DE102009019896A1 - Device for use in diagnostic magnetic resonance device to detect heart movements of patient, has signal analysis unit extracting signal corresponding to heart movements of patient from changes caused by heart movements - Google Patents

Abstract

The device has a high frequency signal generator and a signal analysis unit that are connected with a local-receiving antenna system (18). The signal analysis unit detects changes of electrical characteristics of the local- receiving antenna system and extracts a signal corresponding to heart movements of a patient (6) from the changes that are caused by the heart movements. The electrical characteristic is a reflection factor of an antenna element (18A) in the antenna system. The signal generator is connected with a signal line by a frequency switch.

Description

The The invention relates to a device for detecting heart movements in a diagnostic magnetic resonance apparatus having a local receive antenna system.

at of medical imaging become more specific when taking pictures anatomical areas recorded physiological signals and for synchronization or trigger the image capture used. So z. B. image captures of the heart by means of magnetic resonance technique (MR technique) with ECG signals (Electrocardiography signals) synchronized. Here is the capture including the transfer of physiological Signals because of the technical-physical conditions of the magnetic resonance devices only possible with special MR-compatible devices. MR-compatible means that the devices used neither disturbing the operation of the MR device, nor itself impaired by the operation of the MR device in their function become. In addition, it must still be ensured that the patient to be examined is not endangered.

It on the other hand, is often required vital functions of the Patients continuously monitor, so before, during and after taking the picture. This happens with patient monitoring systems, the z. B. monitor cardiac function via ECG signals and deliver a signal when an abnormal condition occurs.

to Capturing the heartbeat will usually be normal ECG electrodes via special MR-compatible signal transmission means also connected to MR-compatible evaluation devices. The However, attaching the ECG electrodes is expensive. Not Carefully attach the ECG electrodes to the one to be examined Patients can also cause incorrect measurements.

One Another known method detects heartbeat-synchronous signals using light sensors on the fingers. In the light measuring method can have runtime effects due to the not insignificant Distance from the heart to the measuring point lead to incorrect measurements.

In the ISMRM publication of Graesslin et al., "An Alternative Concept of Non-sequence Interfering Patient Respiration Monitoring", published in Proc. Intl. Soc. Mag. Reson. Med., Vol. 16, 2008, p. 202 , a method and a measuring arrangement for detecting the respiratory movement in an MR device is described. The fact is exploited that the respiratory movement of a patient in a high-frequency antenna affects their electrical properties. Measuring coils or pick-up coils (PUC) are used to measure the complex transmission currents in each channel of an 8-channel transmission system of the MR device. The measuring coils are used in normal operation for calibration purposes and for safety monitoring. The advantage here is that there are no interactions with the high-frequency and gradient signals required for imaging. With this concept, the respiratory movement of the patient can be detected from the amplitude change of the measurement signal in the size of approx. ± 1% in the magnetic resonance device. A limitation in the method described therein, however, is that only during the relatively short emission of the high-frequency excitation pulse, the breathing movement is detected.

Of the Invention is now the object of a reliable To provide a device for detecting heart movements in a magnetic resonance device, which is easy to handle. Here are the heart movements also over can be monitored for a longer period of time.

The The object is achieved with the subject matter of claim 1.

Therefore the invention is realized on a device for detection of heart movements in a diagnostic magnetic resonance device with a local receive antenna system. It is with the local receiving antenna system a high-frequency signal generator and a signal analysis unit are connected, wherein the signal analysis unit is formed changes electrical characteristics of the local receiving antenna system, which are caused by the heart movements, to recognize and from it to extract a signal corresponding to the heart movements. There the heart movement so without additional ECG measurement arrangements can be detected directly with the MR device, is the patient preparation considerably simplified. It must be before taking MRI image no ECG electrodes are attached. The detection of the heart movement takes place without contact with the local antennas as sensors. In addition, so is the source of error, the insufficiently mounted ECG electrodes represent completely eliminated. The measurement of the heart movement is not due to the short time of transmission of the radio frequency excitation pulse limited, it can in particular before the start of the measurement sequence start and so the trigger time for the beginning of Determine image acquisition reliably.

