Abstract: A mounter (3) integrally provided with a lancing element (47B) and analyzer includes a lancing member (47) provided with the lancing element (47B), a first member (4) including an accommodation portion (40) for holding the lancing member (47), and a second member (5) formed separately from the first member (4) for holding the analyzer (6). The accommodation portion (40) includes an accommodation space (43) communicable with the outside through a first opening (43a) and a second opening (43b). The lancing member (47) is held and hermetically sealed in the accommodation space (43) by closing the first opening (43a) and the second opening (43b) with a first seal member (44a) and a second seal member (44b).

Abstract: Surfactants useful for enhancing the electrical conduction of electrodes attached to the surface of a patient. The surfactants are also useful in transport of materials in and out of the body of a patient (animal or human) and in the measurement of disease states. Typical surfactants particularly useful in the invention are broadly represented by protein/fatty acid based compounds. The protein/fatty acid compounds may be lipopolypeptides. In some embodiments the lipopolypeptides may be acyl peptides. Typical acyl peptides are Lamepon S™, MayTein C™ and MayTein CT™.

Abstract: Bioadhesive Compositions which comprise a hydrophobic polymer wherein the concentration of the polymer at the surface of the adhesive is greater than its concentration in the bulk of the adhesive are described; and biomedical electrodes, fixation products and wound dressings containing them.

Abstract: An electrode providing electrical contact with a patient's skin includes a conductive member adapted for connection to an external electrical apparatus and a non-liquid water containing film for electrically interfacing to said patient's skin, the non-liquid film being electrically and mechanically connected to said conductive member. The non-liquid water containing film includes an electrically conductive organic polymer plasticized with a polyhydric alcohol with said organic polymer being derived from a monomeric mixture comprising from about 2 to 30 pph acrylic acid, 2 to 30 pph of a glycolvinylether and 0.01 to 1.5 pph of a crosslinking agent. Preferably the polyhydric alcohol is glycerol.

Abstract: Bioadhesive Compositions which comprise a hydrophobic polymer wherein the concentration of the polymer at the surface of the adhesive is greater than its concentration in the bulk of the adhesive are described; and biomedical electrodes, fixation products and wound dressings containing them.

Abstract: The present invention involves an electrode sensor attachable to a substrate for sensing electrical activity of a patient. The electrode sensor comprises an elongated conductive body having first and second ends, wherein the first end is adapted to contact the patient for sensing electrical activity of the patient. The second end is configured to conductively attach to the substrate. The elongated conductive body is greater than about 2 millimeters in length and is configured to extend from the substrate.

Abstract: An ECT, EEG, EMG, ENG or impedance pneumography hospital electrode is designed for use on neonates in high humidity environments, such as in a high humidity incubator. The electrode includes a silver-silver/chloride sensor; a signal transmitting lead connected to the sensor; and an electrically conductive, self-adhesive gel which electrically connects the sensor to the patient's skin. The conductive, self-adhesive gel is formed from a hydrogel which is hydrophilic in nature. In order to stabilize the adhesiveness of the gel in the high humidity environment, the gel is provided with an adjunct non-hydrophilic adhesive member which provides improved adhesion to the skin while maintaining contact between the conductive gel and the patient's skin. The use of the adjunct adhesive member enables the electrode assembly to be used in the high humidity environment for extended periods of time without becoming detached from the patient's skin.

Abstract: An array of electrodes is constructed to allow the user to easily adjust to the correct size of the patient's head. The array is self-adhesive, pre-gelled and disposable. The array fits easily over the temple and forehead areas where EEG signals can be acquired by specially designed monitors for purposes of monitoring a number of bodily phenomena, including but not limited to, depth of anesthesia, and/or ischemia, and burst suppression. The array is connected to the monitor via a tab connector that is integral to the disposable device. The tab connector is insertible into a reusable connector that is part of a monitoring system.

Abstract: A medical electrode includes a first conductive polymerizable gel layer for electrically coupling the electrode to a body and a flexible porous electrical conductor disposed on the first gel layer. A second conductive polymerizable gel layer disposed on the flexible porous electrical conductor and polymerized with the first layer through the porous conductor. An electrical connector disposed in connect with the second gel layer enables the electrical connection to an outside power source, or monitoring device, and an insulative backing is adhered to the second gel layer to prevent inadvertent contact therewith.

Abstract: There is provided a skin engageable, electrode assembly for making selectable contact with the skin. The electrode facilitates the selective collection of electrical data and/or provides selective electrical stimulation. The electrode includes a conductive element, preferably of fabric construction, a semi-fluid conductive layer surrounding the conductive element, a cover preferably made of a perforated fabric or other porous material cell, and one or more temperature sensitive wires embedded in the cover that constrict when heated to cause the semi-liquid conductive layer to permeate the cover via the pores to engage the skin for electrical communication. When the wires cool, they loosen causing the semi-fluid conductive layer to be reabsorbed within the cover to prevent electrical communication with the skin.

