Abstract: A conforming patient contact interface and method of using the same are disclosed. The conforming patient contact interface may flex when deployed to better contact a surface of a body of a patient.

Abstract: A multipart, non-uniform patient contact interface and method of use are disclosed.

Abstract: The invention concerns a method for performing an electric inhibition of the facial muscles for purely aesthetic purposes, using a device comprising a support at the head of a user (1), two contact electrodes (2), an electronic circuit (3) for generating low-voltage electric pulses at said electrodes (2), a direct current electric power supply (4) and means for fixing and locking (7) said components on the head. The invention is characterized in that it includes the following steps: placing the electrodes (2) on either side of the upper part of the nose, at the glabella; passing the electric pulses via the electrodes (2) through the pyramidal muscle of the nose so as to cause said pyramidal muscle of the nose to relax and hence its antagonist muscle, the forehead muscle and the double eyebrow muscle.

Abstract: Methods and devices for monitoring and/or treating patients comprise a switch to automatically start-up the device when the device contacts tissue. By automatically starting up the device, the device may be installed without the clinician and/or user turning on the device, such that the device can be easy to use. In many embodiments, the device comprises startup circuitry with very low current and/or power consumption, for example less than 100 pA. The startup circuitry can detect tissue contact and turn on circuitry that is used to monitor or treat the patient.

Abstract: A method for making a medical electrical lead electrode assembly includes the steps of: forming an insulative carrier from an insulative material; coupling at least one conductive component to the carrier by inserting a pre-formed tab of the conductive component through the carrier, from a first side thereof to a second side thereof, so that the conductive component is secured to the carrier with the tab extending along a surface of the second side of the carrier and an inward facing surface of an electrode portion of the conductive component being disposed against a surface of the first side of the carrier; coupling an elongate flexible conductor to the tab of the component; and forming an insulative layer over the second side of the carrier, the tab and the conductor electrically coupled to the tab.

Abstract: A set of electrodes suitable for being attached to the skin of an animal or human being at locations normally used for attaching single-lead electrodes with a single sensor point. The electrodes of the set of electrodes have at least three sensors arranged to define two linearly independent directions, which allows sensing corresponding electrical potential differences in the two directions. Signals representing sensed potential differences can be transmitted wirelessly or via conductors to a processing apparatus for being transformed into electrical potentials that approximate traditional potentials obtained with wired single-sensor electrodes. A method is also presented.

Abstract: A system for monitoring a physiological parameter comprises a substrate, a pair of drive electrodes, a pair of detection electrodes, and an RFID apparatus. The substrate is arranged to be removably securable to a biological organism. At least the pair of drive electrodes or the pair of detection electrodes is secured to the substrate. The RFID apparatus is arranged to be in electrical communication with at least the pair of drive electrodes or the pair of detection electrodes. Methods of using the device are also provided.

Abstract: Devices and methods of treating a targeted body tissue by stimulating the body tissue with an electric current. In one embodiment, an apparatus includes an electrode carrier configured to be removably coupled to an interior surface of an orthosis. The electrode carrier includes a recess configured to matingly receive a portion of an electrode. The electrode carrier is electrically coupled to the electrode when the portion of the electrode is disposed within the recess. A connection member is electrically coupled to the electrode carrier and is configured to be releasably coupled to a surface of the orthosis. The electrode carrier is electrically coupled to the orthosis when the connection member is coupled to the orthosis. In some embodiments, the electrode carrier is configured to be removably coupled to the interior surface of the orthosis. In some embodiments, at least a portion of the electrode is constructed of an absorptive material.

Abstract: There is provided a biological-information acquisition apparatus including a plurality of flexible attachment devices each provided with an electrode that is attached to a body and that is configured to acquire biological information, and a connector configured to connect the plurality of attachment devices.

