Abstract: Handling or removal of a pair of pre-connected defibrillator electrode pads from their package, or a compartment in the defibrillator, is detected in order to effectively time the issuance of prompts to guide the user. Detection occurs when an impedance level between the electrode pads varies sufficiently over time to indicate occurrence of the handling or removal event. The pads are preferably configured to leverage variability in the impedance that results from bending of pads during handling or removal.

Abstract: A circuit includes a sensor coupled to a processor. The sensor senses an electrical signal that is representative of a patient parameter, and the processor determines a condition of the patient by analyzing first and second overlapping portions of the sensed electrical signal. For example, a portable AED can include such a circuit to sense first and second overlapping sections of an ECG. By utilizing this overlapping-window technique, the AED can obtain and analyze multiple sections of ECG data, and thus can make a shock/no-shock decision, more quickly than an AED using contiguous-window analysis. Thus, the overlapping-window technique allows one to use both longer ECG sections (better accuracy per window) and more of these longer sections (better voting accuracy) over a given analysis time.

Abstract: A device to carry out a bioelectrical interaction with an individual by means of electrodes 29, 29a whereby an on-demand verification of the integrity of the electrical contact of the electrodes is implemented. The device 20 comprises a control unit 22 arranged to determine an occurrence of the predefined event related to a quality of a measured signal. In case the predetermined event is detected, the control unit 22 actuates the testing means 24. The testing means is arranged to generate the test signals, I1, 12 and to apply them via a coupling circuit 23, 23a to the electrodes. In case it is desired that cumulative information about the contact integrity is obtained, is it sufficient to apply a single test signal per electrode. In case it is required to determine which of the electrodes has lost its contact, a sequence of test signals is generated by the sequencer 24b.

Abstract: A quick-connecting dual electrode assembly for use in procedures such as impedance cardiography includes a body having a cable side and a patient side, and three eyelets arranged therein. A distal snap assembly having a distal stud (108) is secured in a first eyelet (101a) of said three eyelets (101a, 102a, 105a) near an end of the body. An additional stud (105) is arranged in a second eyelet (105a) near a center of the body, wherein the distal stud (108) and the additional stud (105) are electrically joined by a jumper assembly. A proximal snap assembly having a proximal stud (106) secured in a third eyelet (102a) at an opposite end from where the distal stud (108) is arranged proximally to the additional stud (105), so that a distance between the proximal stud (106) and the additional stud (105) is substantially less than a distance between the distal stud (180) and the additional stud (105).

Abstract: The invention relates to an ultrasound phased array imaging system comprising: probe (10) with a 2-D array of transducer elements (12) for acquiring 3-D ultrasound data of a volume of a body, including moving tissue and fluid flow; a beamforming system (10, 12, 14, 16) for emitting and receiving in real time ultrasound beams in said volume, which provides, in real time and in 3-D, more than one spatial receive beams signals for each transmission beam within an ensemble length of more than two temporal samples, among which the receive flow beam signals and the receive tissue beam signals are substantially temporally uncorrelated but spatially correlated; separation means (30) for processing in real time the receive beams signals, comprising adaptive spatial tissue filtering means using simultaneously more than one spatial receive beam signals acquired in 3-D within the ensemble length of more than two temporal samples, which separation means analyzes temporal variations of the respective successive receive sig

Abstract: This invention relates to an external defibrillator whose language of operation can be easily changed when the defibrillator is deployed for use. Defibrillators include, manual defibrillators, automatic or semi-automatic external defibrillators (“AEDs”) and defibrillator trainers. In one embodiment, the invention provides a way to change the language in which the defibrillator delivers instructions to a user. Defibrillators of this invention would contain multiple languages in their memory. During the set-up of the defibrillator some or all of the languages could be designated as a language in which a prompt will be offered. Additionally, during set-up, one language will be designated as the default language. Once the defibrillator is deployed for use in an emergency, the operator will indicate a language preference for the defibrillator operating instructions.

Abstract: A defibrillator test device is disclosed that uses a temperature response as an indication of a test result. The defibrillator test device receives electrical energy from a defibrillation pulse and converts the electrical energy into heat in a resistive member. The heat raises the temperature of the resistive member. A visual test result indication is provided in response to a temperature increase of the resistive member.

Abstract: A three dimensional ultrasonic imaging system acquires volume segments of a wide field of view volume image in coincidence with an ECG waveform. The ECG waveforms acquired during acquisition of the volume segments are displayed in a comparative display in which a different ECG waveform can be visually distinguished. A volume segment acquired during an arrhythmic heartbeat can be reacquired or replaced in the wide field of view volume data set. The ECG waveforms can be displayed vertically aligned by their R-waves, in overlapping alignment, or differently shaded or colored. A processor can compare the ECG waveforms automatically and automatically replace the data of a volume segment acquired during an arrhythmic heartbeat.

Abstract: A disposable internal defibrillator paddle providing for a more economical and easier defibrillation procedure than non disposable paddles. The disposable paddle contains: (a) a handle attached to a shaft attached to a spoon, the spoon having a receiving unit, and the handle, the shaft, and the spoon are all made of non conducting material; and (b) an electrode plate attaching onto the receiving unit of the spoon.

Abstract: An atrial defibrillator includes a portable, non-implantable housing, a pair of defibrillator pads, a shock generator, and an analyzer. The pads are applied to the outside of a patient's body, and the shock generator delivers a shock to the patient via the pads. The analyzer receives a cardiac signal from the patient, determines from the signal whether the patient is experiencing atrial fibrillation, and enables the shock generator if the patient is experiencing atrial fibrillation. Unlike conventional external atrial defibrillators, such an atrial defibrillator can be used by a layperson in the comfort of a patient's own home. Furthermore, such a defibrillator does not cause the surgery-related problems associated with implantable atrial defibrillators. Moreover, because the patient can choose when to receive a shock, such a defibrillator is less likely to surprise and embarrass the patient than automatic implantable defibrillators are.

