Abstract: A sensor device has an insulative non-woven fabric and a conductive fabric forming an electrode. The conductive fabric is joined to one surface of the non-woven fabric by at least one of fusion and seaming.

Abstract: The present invention relates to the identification of biological markers of ovarian cancer. Specifically, cancer-associated autoantibodies to ANXA1, ARP3, SAHH, SERPH, ARAP1, OTUB1, ATP1A1, UBA1, and CFAH have been identified in subjects with early stage ovarian cancer. These autoantibodies can be utilised for a range of purposes including methods for detecting ovarian cancer, methods for screening for early stage ovarian cancer, and methods for assessing treatment response as well as disease progression and recurrence. The autoantibodies also represent prognostic markers of ovarian cancer development.

Abstract: The present invention relates to the identification of biological markers of ovarian cancer. Specifically, cancer-associated autoantibodies to ANXA1, ARP3, SAHH, SERPH, ARAP1, OTUB1, ATP1A1, UBA1, and CFAH have been identified in subjects with early stage ovarian cancer. These autoantibodies can be utilised for a range of purposes including methods for detecting ovarian cancer, methods for screening for early stage ovarian cancer, and methods for assessing treatment response as well as disease progression and recurrence. The autoantibodies also represent prognostic markers of ovarian cancer development.

Abstract: The invention relates to a capacitive textile electrode for capacitively measuring electric signals, in particular biological signals, wherein the electrode has a multilayer structure which has at least two electrically conductive layers which are composed of a textile material and has at least one insulation layer which is arranged between the at least two electrically conductive layers, characterized by one, several or all of the following features: a) the at least two electrically conductive layers are mechanically connected to one another and/or to the insulation layer by adhesive bonding, b) at least one several or all of the electrically conductive layers have a prefabricated electrically conductive textile sheet material and/or a prefabricated textile EMC shielding material or comprise the same, c) at least one, several or all of the electrically conductive layers are in the form of textile pieces which have been cut by laser beam, d) at least one amplifier electronics system for amplifying the electri

Abstract: A sensor device has an insulative non-woven fabric and a conductive fabric forming an electrode. The conductive fabric is joined to one surface of the non-woven fabric by at least one of fusion and seaming.

Abstract: System for capacitively recording electrical bio-signals from a bio-signal source, wherein the system has at least one capacitive measuring electrode and at least one electronic evaluation unit which is coupled to the measuring electrode and is intended to evaluate the electrical signals from the measuring electrode, and wherein the system also has means for monitoring the quality of the capacitive coupling between the measuring electrode and the bio-signal source, characterized in that the means for monitoring the quality of the capacitive coupling have, in addition to the measuring electrode(s), at least two injection electrodes which are electrically separated from one another and are intended to feed injection signals into the at least one measuring electrode via the bio-signal source, wherein the system has signal generators for generating a first injection signal and a second injection signal which differs from the first injection signal, which signals are fed into the measuring electrode by means of th

Abstract: The present invention relates to the identification of biological markers of ovarian cancer. Specifically, cancer-associated autoantibodies to ANXA1, ARP3, SAHH, SERPH, ARAP1, OTUB1, ATP1A1, UBA1, and CFAH have been identified in subjects with early stage ovarian cancer. These autoantibodies can be utilised for a range of purposes including methods for detecting ovarian cancer, methods for screening for early stage ovarian cancer, and methods for assessing treatment response as well as disease progression and recurrence. The autoantibodies also represent prognostic markers of ovarian cancer development.

Abstract: The invention relates to a treatment bed for supporting patients in a sitting and/or lying manner for the duration of a treatment and/or diagnosis. The treatment bed has a support surface which consists of one or more segments and on which the patient is supported during the treatment and/or diagnosis. Multiple capacitive measuring electrodes for the contactless capacitive detection of EKG signals of a patient supported on the support surface are arranged in at least one segment of the support surface on the surface side closer to the patient. The treatment bed further has at least one electronic signal processing system which is connected to the measuring electrodes and is designed to process signals, in particular to amplify signals, of the electric signals of the measuring electrodes.

Abstract: System for capacitively recording electrical bio-signals from a bio-signal source, wherein the system has at least one capacitive measuring electrode and at least one electronic evaluation unit which is coupled to the measuring electrode and is intended to evaluate the electrical signals from the measuring electrode, and wherein the system also has means for monitoring the quality of the capacitive coupling between the measuring electrode and the bio-signal source, characterized in that the means for monitoring the quality of the capacitive coupling have, in addition to the measuring electrode(s), at least two injection electrodes which are electrically separated from one another and are intended to feed injection signals into the at least one measuring electrode via the bio-signal source, wherein the system has signal generators for generating a first injection signal and a second injection signal which differs from the first injection signal, which signals are fed into the measuring electrode by means of th

Abstract: The present invention relates to the identification of biological markers of ovarian cancer. Specifically, cancer-associated autoantibodies to ANXA1, ARP3, SAHH, SERPH, ARAP1, OTUB1, ATP1A1, UBA1, and CFAH have been identified in subjects with early stage ovarian cancer. These autoantibodies can be utilised for a range of purposes including methods for detecting ovarian cancer, methods for screening for early stage ovarian cancer, and methods for assessing treatment response as well as disease progression and recurrence. The autoantibodies also represent prognostic markers of ovarian cancer development.