Abstract: The skin preparation device and sensor of the present invention include an array of rigid tines. The tines serve to “self-prepare” the skin at each electrode site. These tines, when pressed against the skin, penetrate the stratum corneum, thereby reducing skin impedance and improving signal quality. A self-prepping device of the present invention is an optimized array of short non-conductive rigid tines in which the individual tines are created in a geometry that allows for a sharp point at the tip when molding, machining or etching is used as a method of fabrication. This non-conductive array with rigid penetrating structures may, therefore, be used in combination with a conductive medium, preferably an ionic conductive gel. In penetrating the stratum corneum, micro-conduits are created in the layers of the skin enabling the conductive medium to reach the low impedance layers and to transmit bioelectrical signals from the skin to the electrode surface.

Abstract: A device, system, and method for delivering a device such as a sensor or fluid transport structure or a fluid transport structure sensor combination into, for example, mammalian skin and receiving, analyzing, and displaying signals from the device such as a sensor are disclosed. A system in accordance with embodiments of the present invention includes a reusable sensor assembly including a transmitter, microcontroller, and housing plus a disposable sensor assembly including a housing having an opening for receiving both the distal end of a biosensor, a sensor insertion guidance structure, and a transmission apparatus for transmitting signals received from the sensor to a reusable sensor assembly for transmission to an external electronic monitoring unit.

Abstract: A system and method for health monitoring are disclosed. The system includes a patch device and an electronic module coupled to the patch device. The method includes providing a patch device, coupling an electronic module to the patch device to provide a wearable device, and monitoring health of a user using the wearable device.

Abstract: A medical electrode which mechanically isolates a conductive interface between the electrode and a patient's skin from forces applied to the lead wires or a lead wire connector is described.

Abstract: A differential non-contact sensor system for measuring biopotential signals is described. The sensor is a low-noise, non-contact capacitive sensor system to measure electrical voltage signals generated by the body comprising two capacitive electrodes and outputting a differential signal.

Abstract: A process for introducing therapeutic doses of electric antioxidants to the human skin with conductive portions in clothing for electrically contacting the skin, for applying direct current, pulsed direct current, or alternating current electricity of various voltage and current levels, for conductive wiring fiber interwoven in clothing, and for electronically controlling the doses of electric antioxidants in microcurrent doses applied percutaneously or transcutaneously to the human skin. A preferred embodiment includes the process for applying clothing that is skin tight, with or without a control module imbedded in the clothing or optionally, a wireless and remote control module for administering the therapeutic doses of electric antioxidants to the skin of the head, feet, legs, hips, or upper torso.

Abstract: A body fat measurement device includes hand electrodes that contact both hands, back area electrodes that contact the surface of a trunk area of the back, foot electrodes that contact both feet, a trunk area width detection unit for measuring the width and depth of the trunk area, a body impedance measurement unit that measures the body impedance of a body using the multiple electrodes and a body fat mass calculation unit that calculates a body fat mass based on the body impedance and the width and depth of the trunk area. The back area electrodes that make contact with the surface of the back of the trunk area are provided in a fitting unit in an exposed state, as well as the trunk area width detection unit. Accordingly, a body fat measurement device can measure a body fat mass easily and accurately in a household or the like.

Abstract: An electrode assembly includes a first surface to be placed adjacent a person's skin and a second surface including a plurality of reservoirs of conductive gel. The plurality of reservoirs of conductive gel are disposed on sections of the electrode assembly that are at least partially physically separated and may move at least partially independently of one another to conform to contours of a body of a patient. The electrode assembly is configured to dispense an amount of the electrically conductive gel onto the first surface in response to an activation signal and to provide for a defibrillating shock to be applied to the patient through the amount of the to electrically conductive gel.

Abstract: The invention provides an electrode and associated electrode holder that are used for physiological measurements, e.g. measurements of signals that can be processed to generate ECG and TBI waveforms. The electrode and electrode holder connect to each other using a magnetic interface. In embodiments, for example, the magnetic interface includes oppositely polled magnets integrated in both the electrode and electrode holder. The magnets are typically rare earth magnets coated with a thin, electrically conductive metal film. This way, when the magnets come in contact with each other, the metal films touch to form both a mechanical and electrical connection. Thus the magnetic interface can replace conventional mechanisms used to connect rivet-based electrodes to leads, which are typically used to secure electrodes for physiological measurements.

