DE102019207673A1 - Arranging measurement signal cables for low-interference measurement of bioelectrical signals - Google Patents

Abstract

The invention relates to a method for arranging measurement signal cables (32, 33, 34, 35) of a differential voltage measurement system, having a plurality of measurement signal cables (32, 33, 34, 35) of different lengths, in one of a magnetic field (B) of a medical imaging Systems (40) intersected area. The measurement signal cables (32, 33, 34, 35) are arranged in a straight line and parallel to one another on a patient's body (O) and they are arranged in such a way that they span an area (FL) parallel to the magnetic field lines of the magnetic field (B). A measurement signal cable arrangement (30) is also described. A differential voltage measurement system is also described. A medical imaging system (40) is also described.

Description

The invention relates to a method for arranging measurement signal cables of a differential voltage measurement system in an area penetrated by a magnetic field of a medical imaging system. The invention also relates to a measurement signal cable arrangement. The invention also relates to a voltage measurement system with such a measurement signal cable arrangement. The invention also relates to a differential voltage measuring system. The invention also relates to a medical imaging system.

Differential voltage measuring systems for measuring bioelectrical signals are used, for example, in medicine to measure electrocardiograms (EKG), electroencephalograms (EEG) or electromyograms (EMG).

The measurements mentioned can also be used in combination with medical imaging processes such as computed tomography. For example, a heart recording or general imaging in the chest area can be clocked by an EKG in order to be able to take heart movements or chest movements into account in the imaging. With the imaging methods mentioned, the patient is located in a tubular examination unit, also called a gantry. During the imaging process in a CT system, a detector and x-ray source system runs around the patient to capture projection images from all sides. If a larger area of the gantry is magnetized, even at low field strengths of less than 1 mT, due to the size of the gantry, a magnetic field can occur which penetrates the patient almost homogeneously and thus causes disturbances in the ECG signal down to the mV range can. The disturbances mentioned are mainly characterized by the frequency of rotation of the gantry. In modern systems, this rotation frequency assumes values of 0.25 to 0.33 Hz. The interference has the result that certain characteristic features of differential measurements, such as the P wave or the T wave of the electrocardiogram, can no longer be clearly identified.

In 1 an example of an electrocardiogram is shown which shows T-wave-like disturbances that occur during an image acquisition in a CT system. After the patient has been pushed out of the gantry, the interfering signal disappears and an ECG signal with a barely measurable T-wave results.

It is therefore an object of the present invention to reduce or even avoid interference caused by magnetic fields in the measurement of bioelectrical signals.

This object is achieved by a method for arranging measuring signal cables of a differential voltage measuring system in an area penetrated by a magnetic field of a medical imaging system according to claim 1, by a measuring signal cable arrangement according to claim 4, by a differential voltage measuring system according to claim 10 and a medical imaging system according to claim 11 .

In the method according to the invention for arranging measuring signal cables of a differential voltage measuring system, having a plurality of measuring signal cables of different lengths, in an area penetrated by a magnetic field of a medical imaging system, the measuring signal cables are arranged in a straight line and parallel to one another on a patient's body and they are arranged such that they span a surface parallel to the magnetic field lines of the magnetic field.

An interference signal generated by magnetic fields and superimposed on the measurement signal can advantageously be avoided, so that the signal quality of a differential voltage measurement is improved and weaker characteristics of the measurement signal can also be recognized.

The inventive measurement signal cable arrangement of a differential voltage measurement system, which comprises a plurality of measurement signal cables of different lengths in an area penetrated by a magnetic field of a medical imaging system, has a plurality of measurement signal cables of different lengths, which are arranged in a straight line and parallel to one another on a patient's body so that they are arranged such that they span an area parallel to the magnetic field lines of the magnetic field.

For the conception of the measurement signal cable arrangement according to the invention, the knowledge is used that a magnetic field generated in the gantry only induces disturbances on surfaces or coils parallel to the support surface of the patient table, but not on surfaces perpendicular thereto. Therefore, according to the invention, an arrangement of the measurement signal cables is chosen in which they do not span a surface parallel to the patient table or do not form an edge of such an area in the edge of which, according to the induction law, an interference signal can be induced by a magnetic flux density that changes over time.

Due to the advantageous geometric arrangement, an interference signal generated by magnetic fields can be prevented or at least reduced, so that the signal quality is improved and weak characteristics of the measurement signal can also be recognized.

The differential voltage measuring system according to the invention for measuring bioelectric signals has the measuring signal cable arrangement according to the invention. The differential voltage measuring system according to the invention shares the advantages of the measuring signal cable arrangement according to the invention.

Further, particularly advantageous embodiments and developments of the invention emerge from the dependent claims and the following description, whereby the claims of one claim category can also be developed analogously to the claims and parts of the description for another claim category and in particular also add individual features to different exemplary embodiments or variants new embodiments or variants can be combined.

• - ein Magnetresonanzbildgebungssystem,
• - ein Computertomographiesystem.

In one embodiment of the method according to the invention, the medical imaging system comprises one of the following system types:

• - a magnetic resonance imaging system,
• - a computed tomography system.

