The present teachings relate to monitoring the condition of a subject with a contactless system for sensing biopotential signals comprising: a support surface; one or more inner layers; a plurality of contactless electrode units within the one or more inner layers; one or more outer layers; and wherein the plurality of contactless electrode units are arranged in an inner shape within an outer shape such that the contactless electrode units form the vertices of the inner shape and the outer shape. The method includes the steps of: providing a support surface having one or more sensing devices embedded therein; positioning the subject at least partially on the support surface; acquiring data from an electrocardiograph reading on the subject for a predetermined amount of time; outputting the data of the step (c); and analyzing the data of the step (c), by identifying one or more biomarkers consistent with a disease condition.
A61B 5/26 - Bioelectric electrodes therefor maintaining contact between the body and the electrodes by the action of the subjects, e.g. by placing the body on the electrodes or by grasping the electrodes
The present teachings relate to monitoring the condition of a subject with a contactless system for sensing biopotential signals comprising: a support surface; one or more inner layers; a plurality of contactless electrode units within the one or more inner layers; one or more outer layers; and wherein the plurality of contactless electrode units are arranged in an inner shape within an outer shape such that the contactless electrode units form the vertices of the inner shape and the outer shape. The method includes the steps of: providing a support surface having one or more sensing devices embedded therein; positioning the subject at least partially on the support surface; acquiring data from an electrocardiograph reading on the subject for a predetermined amount of time; outputting the data of the step (c); and analyzing the data of the step (c), by identifying one or more biomarkers consistent with a disease condition.
Physiological parameter(s) are determined from a biopotential having one or more signal distorting elements. The method may involve suppressing one or more signal distorting elements may be from an acquired biopotential signal by decomposing the acquired biopotential signal, identifying the one or more signal distorting elements present in the acquired biopotential signal and reconstructing the decomposed biopotential signal without the one or more identified signal distorting elements. The method may involve determining a physiological parameter by analyzing decomposed elements of an acquired biopotential signal.
Systems and apparatus for contactless measuring of biological electrical activity corresponding to an individual include an electrode capacitively coupled with a tissue surface of the individual and a high input impedance amplifier circuit for amplifying a sensing signal generated by the electrode. In some embodiments, the electrode comprises a sensing portion comprising a plurality of electrically conductive layers including a sensing layer, a guard layer and a grounding layer layered between electrically non-conductive insulating layers. Optionally, the sensing portion may also include an electrically conductive guard ring. The guard layer, guard ring and/or grounding layer may shield the sensing layer from external electromagnetic interference which may impinge on the sensing layer and/or maintain high input impedance of the high input impedance amplifier circuit. The high input impedance amplifier circuit may comprise an integrator circuit for biasing a high input impedance amplifier minimizing saturation of the high input impedance amplifier.
Systems and apparatus for contactless measuring of biological electrical activity corresponding to an individual include an electrode capacitively coupled with a tissue surface of the individual and a high input impedance amplifier circuit for amplifying a sensing signal generated by the electrode. In some embodiments, the electrode comprises a sensing portion comprising a plurality of electrically conductive layers including a sensing layer, a guard layer and a grounding layer layered between electrically non-conductive insulating layers. Optionally, the sensing portion may also include an electrically conductive guard ring. The guard layer, guard ring and/or grounding layer may shield the sensing layer from external electromagnetic interference which may impinge on the sensing layer and/or maintain high input impedance of the high input impedance amplifier circuit. The high input impedance amplifier circuit may comprise an integrator circuit for biasing a high input impedance amplifier minimizing saturation of the high input impedance amplifier.