Abstract: The present invention relates to a physiological monitoring device. Some embodiments of the invention allow for long-term monitoring of physiological signals. Further embodiments may also allow for the monitoring of secondary signals such as motion.

Abstract: A biosensor is described which can obtain physiological data from an individual. The biosensor may collect electrodermal activity, skin temperature, and other information. The biosensor may be attached to the body through the use of a garment which may be fastened in multiple locations on the human body. The biosensor has replaceable electrodes which may be interchanged. The electrodes contact the body without having any wires or leads external to the sensor.

Abstract: An EIT system (1) adapted to detect internal bleeding in a body portion, the EIT system (1) comprising a plurality of electrodes (3) adapted in use to extend in a substantially linear orientation across one side only of the body portion and to be applied in electrical contact with the skin of the body portion, a current source adapted to cyclically apply an electric current between one pair of the electrodes (3), a voltage measuring means to measure the voltage across each of the other pairs of the electrodes resulting from the current, a data collection system (2) and a data analysis system (4) to analyze data resulting from the voltages that are measured by the voltage measuring means, wherein the analysis system (4) is configured to obtain quantitative information related to amounts and rates of conductive tissue changes occurring in the body, based on an EIT analysis equivalent to that obtained from data derived from electrodes spaced around the full perimeter of the body portion.

Abstract: An article of wearing apparel provided with a sensor for measuring a physiological signal, and a method for manufacturing the wearing apparel provided with a sensor. The wearing apparel includes a flexible substrate and the sensor includes at least one electrode, which has a signalling surface, and which faces in the same direction as the first surface of the flexible substrate. In addition, the sensor includes a signal transmission conductor, which is connected electrically to the electrode. The signal transmission conductor is attached in a watertight manner to the second surface of the substrate. The wearing apparel is comfortable to the user, and sensor in the wearing apparel is reliable, economical to manufacture, and waterproof.

Abstract: A portable electrocardiography (ECG) device includes a first pair of first type snap-in buttons at a first plane of a case. The first type snap-in buttons are configured for coupling to ECG electrodes having a second type snap-in button. The portable ECG device also includes a processor in electrical connection with the first pair of first type snap-in buttons. The processor is configured for monitoring and processing electrocardiography signals obtained by the ECG electrodes.

Abstract: An electrocardiogram (ECG) sensor system is disclosed that includes one or more interface connectors configured to be coupled to one or more electrodes. The ECG sensor system includes a processor configured to receive an ECG signal via the one or more interface connectors. The processor may be configured to determine one or more noise values associated with the ECG signal. Each of the one or more noise values may be indicative of a measurement of a component of the ECG signal that is potentially related to a non-heart beat source. The processor may be configured to send one or more noise values to an automated troubleshooting system.

Abstract: An applicator for applying an electrode to a patient, and a system for recording of the electroencephalographic potential, the evoked potential, and the ground and reference potentials in electroenceophalographic and evoked potential measurements, is disclosed herein. The applicator includes a main body and a plunger unit.

Abstract: Wearable (ambulatory) monitors of the present invention have a segmented design, with at least two and preferably three (or more) mechanically independent, spaced apart sensors (e.g., electrodes or other types of physiological sensors) located in discrete islands, or housing structures that are flexibly connected to one another. Each of the sensors is in operable communication with one or more electronics module(s), also located in one or more of the islands. In some embodiments, an electronics module may be centrally located with respect to two or more peripherally located sensors.