A magnetic resonance imaging system has time-dependent gradient fields which can induce an interference signal in measuring electrodes. In a computed tomography system, a weak magnetization of parts of the gantry can already lead to a relatively strong interfering magnetic field due to their size.

In a variant of the method according to the invention, the measurement signal cables are arranged in such a way that they span a surface perpendicular to a patient support. The magnetic field lines of an interfering magnetic field usually run perpendicular to the patient bed, particularly in a CT system. A magnetic field aligned in this way does not induce an electrical voltage parallel to the direction of the magnetic field. Thus, by stretching a surface of the measurement signal cables perpendicular to the surface of the patient bed, that is, in a plane parallel to the direction of the magnetic field, an induction of an interference voltage in the measurement signal cables by the interference magnetic field is avoided.

In one embodiment of the measurement signal cable arrangement according to the invention, the measurement signal cables are arranged in such a way that they span a surface perpendicular to a patient support. As already explained above, this arrangement achieves a reduction in interference signals.

In one embodiment of the invention, the measurement signal cable arrangement according to the invention has cable guides which lead electrodes further away from the measuring device via electrodes arranged closer to the measuring device. In other words, the electrodes connected to the measuring device via shorter measuring signal cables gain access to the patient's body in that they are arranged closer to the patient's body in the vertical direction. All measurement signal cables run along the same path, so that the measurement signal cables do not form an edge of a surface parallel to the patient's support surface and thus the induction of an interference signal in the measurement signal cable arrangement is prevented or at least counteracted.

In a variant of the measurement signal cable arrangement according to the invention, it has a device for setting a variable length of the individual measurement signal cables in order to adapt their length to a patient's shape, the device having a minimal area parallel to the patient table. The length of the cables can advantageously be set with the aid of this device in such a way that the measurement signal cables do not form loops and run along a common cable path so that they do not span any surface parallel to the patient's support surface. Because the device for setting a variable length of the individual measurement signal cables is itself optimized with regard to an induction surface, any interference signal that occurs can be further minimized.

The device for setting a variable length of the individual measurement signal cables can have a device for tightly rolling up a spiral cable or a small cable drum which is arranged on a distributor of the measurement signal cables perpendicular to the patient table. That is, the longitudinal axis of the device is oriented perpendicular to the surface of the patient table. The area spanned by the measurement signal cables in the area in which they are rolled up is advantageously kept small and a means for adapting the length of the individual measurement signal cables to an individual body size of a patient is provided.

The distributor can comprise a stand with which it can be positioned next to a patient so that the measurement signal cables are distributed in a plane perpendicular to the patient table. This measure also serves to ensure that the measurement signal cables do not form an attack surface for a magnetic field.

• 1 ein EKG-Schaubild, welches durch Störanteile, die durch Magnetfelder verursacht werden, verzerrt ist,
• 2 ein Flussdiagram, welches ein Verfahren gemäß einem Ausführungsbeispiel der Erfindung veranschaulicht,
• 3 eine Messsignalkabelanordnung gemäß einem Ausführungsbeispiel der Erfindung,
• 4 eine schematische Darstellung eines CT-Systems mit einem EKG-Messsystem mit einer Messsignalkabelanordnung gemäß einem Ausführungsbeispiel der Erfindung.

The invention is illustrated below with reference to the accompanying figures with reference to FIG Embodiments explained again in more detail. The same components are provided with identical reference numbers in the various figures. The figures are usually not to scale. Show it:

• 1 an EKG diagram that is distorted by interference caused by magnetic fields,
• 2 a flow chart illustrating a method according to an embodiment of the invention,
• 3 a measurement signal cable arrangement according to an embodiment of the invention,
• 4th a schematic representation of a CT system with an EKG measuring system with a measuring signal cable arrangement according to an embodiment of the invention.

The figures each show an example of an EKG measuring system 1 as a differential voltage measuring system 1 started out to measure bioelectrical signals, here EKG signals. However, the invention is not restricted to this.

1 shows an example of an EKG diagram which was recorded with disturbances induced by magnetic fields. The disturbances result from the rotational movement of magnetized materials, in particular the gantry of a CT system. In 1 the amplitude A of an EKG measurement signal is plotted over time t. For the first 10 cycles of the EKG measurement signal up to time t _{1 it} looks as if the EKG is a T-wave T would show. However, undulations running between individual R-waves disappear after the end of the imaging, ie after the tenth cycle or the point in time t ₁ . As can be seen from the last three EKG measurement cycles, no T-wave is measured in the undisturbed EKG, but rather a P-wave and an R-wave. The interference field in the in 1 The case shown during the first ten cycles thus leads to a misinterpretation of the measurement signal. It would therefore be desirable to use the in 1 suppress or at least reduce the illustrated interference.