Abstract: A double electrode connector for connecting to medical electrodes preferably in an impedance cardiography system includes a connector housing comprising a base having two holes therein of predetermined diameters arranged at predetermined location in the housing, with a first of the two holes associated with a first connector and a second of the two holes associated with a second connector of the double-electrode connector; a pair of biasing elements arranged along a surface of the housing so that each one of the pair of biasing elements is adapted for biasing against an electrode stud inserted in a respective hole of the two holes in the housing; a cable assembly including a twin wire cable and a bend relief, wherein each one of the pair of metal lugs is connected to one of the first connector and second connector, and the bend relief is arranged in a hole in the base to flexibly connect the twin wire cable to respective metal lugs of the pair of metal lugs.

Abstract: A defibrillator capable of delivering a damped biphasic truncated (DBT) defibrillation pulse is provided. An energy storage circuit is coupled across a high voltage switch such as an H-bridge for delivering a defibrillation pulse to the patient through a pair of electrodes. A controller operates to control the entire defibrillation process and detects shockable rhythms from the patient via an ECG front end. The energy storage circuit consists of an energy storage capacitor, a series inductor, a shunt diode, and optionally a resistor in series with the inductor. The controller measures as the patient dependent parameter the time interval between the initial delivery of the defibrillation pulse and the occurrence of the peak current or voltage to determine the first and second phases of the defibrillation pulse to provide for compensation for patient impedance.

Abstract: A defibrillation system for patients of all ages may include an Automated External Defibrillator (AED) coupled to a set of universal electrodes. Universal electrodes may be reduced-size versions of adult electrodes, and may include an opening to lower effective impedance. The AED may include an adult/pediatric mode control or switch. Based upon the setting of the adult/pediatric switch, the AED may perform an adult defibrillation sequence or a pediatric defibrillation sequence. An adult defibrillation sequence may comprise delivery of one or more waveforms or shocks characterized by energies appropriate for adults, for example, 150 Joule biphasic waveforms. A pediatric defibrillation sequence may comprise delivery of one or more waveforms characterized by energies appropriate for children, for example, 50 Joule biphasic waveforms.

Abstract: An apparatus for using automatically retractable cables with a defibrillator. The Apparatus provides (a) a defibrillator comprising a power source electrically connected between a first wire and a second wire; and (b) an automatic rotatable housing automatically retracting the first wire and the second wire wound around the rotatable housing. A circular spring can also be used to exert rotational force on the rotatable housing and connect the cables to the power source.

Abstract: A defibrillator having a pair of electrodes for delivering an impedance-compensated defibrillation shock and a method thereof is provided. The defibrillator can be deployed rapidly and effectively with no or minimal clothing and hair removal. To achieve this, one electrode is coupled to a neck region of the patient, whereas the other electrode is coupled to the patient's body. Both attachment areas are easily accessible to the rescuer, thus allowing a minimally trained user to easily deploy the defibrillator to treat the patient. A wide range of energy levels that are safe for the patient can be generated selectively based on the patient impedance. The presence of voids in the electrodes decrease the effective shock impedance of the electrodes, thus allowing the defibrillator to operate at a lower level of energy when delivering the electrical pulse to the victim's heart.

Abstract: An automated or semi-automated defibrillator (AED) system includes an AED and a cartridge attachable to the AED. The cartridge includes electrode pads and a power source such as a battery or fuel cell, which may recharge a defibrillator battery, power defibrillator circuitry, or both. Because the cartridge includes both a power source and electrode pads, one can replace the power source and the pads at the same time by replacing a single cartridge. Furthermore, in defibrillator systems where the power source charges the defibrillator battery, the power source can be selected to have the same life as the pads, thus making it practical to replace the power source and pads at the same time. In addition, maintenance for such a charging defibrillator system typically costs less than for a non-charging system because it often costs less to replace the power source than to replace the defibrillator battery.

Abstract: A method and apparatus for identifying electrodes attached to a defibrillator and adjusting patient therapy delivered by a defibrillator in response thereto.

Abstract: A novel apparatus and method for recording and replaying patient treatment and response data that occurs during the course of an emergency response on a defibrillator. The data and events of an emergency response may be recorded automatically by the defibrillator. Incidents may then be randomly accessible (i.e. “scrollable”) by medical personnel on the defibrillator by placing the defibrillator into an incident review mode. The ability to quickly review critical ECG and event data on the scene. This provides medical personnel with a reliable and efficient alternative to paper based recording systems.

Abstract: An automated or semi-automated external defibrillator (AED) is provided with a plurality of power sources. The AED includes a first power source that powers circuitry creating a defibrillation electrical shock, and a second power source for powering other circuitry. By including a separate power source for the low-power needs of the AED, the high-power source will typically last longer than if the low-power source were omitted. This reduces maintenance costs, particularly where the high-power source is more expensive to replace than the low-power source. Furthermore, one may use the high-power source as a backup to the low-power source so the AED can still operate even if the low-power source fails.

Abstract: A package stores at least one electrode pad having a lead. The package includes an interior for storing the pad, and includes a portion that is openable to allow removal of the package from the leads. For example, the openable portion of the package may include a sealed seam through which the lead extends. The operator can peel apart the seam to both open the package and free the package from the lead. Where the pad is a defibrillator electrode pad, the ability to quickly and easily free the package from the lead may save precious seconds during the rescue of a patient in cardiac arrest. For example, freeing the package from the lead typically allows the operator a fuller view of and easier access to the defibrillator and the patient, and eliminates a potential distraction.