Abstract: Embodiments relate generally to electrical and electronic hardware, computer software, wired and wireless network communications, and wearable computing devices in capturing and deriving physiological characteristic data. More specifically, an array of electrodes and methods are configured to determine physiological characteristics using a wearable device (or carried device) that may be subject to motion. In one embodiment, an array of electrodes is disposed substantially in a wearable housing. At least a portion of the array including electrodes configured to either drive a first signal to a target location or receive a second signal from the target location. The second signal includes data representing one or more physiological characteristics. A sensor selector is configured to identify a subset of the electrodes adjacent to the target location and to select the subset of the electrodes from which to receive a sensor signal that includes data representing one or more physiological characteristics.

Abstract: The invention provides a disposable programmable ECG sensor patch for the non-invasive detection of risk patterns according to programmed criteria. The patch is programmed by a medical professional to select one or more monitoring parameters for detection and alarm indication. One application is to detect changes in the ECG due to cardioactive drugs. Another application is triggering an alarm for a cardiac patient during a stress condition. The programmable patch operates in conjunction with an external programming unit for selecting the detection monitoring parameters.

Abstract: In one embodiment, a system for wrapping biomedical conductor wires about core material, comprises: a payout assembly and a take-up assembly for controllably paying out the core material and taking up the core material with the wrapped conductor wires; a turntable; a plurality of carriers, disposed on the turntable, for letting out the conductor wires; and a die for applying force to the conductor wires as the wires are wrapped about the core material, the die adapted to rotate according to group rotation of the plurality of carriers by the turntable during operation of the system, wherein the die comprises one or more features asymmetrically arranged about a circumference of the die, the one or more features adapted to direct the conductor wires from the plurality of carriers onto the core material in an axially repeating pattern of groups of closely spaced wires with each group separated by a distance larger than the spacing between adjacent wires within each group.

Abstract: A biosignal measurement electrode includes a liquid retaining member, an electric plate, and a cover member. The liquid retaining member is configured to be elastically deformed and impregnated with conductive liquid, the liquid retaining member including a contact surface configured to be brought into contact with a living body surface. The electric plate is configured to be brought into contact with the conductive liquid. The cover member is configured to be elastically deformed and cover the liquid retaining member except for the contact surface.

Abstract: A medical electrode includes an electrode member having a top face and a bottom face, an electrical conductor having an unfanned, unsheathed end portion for conducting energy between the electrode member and a medical device, and a patient contacting layer secured to at least a portion of the bottom face of the electrode member. An energy blocking layer is disposed between the unfanned conductor end portion and the electrode member to prevent immediate transfer of energy to the electrode member. A current distributing structure is described to conduct and distribute energy to the electrode member.

Abstract: An apparatus including a chest strip comprising a plurality of precordial and limb leads for an electrocardiogram (ECG) and an ECG data recorder coupled to the chest strip, wherein the ECG data recorder configured to receive signals from the leads. An apparatus including a chest strip comprising a plurality of precordial leads positioned to correspond with desired lead placement for an electrocardiogram (ECG) and an ECG data recorder; a plurality of limb leads coupled to the chest strip, wherein the ECG data recorder is coupled to plurality of precordial leads and the plurality of limb leads and configured to receive electrocardiogram data generated by the plurality of precordial leads and the plurality of limb leads. A method including coupling a chest strip including precordial leads and a data recorder to a newborn, the data recorder configured to receive electrocardiogram data from the precordial leads; and transmitting electrocardiogram data from the data recorder.

Abstract: Patient electrodes, patient monitors, defibrillators, wearable defibrillators, software and methods may warn when an electrode stops being fully attached to the patient's skin. A patient electrode includes a pad for attaching to the skin of a patient, a lead coupled to the pad, and a contact detector that can change state, when the pad does not contact fully the skin of the patient. When the detector changes state, an output device may emit an alert, for notifying a rescuer or even the patient.

Abstract: In an exemplary implementation of this invention, a user wears comfortable biosensors. These sensors gather physiological data from the user and transmit this data to another radio-enabled device. This other device may be a mobile phone. The data is further transmitted, via this other radio-enabled device, to one or more networks (such as wireless networks or the Internet). A processor analyzes this transmitted data, in real time, to recognize patterns in the data that indicate the need for therapeutic intervention. Upon recognition of such a pattern, the processor outputs instructions for a transducer to deliver therapeutic stimuli. These instructions are transmitted, over one or more wired or wireless networks, to a transducer which delivers the therapeutic stimuli to the user.