Abstract: The EEG electrode and EEG electrode locator assembly may be used in combination with an EEG electrode locator headgear including a plurality of locator straps connectable to one or more of the EEG electrode locators that form an electrode locator assembly with the EEG electrode, for accurately positioning one or more of the EEG electrodes relative to the user's scalp, and for biasing the plurality of electrodes toward the user's scalp. The EEG electrode is adapted to be received in and cooperate with an EEG electrode locator ring, to form the electrode locator assembly. The EEG electrode includes a dispenser assembly adapted to dispense an electrically conductive gel onto the user's scalp to prepare the user's scalp.

Abstract: There is provided a skin engageable, electrode assembly for making selectable contact with the skin. The electrode facilitates the selective collection of electrical data and/or provides selective electrical stimulation. The electrode includes a conductive element, preferably of fabric construction, a semi-fluid conductive layer surrounding the conductive element, a cover preferably made of a perforated fabric or other porous material cell, and one or more temperature sensitive wires embedded in the cover that constrict when heated to cause the semi-liquid conductive layer to permeate the cover via the pores to engage the skin for electrical communication. When the wires cool, they loosen causing the semi-fluid conductive layer to be reabsorbed within the cover to prevent electrical communication with the skin.

Abstract: A method is disclosed which provides for a reduced corrosion of an electrically conductive metallic layer during storage of an electrode comprising said electrically conductive metallic layer in intimate contact with an electrically conductive gel, said electrode being adapted for establishing electrical contact with the skin, wherein the access to oxygen is reduced or eliminated.

Abstract: A system for detecting and marking the positions of peripheral nerves is disclosed. A reusable electrode array comprising a plurality of electrodes is combined with a disposable skin attachment system comprising hydrogel islands. In use, the electrode array is connected to a peripheral nerve detection instrument. The disposable skin attachment system is then attached to an electrode sensor region. The skin attachment system is then adhered to an area of skin, detection is carried out, and then the electrode array is peeled back from the skin, leaving a skin marking guide in place. The skin marking guide is then used to mark areas of interest to a therapist.

Abstract: A sensor for biopotential measurements is designed to detect low voltage electrical signals on a subject's skin surface. A plurality of soft elastomeric bristles are arranged about the surface of the skin. Various bristles contain a wick, made of polyolefin, polyester or nylon, extending along its center axis with one end protruding from the bristle and another end in contact with a fluid reservoir. The wick is saturated with an electrically conductive liquid, such as a salt solution. The solution may contain a surfactant. The rheological properties of the electrically conductive liquid are optimized for predictable flow through the wick onto the skin surface. An electrode is positioned in the vicinity of the wick and the reservoir. Alternatively, a sensor comprises a plurality of hollow, soft elastomeric bristles filled with a hydrogel. An electrically conductive cap provides the electrical contact between the hydrogel and the electrical circuit.

Abstract: A sensor for biopotential measurements is designed to detect low voltage electrical signals on a subject's skin surface. A plurality of soft elastomeric bristles are arranged about the surface of the skin. Various bristles contain a wick, made of polyolefin, polyester or nylon, extending along its center axis with one end protruding from the bristle and another end in contact with a fluid reservoir. The wick is saturated with an electrically conductive liquid, such as a salt solution. The solution may contain a surfactant. The rheological properties of the electrically conductive liquid are optimized for predictable flow through the wick onto the skin surface. An electrode is positioned in the vicinity of the wick and the reservoir. Alternatively, a sensor comprises a plurality of hollow, soft elastomeric bristles filled with a hydrogel. An electrically conductive cap provides the electrical contact between the hydrogel and the electrical circuit.

Abstract: A sensor for biopotential measurements is designed to detect low voltage electrical signals on a subject's skin surface. A plurality of soft elastomeric bristles are arranged about the surface of the skin. Various bristles contain a wick, made of polyolefin, polyester or nylon, extending along its center axis with one end protruding from the bristle and another end in contact with a fluid reservoir. The wick is saturated with an electrically conductive liquid, such as a salt solution. The solution may contain a surfactant. The surface properties of the electrically conductive liquid and wick are optimized for predictable flow through the wick onto the skin surface. An electrode is positioned in the vicinity of the wick and the reservoir.

Abstract: A medical electrode includes a first conductive polymerizable gel layer for electrically coupling the electrode to a body and a flexible porous electrical conductor disposed on the first gel layer. A second conductive polymerizable gel layer disposed on the flexible porous electrical conductor and polymerized with the first layer through the porous conductor. An electrical connector disposed in connect with the second gel layer enables the electrical connection to an outside power source, or monitoring device, and an insulative backing is adhered to the second gel layer to prevent inadvertent contact therewith.

