal to the support, running through the attachment element, runs through the conductor or a recess in the conductor and through the contact medium or a recess in the contact medium. The conductor has on its surface a redox pair suitable for the depolarization of the electrode. The attachment element has a projection reaching through the support with a widened region at its end, and the conductor is arranged between the widened region and the support.

A multifunctional electrophysiological monitoring system includes a body-worn tattoo sensor pattern and an electrophysiological monitor connected to sensor contacts of the pattern. A dongle performs a supplemental function, such as acquiring information about a physiological parameter. The dongle interfaces with a port of the monitor. The monitor interfaces wirelessly with a mobile communication device and a monitor network. In an embodiment, the monitor transmits ECG, EMG, or EEG signals. The dongle may provide further monitoring such as body temperature or blood oxygen saturation level. In some embodiments a plurality of dongles may be connected to the monitor.

A multifunctional electrophysiological monitoring system includes a body-worn tattoo sensor pattern and an electrophysiological monitor connected to sensor contacts of the pattern. A dongle performs a supplemental function, such as acquiring information about a physiological parameter. The dongle interfaces with a port of the monitor. The monitor interfaces wirelessly with a mobile communication device and a monitor network. In an embodiment, the monitor transmits ECG, EMG, or EEG signals. The dongle may provide further monitoring such as body temperature or blood oxygen saturation level. In some embodiments a plurality of dongles may be connected to the monitor.

The present invention provides an electroencephalogram measurement structure formed by an ear-hanging structure and a second circuit board. The ear-hanging structure includes a body. An ear-hanging member is disposed at the extension of the body. The body can be worn on the ear via the ear-hanging member. In addition, a first reference electrode and a second reference electrode are disposed on the body and coupled to a first circuit board. The first circuit board is coupled to an electrical jack; the second circuit board is coupled to the electrical jack via an electrical plug. Thereby, the electroencephalogram measurement can be performed simply by wearing the ear-hanging member on the ear of the person under test. Hence, the problems of complicated wiring and inconvenience in wearing can be solved concurrently.