Abstract: A flexible dry electrode and the manufacturing method thereof are provided. The electrode has an electroplated uneven surface and at least one hole and is made of porous material.

Abstract: An electrode assembly for making electrocardiogram measurements includes a substrate and at least two electrodes. The substrate includes at least one electronic item sealed therewithin and is laminated or otherwise constructed so as to facilitate removal of the electronic item from the substrate prior to disposal. The electronic item may therefore be re-used in the manufacture of new electrode assemblies.

Abstract: A pad tray includes a base portion and a recessed region that is formed in the front side of the base portion and is for accommodating an electrode pad, the recessed region having a bottom region and a sidewall region that extends up from the bottom region and is provided so as to surround the electrode pad.

Abstract: A self-adhering sensor for non-invasively attaching to a portion of a skin is provided. The sensor comprises a biocompatible substrate, and an array of solid nanoelectrodes coupled to the biocompatible substrate and configured to self-adhere to the skin. Also provided is a sensor for attaching to a portion of a skin, where the sensor comprises an array of solid electrodes configured to self-adhere to the skin, where each of the solid structures comprises a stem and one or more projections extending out from the stem, where both the stem and the projections are solid. The stem comprises a mechanical stopper to control the extent of penetration of the solid electrodes into the skin. The sensor further comprises an electrolyte coating disposed on one or more of the solid structures.

Abstract: A physiological signal detection device includes at least one electrode pad, a base layer, and at least one water absorption unit. The electrode pad is positioned on a top surface of the base layer. The electrode pad and the base layer form a first receiving compartment therebetween. The water absorption unit is positioned in the first receiving compartment. The water absorption unit has a top engaging the electrode pad, and the water absorption unit has a bottom engaging the base layer.

Abstract: An ambulatory electrocardiographic (ECG) monitor with a jumpered sensing electrode and method of use is provided. Self-powered ECG sensing circuitry is fully enclosed in a housing that provides electrode connection receptacles on a bottom surface of the housing. A flexible and stretchable electrode mounting panel having an elongated shape is provided with a layer of skin adhesive on a skin contacting surface. Sensing electrodes are mounted on opposite ends of the mounting panel. Each sensing electrode includes an electrode pad facing the skin contacting surface and an oppositely-facing electrode connection plug. Each connection plug is removably and pivotably couplable into the connection receptacles. A jumper wire assembly includes a jumper connection plug electrically connected to a jumper connection receptacle.

Abstract: An ambulatory electrocardiographic (ECG) monitor with a jumpered sensing electrode and method of use for female and large-girthed patients is provided. Self-powered ECG sensing circuitry is fully enclosed in a housing with electrode receptacles on a bottom surface. A flexible and stretchable electrode mounting panel is provided with a layer of skin adhesive. A standoff pad is placed between the housing and the electrode mounting panel. Sensing electrodes are mounted on opposite ends of the mounting panel. Each sensing electrode includes an electrode pad facing the skin contacting surface and an oppositely-facing electrode plug. Each plug is removably and pivotably couplable into the receptacles. A jumper wire assembly includes a jumper plug electrically connected to a jumper receptacle. The jumper plug is removably and pivotably couplable into the receptacles and the jumper receptacle is removably and pivotably couplable into the plugs on the mounting panel opposite from the standoff pad.

Abstract: A physiological signal detection device includes a base layer, at least one electrode pad, and at least one projection. The electrode pad is positioned on a top surface of the base layer. The electrode pad and the base layer form a first receiving compartment therebetween. The projection is retained in the first receiving compartment. The projection includes at least one raised surface, and the raised surface of the projection supports and raises the electrode pad.