Abstract: A medical electrode assembly includes a conductive electrode, an electrically insulative backing layer on one side of the electrode, an electrically conductive coupling agent in contact with another side of the electrode, an attachment mechanism rigidly connected to a center portion of the electrode, and an electrical conductor connected to the attachment mechanism. The combination of the electrode with the attachment mechanism is constructed with substantial circumferential uniformity such that electrical current provided to the center portion of the electrode through the low-profile attachment mechanism is distributed radially through the electrode in a substantially circumferentially uniform distribution. The electrode is constructed to perform defibrillation or cardioversion. The attachment mechanism is substantially flat and has a low profile. The electrical conductor has a substantially flat, strap-like configuration.

Abstract: A package for increasing shelf life of electrodes packaged therein. A first package within which one or more gel-containing electrode pads are sealed. In addition, at least one moisture source is sealed within the package.

Abstract: A medical electrode includes a first conductive polymerizable gel layer for electrically coupling the electrode to a body and a flexible porous electrical conductor disposed on the first gel layer. A second conductive polymerizable gel layer disposed on the flexible porous electrical conductor and polymerized with the first layer through the porous conductor. An electrical connector disposed in connect with the second gel layer enables the electrical connection to an outside power source, or monitoring device, and an insulative backing is adhered to the second gel layer to prevent inadvertent contact therewith.

Abstract: A biomedical electrode comprises a connector stud (1) anchored in a patch of adhesive-coated backing material (7) which is used to secure the electrode to the skin of a patient. The connector stud (1), which is located in a pierced opening in the backing material (7), has a head portion (2) to which an electrical lead of an electromedical monitoring/diagnostic system can be attached, and an electrode plate (3) which, when the biomedical electrode is in use, is placed in electrical communication with the skin of the patient. A strip of ionically-conductive adhesive (9) extends across the backing material and over the electrode plate (3) and a strip of scrim material (17) is located adjacent the adhesive coating on the backing material, underneath the adhesive strip (9). The two strips (9, 17) are displaced, relative to the electrode plate (3), towards a tab (13) which is used for removing the electrode from the skin of the patient.

Abstract: An electrolyte (70) for use in a single-use biomedical electrode assembly (A, B, C, D) designed for receiving body-generated electrical signals at a patient's skin surface includes: Component Range (%) Skin penetration agent 10-25  Thickener 0-10 Alkali metal or alkaline earth 1-13 metal chloride Alkali metal or alkali earth 1-13 metal nitrate Surfactant 0.001-5    Soluble silver salt, as silver   0-0.01 Buffer 0-10 Water Q.S. The skin penetration agent improves penetration of the outer, dead skin layers by the electrolyte, thereby improving pickup of minute electrical signals generated within the patient's body. A preferred skin penetration agent includes sodium 2-pyrrolidone-5 carboxylate at a concentration of 15-20% by weight of the electrolyte composition.

Abstract: An electrode providing electrical contact with a patient's skin includes a conductive member adapted for connection to an external electrical apparatus, and a multilayer system for providing electrical interface between the patient's skin and the conductive member. The multilayer system includes a first layer of an electrically conductive gel having a relatively low peel strength, for removably contacting the patient's skin, and a second layer of an electrically conductive gel having a relatively high peel strength, for contacting said conductive member. The first and second layers are laminated with a sponge third layer therebetween.

Abstract: An electrode provides electrical contact with a patient's skin with the electrode including a conductive member for connection to an external electrical apparatus and multilayers of gel for providing electrical interface between the patient's skin and the conductive member. A first layer is provided which includes an electrically conductive gel having a relatively low peel strength for removably contacting the patient's skin and a second layer is provided which includes an electrically conductive gel having a relatively high peel strength for contacting the conductive member. The first and second layers are laminated in accordance with the method of the invention. Other layers may be utilized in combination with the first and second layers. Such layers include a scrim layer and a layer including physiologically active ions. Further, the electrode through the use of multilayer gels is suitable for use with garments for the selective positioning of electrodes to a patient's skin.

Abstract: A multi-functional, differing electrochemical potential biomedical electrode is disclosed. Several embodiments are described based on the difference in composition of multiple conductors, the difference in composition of fields of ionically conductive media, or both on a single insulative backing of a tab/pad style electrode. A galvanic circuit can be created from electrodes of the present invention, permitting self-restoration of defibrillation recovery of monitoring electrodes and the powering of iontophoretic delivery of pharmaceuticals, among other uses.

