An electrocardiographic system, the electrocardiographic system includes a first part that includes: a first housing that comprises of a first bottom layer that is elastic and has an underside provided with an adhesive material; a first set of electrodes that is located within the first housing; wherein the first set of electrodes comprises at least one first electrode; a second part that comprises: a second housing that comprises a second bottom layer that has an underside provided with an adhesive material; a second set of electrodes that are located within the second housing; wherein the second set of electrodes comprises at least one second electrode; a mechanical adaptor that is arranged to be detachably connected to a electrocardiographic device that comprises a processor and a wireless transmitter; and an electrical connector that is detachably is arranged to be detachably connected to the electrocardiographic device and to electrically couple the electrocardiographic device to conductors that convey signals from the first and second sets of electrodes.

A connector is provided that has multiple electrode rings which are arranged in a row and capable of allowing multiple wires to pass therein The connector also has a relay ring capable of allowing the multiple wires to pass therein. The relay ring has a first mating part fitted to one electrode ring of two adjacent electrode rings and a second mating part fitted to the other electrode ring.

Methods and systems of evaluating cardiac pacing in candidate patients for cardiac resynchronization therapy and cardiac resynchronization therapy patients are disclosed. The methods and systems disclosed allow treatments to be personalized to patients by measuring the extent of tissue capture from cardiac pacing under various therapy parameter conditions. Systems and methods of optimizing right ventricle only cardiac pacing are also disclosed.

The present invention provides a medical electrode comprising a conductive metal base comprising a plate element and a boss formed on the plate element and a conductive support cylinder separate from the conductive metal base. The conductive support cylinder is rotatably mounted to the conductive metal base while remaining in electrical communication with said conductive metal base. The present invention also provides a limb clamp for an ECG device. According to the present invention, it is possible to prevent bending of the cable connecting with the medical electrode, thereby avoiding cable failure.

Unique methods and bio-imaging systems are introduced herein for self-automated self-operable biomedical devices and methods for bio-signal monitoring, such as electrocardiograms (ECG), heart rate, and other vital signs, requiring no trained medical assistance or minimal assistance. In particular, methods and devices disclosed herein may require no dedicated medical resources, generate diagnostic quality results, and provide for motion artifact correction without inducing discomfort or irritation. Moreover, long term recording is realizable. Such methods and devices reduce the backlog of patients at out-patient wards as well as emergency response in remote areas.

An electrocardiogram analysis apparatus includes: an electrocardiogram signal inputting section to which electrocardiogram signals of measurement electrodes attached to a subject are input; a mistaken attachment determining section which, by using the input electrocardiogram signals, determines whether the measurement electrodes are mistakenly attached or not; an outputting section which, if it is determined that the measurement electrodes are mistakenly attached, notifies of mistaken attachment of the measurement electrodes; and an electrocardiogram data storing section which, in a case where there is an input indicative of confirmation of the notification, stores information indicating that the measurement electrodes have been checked, together with the input electrocardiogram signals, and, in a case where there is not an input indicative of confirmation of the notification, stores information indicating that the measurement electrodes have not been checked, together with the input electrocardiogram signals.

Long-term electrocardiographic and physiological monitoring over a period lasting up to several years in duration can be provided through a continuously-recording subcutaneous insertable cardiac monitor (ICM). The sensing circuitry and the physical layout of the electrodes are specifically optimized to capture electrical signals from the propagation of low amplitude, relatively low frequency content cardiac action potentials, particularly the P-waves that are generated during atrial activation. The ICM is intended to be implanted centrally and positioned axially and slightly to either the left or right of the sternal midline in the parasternal region of the chest, with at least one of the ECG sensing electrodes of the ICM being disposed for being positioned in a region overlying the sternum or adjacent to the sternum and the other of the electrodes also being disposed for being positioned over the sternum or adjacent to the sternum of on the patient's chest.

An electrode padset and a method of using the electrode padset are disclosed herein. The electrode padset is a single unit, consisting of multiple patient-contacting conductive pads arranged on a single piece of material. The padset is comprised of a plurality of conductive pads, at least one conductive pad adapted to emit an electrical signal and at least one other conductive pad adapted to receive an electrical signal, and an electrically conductive material coupling the conductive pads.

A system and method for locating a medical device within a body uses wireless technology to transmit the information obtained from the sensors to a mobile device or other computing system. A software application on the mobile device or computing system can be used to display the information, wherein the user can control the display without needing to contact any items that are not sterile.

An apparatus and method for an electrocardiogram (ECG) cable suitable for use inside a Magnetic Resonance (MR) scanner during a Magnetic Resonance Imaging (MRI) operation. In particular, the present invention relates to a patient safe (MRI-conditional) 12-lead ECG cable capable of use inside an MR scanner during an MRI scan. The ECG cable does not heat up to a degree that would burn a patient undergoing an MRI scan, but also enables the conventional 12-lead ECG electrode placement required for diagnostic monitoring of the patient. Specifically, the ECG cable electrodes can be placed on a patient in the traditional configuration as 12-lead ECG cable designed for use outside of an MR scanner and take diagnostic level readings, during operation of an MR device or system. Additionally, the cable provides a continuous shield which maintains zero emissions while satisfying defibrillation requirements.