Abstract: A clamp-type electrode contact for physiological use on animals including a first clamping member, a second clamping member, a connecting lead member, and a spring means. A spring engaging member disposed between first and second clamping members and connecting lead member may be included. Spring means is adapted for being placed in a first position when clamping members are in a closed position, and being placed in a second position when clamping members are in an open position. At least one inner side of clamping members includes engagement grooves formed along the inner side. Engagement grooves preferably form a crosshatch pattern, and each groove preferably has a rounded radius and is sufficiently shallow as not to introduce any epidermal or vascular trauma. First and second clamping members are generally aligned with one another whereby inner side of first clamping member and inner side of second clamping member face one another.

Abstract: A wearable medical device and method of detecting clipping of ECG signals is disclosed. In one embodiment, the wearable medical device comprises a plurality of ECG sensing electrodes configured to sense an ECG of a patient and an ECG acquisition circuit electrically coupled to a pair of the plurality of ECG sensing electrodes and configured to provide an amplified and conditioned analog ECG signal, a programmable attenuation/gain stage electrically coupled between a first gain stage and a second gain stage, an ADC electrically coupled to the ECG acquisition circuit to receive and digitize the amplified and conditioned analog ECG signal and provide a digitized ECG signal, and a signal conditioning and control unit electrically coupled to the ECG acquisition circuit and the ADC to receive and monitor the digitized ECG signal and to detect clipping of the amplified and conditioned analog ECG signal based upon the digitized ECG signal.

Abstract: The invention refers to a sensor arrangement with at least one sensor and a method for monitoring physiological parameters of a person, a textile fabric and a use of a textile fabric. An sensor arrangement is described that is suited to improve signal quality and suppress noise, for instance in remote capacitive sensing of body parameters. To achieve this, certain textile fabrics are used, preferably integrated into textile used in a bed, e.g. the blanket, the bed cover, or the mattress. These textile fabrics allow for a suppression of electromagnetic interference from external sources and can be arranged to avoid charge build-up during measurements, in particular those caused by movements of the person.

Abstract: A system for positioning electrodes on a patient body includes an image capturing system, a memory device, a processing system and an indicator system. The image capturing system generates an actual image of the patient body. The memory device stores a reference image, the reference image including a reference body and a reference position on the reference body. The processing system compares the actual image and the reference image and for determining an electrode position on the patient body by matching the reference position on the reference body. The indicator system indicates the electrode position on the patient body.

Abstract: An ECG lead set assembly including a lead set hub and a retractable reel assembly retained within the lead set hub. The retractable reel assembly includes a reel member adapted for rotation within the lead set hub and an electrode lead wrapped about the reel member and having an electrical conductor for connecting to an electrode for receiving biopotential signals from a patient. The electrode lead is extendable from the reel member upon rotation within the lead set hub.

Abstract: A method and system for detecting and treating abnormal cardiac function. The patient's cardiac activity is substantially continuously monitored via a portable wearable device having electrodes and a microcontroller. Features in the monitored cardiac activity indicative of abnormal cardiac function are automatically detected. In response to the detection of an abnormal detected cardiac function, at least one person is automatically alerted of the detected abnormal cardiac function of the patient, and medication may be automatically caused to be administered to the patient. The portable wearable device preferably includes a plurality of electrodes and a microcontroller in communication with the electrodes, adapted to receive sensed cardiac activity signals and create digital signals enabling identification of at least one cardiac parameter.

Abstract: A garment accessory includes a member having first and second ends, with the length of the member between the first and second ends being less than the circumference of a subject that the member is configured for and a pair of fastener mechanisms disposed in proximity to the first and second ends of the member, the fastener mechanisms configured to attach the member to an article of clothing worn by a subject. The garment accessory also includes at least a pair of sensors supported by the member with the sensors being at least one of ECG sensors, motion sensors, body temperature sensors and impedance plethysmography sensors.

Abstract: Embodiments relate to methods and systems for monitoring bioelectric potentials. In some instances, an electrode is applied to a patient's skin. The electrode may be at least partly inserted into the patient's skin, such as by inserting at least part of one or more teeth underneath the skin.