In the application, the local receive antenna system is positioned as directly above and / or below the heart as possible. This is advantageous both for recording the heart movement and for the actual image acquisition itself. The change in the geometry of the heart, especially due to muscle contraction, or even through the heart shock induced redistribution of the electrically conductive blood volume modulates accordingly the electrical properties of the local receiving antenna system. This change is measured and the corresponding signal can be used after signal conditioning to trigger the MR image acquisition or for patient monitoring.

In An advantageous embodiment of the invention are the high-frequency signal generator and the signal analysis unit having an antenna element of the local receiving antenna system connected, wherein the electrical property of the reflection factor of the antenna element. The heart movement causes a corresponding change the characteristic impedance of the connected antenna element, whereby a signal wave traveling towards the antenna element more or less reflected. The returning or reflected wave can then be measured and evaluated.

at A further advantageous embodiment of the high-frequency signal generator and the signal analysis unit with different antenna elements connected to the local antenna system, the electrical property is the transmission factor between the antenna elements. It will the coupling of the two modulated by the heart movements Antenna elements measured and evaluated.

A Another advantageous embodiment is characterized in that the local antenna system is formed double resonant, wherein the first of the resonance frequencies an operating frequency of the magnetic resonance apparatus and the second of the resonance frequencies of an operating frequency of the high frequency signal generator corresponds and wherein both operating frequencies are different. This embodiment also allows it to continue receiving the magnetic resonance signal to measure a signal analogous to the movement of the heart.

A further, particularly advantageous embodiment of the invention is characterized characterized in that the high-frequency signal generator via a first crossover is connected to a signal line, wherein the signal line both for transmission of the operating frequency of the magnetic resonance apparatus as well as the working frequency of the High-frequency signal generator is formed, and that the local receiving antenna system via a second crossover is connected to the signal line for Off and / or coupling of signals with the working sequence of High-frequency signal generator. With the intended feed and decoupling via crossovers becomes only a single Signal line needed, both for transmission the actual magnetic resonance signal as well as for transmission the signal used to represent the cardiac movement becomes.

A Another advantageous embodiment is characterized in that the operating frequency of the high frequency signal generator equal to the Operating sequence of the magnetic resonance device is and that Signal analysis unit on parts of the receiving system of Magnetic resonance system is connected to the local antenna system. In this embodiment, parts of the receiving system of the magnetic resonance apparatus both for the received magnetic resonance signals as well used for signal conditioning and evaluation of the signals affecting the heart movement represent.

at a further advantageous embodiment, in the parts of the receiving system of the magnetic resonance apparatus also for signal transmission used the signal of heart movement, used in more advantageous Way a coupler, for feeding the signal of the high frequency signal generator.

Further Embodiments of the invention are described below explained with reference to 11 figures. Show it:

1 in an overview representation of the essential functional units of a diagnostic magnetic resonance apparatus with a device for detecting heart movements,

2 a first measuring device for detecting the heart rate-modulated reflection factor on an antenna element,

3 a second embodiment of a measuring device for detecting heart movements, which measures the transmission modulated by the heart movement between two antenna elements,

4 a third measuring device for detecting heart movements, which uses parts of the receiving system of the magnetic resonance apparatus and detects the reflection on an antenna element,

5 a fourth embodiment of a measuring device for detecting heart movements, which also uses parts of the receiving system of the magnetic resonance apparatus, but evaluates the transmission between two antenna elements,

6 a fifth embodiment of a measuring device for detecting heart movements whose operating frequency differs from the operating frequency of the magnetic resonance device,

7 a sixth embodiment of a Measuring device for detecting heart movements, in which the signal of the heart movement and the magnetic resonance signal are transmitted via the same signal line,

8th a seventh embodiment of a measuring device, similar to the measuring device according to 6 in which the transmission modulation is measured between two antenna elements,

9 an eighth measuring device for detecting heart movements, similar to the measuring device according to 7 in which, however, the transmission between two antenna elements is measured,

10 the reflection factor modulated by the heart movement with its real and imaginary parts during a breath holding period and

11 the reflection factor modulated by the heart movement with its real and imaginary parts during respiration and a subsequent breath holding period.