Systems and apparatus for contactless measuring of biological electrical activity corresponding to an individual include an electrode capacitively coupled with a tissue surface of the individual and a high input impedance amplifier circuit for amplifying a sensing signal generated by the electrode. In some embodiments, the electrode comprises a sensing portion comprising a plurality of electrically conductive layers including a sensing layer, a guard layer and a grounding layer layered between electrically non-conductive insulating layers. Optionally, the sensing portion may also include an electrically conductive guard ring. The guard layer, guard ring and/or grounding layer may shield the sensing layer from external electromagnetic interference which may impinge on the sensing layer and/or maintain high input impedance of the high input impedance amplifier circuit. The high input impedance amplifier circuit may comprise an integrator circuit for biasing a high input impedance amplifier minimizing saturation of the high input impedance amplifier.
Physiological parameter(s) are determined from a biopotential having one or more signal distorting elements. The method may involve suppressing one or more signal distorting elements may be from an acquired biopotential signal by decomposing the acquired biopotential signal, identifying the one or more signal distorting elements present in the acquired biopotential signal and reconstructing the decomposed biopotential signal without the one or more identified signal distorting elements. The method may involve determining a physiological parameter by analyzing decomposed elements of an acquired biopotential signal.
Physiological parameter(s) are determined from a biopotential having one or more signal distorting elements. The method may involve suppressing one or more signal distorting elements may be from an acquired biopotential signal by decomposing the acquired biopotential signal, identifying the one or more signal distorting elements present in the acquired biopotential signal and reconstructing the decomposed biopotential signal without the one or more identified signal distorting elements. The method may involve determining a physiological parameter by analyzing decomposed elements of an acquired biopotential signal.
Systems and apparatus for monitoring heart muscle activity of an individual include a first electrode unit, for receiving a first signal indicative of electrical, activity at a first location on a body of the individual and a second electrode unit for receiving a second, signal indicative of electrical activity at a second location on the body of the individual. Each of the first and second electrode units is configurable to operate in a field-sensing mode wherein the electrode unit is placed on or it! proximity to the individual's skin, and a current-sensing mode wherein the electrode unit is coupled to a resistive sensor sensing element placed directly on the individual's skin. The field-sensing mode can be either non-contact field-sensing mode.
Systems and apparatus for monitoring physiological electrical activity of an individual include a first electrode unit for receiving a first signal indicative of electrical activity at a first location on a body of the individual and a second electrode unit for receiving a second signal indicative of electrical activity at a second location on the body of the individual. Each of the first and second electrode units may be operated in a field-sensing mode wherein the electrode unit is placed on or in proximity to the individual's skin. The first and second electrode units comprise a capacitive sensor element, and the capacitive sensor element of each of the electrode units comprising an electrodynamic sensor which is sensitive to electromagnetic waves; and an antenna comprising an electrically conductive radiating element for receiving electromagnetic waves. The field-sensing mode can be either non-contact field-sensing mode wherein the electrode unit is placed on the individual's clothing or a contact field-sensing mode wherein the electrode unit is placed directly on the individual's skin.
Systems and apparatus for monitoring heart muscle activity of an individual include a first electrode unit, for receiving a first signal indicative of electrical, activity at a first location on a body of the individual and a second electrode unit for receiving a second, signal indicative of electrical activity at a second location on the body of the individual. Each of the first and second electrode units is configurable to operate in a field-sensing mode wherein the electrode unit is placed on or it! proximity to the individual's skin, and a current-sensing mode wherein the electrode unit is coupled to a resistive sensor sensing element placed directly on the individual's skin. The field-sensing mode can be either non-contact field-sensing mode.
Systems and apparatus for monitoring heart muscle activity of an individual include a first electrode unit, for receiving a first signal indicative of electrical, activity at a first location on a body of the individual and a second electrode unit for receiving a second, signal indicative of electrical activity at a second location on the body of the individual. Each of the first and second electrode units is configurable to operate in a field-sensing mode wherein the electrode unit is placed on or it! proximity to the individual's skin, and a current-sensing mode wherein the electrode unit is coupled to a resistive sensor sensing element placed directly on the individual's skin. The field-sensing mode can be either non-contact field-sensing mode.
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