In 2 is a flow chart 200 which illustrates a method for arranging measurement signal cables of a differential voltage measurement system, which has a plurality of measurement signal cables of different lengths, in an area penetrated by a magnetic field of a medical imaging system. At the step 2.1 the measurement signal cables are arranged in a straight line and parallel to one another on a patient's body. At the step 2.II the measurement signal cables are then aligned in such a way that they span an area parallel to the magnetic field lines of the magnetic field. Ie the surface and the magnetic field lines do not intersect. In this way it is achieved that no magnetic flux flows through the area spanned by the measurement signal cables and thus no interference signal can be induced in the measurement signal cables by the magnetic field.

In 3 is a measurement signal cable arrangement 30th illustrated according to an embodiment of the invention. The measurement signal cable arrangement 30th includes a trunk cable 31 , from which a plurality of electrode measuring lines 32 , 33 , 34 , 35 via a distributor 31a go out and to that via a connection 31b an EKG measuring unit (not shown) is also connected. Furthermore, in 3 a patient O is also shown schematically in the axial direction, lying on a patient bed 42 lies. The patient couch 42 is also shown oriented in the direction of its longitudinal axis. The electrode test leads 32 , 33 , 34 , 35 each have a different length because they contact different areas of the human body. The electrode test leads 32 , 33 , 34 , 35 run parallel to one another and form a surface FL which is parallel to the field lines B of an interference field and perpendicular to a support surface of the patient bed 42 runs on which the patient is 0 is located.

In 4th Fig. 3 is an oblique top perspective view of a CT system 40 with a measurement signal cable arrangement 30th shown. The CT system 40 includes a gantry 41 , in a patient couch 42 , on which a patient O is lying, is pushed in. The electrode test leads 32 , 33 , 34 , 35 are arranged one above the other along the dashed line in such a way that together they form a surface parallel to the vertical. Since a magnetic field induced by the gantry is tight against this surface, the electrode measuring lines form 32 , 33 , 34 , 35 therefore no loop into which an interfering signal could be induced. A first electrode test lead 32 is coupled to the patient's foot O and is therefore marked with F. A second electrode test lead 33 is linked to the patient's left arm O and is therefore identified with the letter L. A third electrode test lead 34 is marked with N and forms the neutral electrode. A fourth electrode test lead 35 is linked to patient O's right arm and is identified by the letter R.

Finally, it is pointed out once again that the devices and methods described in detail above are merely exemplary embodiments which can be modified in various ways by the person skilled in the art without departing from the scope of the invention. The differential voltage measurement system can not only be an EKG device, but also other medical devices with which bioelectrical signals are recorded, such as EEGs, EMGs, etc. Furthermore, the use of the indefinite article "includes" or “One” does not exclude the possibility that the characteristics concerned can also be present several times. Likewise, the term “unit” does not exclude that it consists of several components, which may also be spatially distributed.

Claims (11)

Method for arranging measurement signal cables (30) of a differential voltage measurement system in an area penetrated by a magnetic field (B) of a medical imaging system (40), having a plurality of measurement signal cables (32, 33, 34, 35) of different lengths, the measurement signal cables ( 32, 33, 34, 35) - be arranged in a straight line and parallel to one another on a patient's body (O) and - A surface (FL) can be arranged spanning parallel to the magnetic field lines of the magnetic field (B). Procedure according to Claim 1 wherein the medical imaging system (40) comprises one of the following system types: - a magnetic resonance imaging system, - a computed tomography system. Method according to one of the preceding claims, wherein the measurement signal cables (32, 33, 34, 35) are arranged in such a way that they span a surface (FL) perpendicular to a patient support (42). Measurement signal cable arrangement (30) of a differential voltage measurement system in an area penetrated by a magnetic field (B) of a medical imaging system (40), comprising a plurality of measurement signal cables (32, 33, 34, 35) of different lengths, which are straight and parallel to one another on a patient's body (O) are arranged so that they are arranged spanning a surface (FL) parallel to the magnetic field lines of the magnetic field (B). Measurement signal cable arrangement according to Claim 4 , the measurement signal cables (32, 33, 34, 35) being arranged in such a way that they span a surface (FL) perpendicular to a patient support (42). Measurement signal cable arrangement according to Claim 4 or 5 , having cable guides, which lead electrodes further away from a measuring unit of the differential voltage measuring system over electrodes arranged closer to the measuring unit of the differential voltage measuring system. Measurement signal cable arrangement according to one of the Claims 4 to 6th which has a device for setting a variable length of the individual measurement signal cables (32, 33, 34, 35) in order to adapt them to a patient's shape, the device having a minimal area parallel to the patient support (42). Measurement signal cable arrangement according to Claim 7 , wherein the device has a device for tightly rolling up a spiral cable or a small cable drum, which are arranged on a distributor (31a) of the measurement signal cables (32, 33, 34, 35) perpendicular to the patient table (42). Measurement signal cable arrangement according to Claim 8 wherein the distributor (31a) comprises a stand with which it can be positioned next to a patient, so that the measurement signal cables (32, 33, 34, 35) are distributed in a plane perpendicular to the patient table (42). Differential voltage measuring system for measuring bioelectrical signals with a measuring signal cable arrangement (30) according to one of the Claims 4 to 9 . Medical imaging system (40), preferably a CT system, having a differential voltage measuring system Claim 10 .

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