Abstract: A biomedical electrode for an electrocardiograph or similar device is provided. The biomedical electrode includes a disposable electrode having an electrically conductive gel layer and a smooth layer film. The disposable electrode interfaces with a reusable leadwire connector having the relatively expensive metallic conductive material. The reusable leadwire adapter includes a vinyl top layer which attaches to the smooth layer film of the disposable electrode through surface attraction. The reusable leadwire adapter may include a suction cup which attaches to the disposable electrode through a partial vacuum. The reusable leadwire also includes a stud member which snaps into a standard leadwire connector.

Abstract: An electrode and a method for measuring bio-electric waves are provided in which the electrode comprises a support member, a piece of absorbent fiber projecting from the support member and a non-corrosive lead coupled to the piece of absorbent fiber. Improved electrical contact between the electrode and the subject's skin is provided by allowing the piece of absorbent fiber to absorb an electrically conductive fluid.

Abstract: An electrode provides electrical contact with a patient's skin with the electrode including a conductive member for connection to an external electrical apparatus and multilayers of gel for providing electrical interface between the patient's skin and the conductive member. A first layer is provided which includes an electrically conductive gel having a relatively low peel strength for removably contacting the patient's skin and a second layer is provided which includes an electrically conductive gel having a relatively high peel strength for contacting the conductive member. The first and second layers are laminated in accordance with the method of the invention. Other layers may be utilized in combination with the first and second layers. Such layers include a scrim layer and a layer including physiologically active ions. Further, the electrode through the use of multilayer gels is suitable for use with garments for the selective positioning of electrodes to a patient's skin.

Abstract: An array of electrodes is constructed to allow the user to easily adjust to the correct size of the patient's head. The array is self-adhesive, pre-gelled and disposable. The array fits easily over the temple and forehead areas where EEG signals can be acquired by specially designed monitors for purposes of monitoring a number of bodily phenomena, including but not limited to, depth of anesthesia, and/or ischemia, and burst suppression. The array is connected to the monitor via a tab connector that is integral to the disposable device. The tab connector is insertible into a reusable connector that is part of a monitoring system.

Abstract: Disclosed is an electrode array (i.e., "sensor") and a method for separating near and far-field signals. In one embodiment a horizontal array is used, and in an alternate embodiment a vertical array is used. The electrode array consists of two well-separated pairs of closely spaced electrodes (and a separate ground element). In a typical application of collecting a channel of EEG, "sensing" electrodes are placed in standard locations (e.g., R and Ctr) with a ground electrode placed elsewhere on the head. The voltage measured between the well-separated sensing electrodes is the far-field dominant (i.e., EEG-dominant) channel. Additional electrodes are placed near each of the two sensing electrodes. (The additional electrodes are immediately lateral to the existing electrodes in the horizontal array, and are immediately above the existing electrodes in the vertical array.) The voltages measured between the pairs of closely spaced electrodes are near-field dominant (i.e., EMG/EOG-dominant) channels.

Abstract: A medical electrode assembly includes an electrically conductive electrode, an electrically conductive sacrificial element, and a layer of electrically conductive gel. The electrode has an electrical terminal to connect with external electrical circuitry. The sacrificial element is electrically connected with the electrode through an impedance element or a power supply. The layer of electrically conductive gel contacts both the electrode and the sacrificial element so as to form an anode-cathode cell in which the sacrificial element functions as a sacrificial anode that corrodes and the electrode functions as a cathode that is protected from corrosion.

Abstract: An electrical conductor and a biomedical electrode using the electrical conductor are disclosed. The electrical conductor has a flexible, non-conductive film and two different carbon-containing coatings on a major surface of the film. The electrical conductor coatings are a low porous carbon-containing coating and a high porous carbon-containing coating. The low porous carbon-containing coating contacts the film and the high porous carbon-containing coating contacts the low porous carbon-containing coating. A tab/pad style of biomedical electrode using the electrical conductor has a field of ionically conductive media containing electrolyte contacting the high porous carbon-containing coating. The electrolyte diffuses into the high porous carbon-containing coating for electrochemical advantages.

Abstract: A DC biopotential sensing electrode assembly is provided for an apparatus for sensing DC biopotentials present at the skin of a subject. An electroconductive medium for transmitting ions from the skin which has a chloride ion content within a range of from 6-15 grams per hundred grams of such medium is formulated for use with the electrode. To reduce the corrosive effect of this electroconductive medium, each electrode includes only one metallic component, and to provide an electrode with a low AC impedance, this metal is uniformly coated upon nonmetallic sensor and terminal bodies with a coating thickness within a range of from 0.5 to 1.5 mil. To insure a complete electrical path through both the sensor and the terminal bodies, the nonmetallic portions are formed of conductive plastic.