Abstract: An ECG device designed as a portable hand-held device, comprising a housing, on the outer face of which a plurality of ECG sensors in the form of capacitive electrodes is arranged in a sensor region, characterized by the following features: the EGG device has at least one flexible retaining mat in the sensor region, which retaining mat is designed to retain at least some or all ECG sensors, the retaining mat is made of liquid-tight material, at least some or all ECG sensors are fastened to the outer face of the retaining mat facing away from the housing.

Abstract: The invention relates to a capacitive textile electrode for capacitively measuring electric signals, in particular biological signals, wherein the electrode has a multilayer structure which has at least two electrically conductive layers which are composed of a textile material and has at least one insulation layer which is arranged between the at least two electrically conductive layers, characterized by one, several or all of the following features: a) the at least two electrically conductive layers are mechanically connected to one another and/or to the insulation layer by adhesive bonding, b) at least one several or all of the electrically conductive layers have a prefabricated electrically conductive textile sheet material and/or a prefabricated textile EMC shielding material or comprise the same, c) at least one, several or all of the electrically conductive layers are in the form of textile pieces which have been cut by laser beam, d) at least one amplifier electronics system for amplifying the electri

Abstract: The invention relates to an ECG device (1) designed as a portable hand-held device, comprising a housing (2), on the outer face of which a plurality of ECG sensors in the form of capacitive electrodes is arranged in a sensor region (3), characterized by the following features: a) the ECG device (1) has at least one flexible retaining mat (4) in the sensor region (3), which retaining mat is designed to retain at least some or all ECG sensors (20), b) the retaining mat (4) is made of liquid-tight material, c) at least some or all ECG sensors (20) are fastened to the outer face of the retaining mat (4) facing away from the housing (2).

Abstract: A bio-measurement data recording device has a seat which has a back surface made of a foam material, a seat surface, and a plurality of back surface sensors embedded in the back surface such that a plurality of leads for an electrocardiogram of a the person can be received. At least two seat surface sensors are embedded in the seat surface. A left hand grip is arranged such that it can be gripped by the person with the left hand and which has a left hand grip sensor or conducting a channel for the electrocardiogram, and a right hand grip is arranged such that it can be gripped by said person with the right hand and which has a right hand grip sensor for conducting a channel for the electrocardiogram. An evaluation unit is connected to the sensors and is configured to ascertain the electrocardiogram.

Abstract: The invention relates to a medical diagnostic device (1) having at least one sensor matrix (2) for capturing electrical voltage signals at a plurality of locations on the body surface of a person or animal, wherein the diagnostic device (1) is set up for capturing a signal (12) representing the position of the sensor matrix (2) relative to the body of the person or animal, and for determining position information (14) about the position of the sensor matrix (2) relative to the body, localized image information (13) is determined from the voltage signals, and the localized image information (13) is associated with the position information (14).

Abstract: An ECG device designed as a portable handheld device, with a housing which has a grip area and/or grip elements, wherein the grip area and/or the grip elements are designed to allow the ECG device to be held by an operator, and the ECG device has a sensor area, which is arranged outside the grip area and the grip elements and in which a plurality of ECG sensors in the form of capacitive electrodes is provided. Here, the ECG sensors are at least partially embedded in a foam block secured on the housing, and the ECG sensors are held by the foam block and supported elastically therein.

Abstract: The invention relates to an ECG device (1) designed as a portable handheld device, with a housing (2) which has a grip area (3) and/or grip elements, wherein the grip area (3) and/or the grip elements are designed to allow the ECG device (1) to be held by an operator, and the ECG device (1) has a sensor area (4), which is arranged outside the grip area (3) and the grip elements and in which a plurality of ECG sensors (5) in the form of capacitive electrodes is provided. Here, the ECG sensors (5) are at least partially embedded in a foam block (6) secured on the housing (2), and the ECG sensors (5) are held by the foam block (6) and supported elastically therein.

Abstract: The invention relates to a medical diagnostic device (1) having at least one sensor matrix (2) for capturing electrical voltage signals at a plurality of locations on the body surface of a person or animal, wherein the diagnostic device (1) is set up for capturing a signal (12) representing the position of the sensor matrix (2) relative to the body of the person or animal, and for determining position information (14) about the position of the sensor matrix (2) relative to the body, localized image information (13) is determined from the voltage signals, and the localized image information (13) is associated with the position information (14).

Abstract: A method for determining the position or orientation of a transponder by inductive coupling in a radio system, wherein the radio system includes a transceiver having antenna means, comprising a step of generating a magnetic alternating field by means of the transceiver and the antenna means and a step of determining an association signal representing a measure of inductive coupling between the antenna means of the transceiver and the transponder, wherein a distance or orientation of the transponder to the antenna means may be associated to the inductive coupling.