1 shows an overview of the structure of a diagnostic magnetic resonance apparatus with the essential components, as they are important for the embodiments of the invention described below.

The outer ones Dimensions of the diagnostic magnetic resonance device shaped by the magnet, which is used to polarize the Imaging used atomic nuclei is needed. The diagnostic Imaging takes place almost exclusively via hydrogen nuclei (1 H nuclei).

In 1 is a superconducting magnet 2 shown in cross-section, which is itself cylindrical and a cylindrical bore 4 having. In the center of the cylindrical bore 4 the magnet generates 2 a homogeneous magnetic field area, wherein the imagined parts of a patient 6 be stored. For insertion and removal of the patient in or from the imaging area of the magnetic resonance device is a movable in its longitudinal direction patient bed 8th intended. For spatial encoding of the magnetic resonance signals, a gradient system is present, which is in the cylindrical bore 4 arranged gradient coils 10 and a gradient control 12 comprising the currents necessary to generate the magnetic gradient fields. To excite the magnetic resonance signals, a high-frequency system is necessary. The high frequency system includes a whole body antenna 14 that are inside the gradient coils 10 is arranged. Furthermore, the high-frequency system comprises a high-frequency transmitter 16 , the one with the whole-body antenna 14 connected is. The whole-body antenna 14 and the radio frequency transmitter 16 together make up the high frequency broadcasting system. A high frequency receiving system 17 comprises receive amplifiers and furthermore receive signal processing for the received magnetic resonance signals. Furthermore, the Hochfre frequency receiving system includes 17 a local receive antenna system 18 , The local receive antenna system is exemplified by three antenna elements 18A . 18B . 18C In fact, however, the number of antenna elements in the local receiving antenna system is higher. The antenna elements 18A . 18B . 18C are as close as possible to be imaged parts of the patient 6 arranged, resulting in comparison to the whole-body antenna 14 to achieve a higher signal-to-noise ratio from the corresponding range.

A controller 20 controls the sequence of the pulse sequence used for the imaging, in particular the gradient fields required for the spatial encoding and the high-frequency transmission pulses for the excitation of the magnetic resonance. The control 20 further comprises a reconstruction unit with which the received magnetic resonance signals are finally transformed into image data that can be displayed on a display unit. The control 20 is essentially realized by a correspondingly programmed control computer and thus includes hardware and software components. The display is part of a user interface 22 further comprising a keyboard and the input means for controlling the magnetic resonance device via a graphical user interface.

To avoid motion artifacts when imaging areas of the patient 6 which move more or less periodically, the imaging pulse sequence signal pulses used for imaging must be coordinated according to the motion. Particularly in the case of cardiac imaging, the imaging sequence is controlled as a function of the heart's movement. This is a signal processing module 24 provided with the local receiving antenna system 18 connected is. This signal connection is in 1 shown only schematically, special implementations are hereinafter in the embodiments of the 2 to 9 described.

At the in 2 illustrated embodiment, the signal processing module 24 a network analyzer 26 that has a first switch 28 a signal line 30 connected is. The signal line 30 is at the other end over and two more switches 32 and 34 with the antenna element 18A of the local receive antenna system 18 connected. The signal line 30 is also used for signal transmission from the antenna element 18A received magnetre resonant signal to the radio frequency receiving system 17 , In the periods when no magnetic resonance signal is received, the switches are 28 . 32 . 34 in the in 2 illustrated switching position. When receiving, all switches are 28 . 32 . 34 brought into their other switching position, in which case a preamplifier in the receiving channel 38 between the antenna element 18A and the input of the radio frequency receiving system.

The network analyzer 26 includes a high frequency signal generator 40 , which is a traveling wave to the antenna element 18A sends. The frequency of the outgoing wave corresponds to the operating frequency of the magnetic resonance apparatus and thus also the resonance frequency of the antenna element 18A , Amplitude and phase of the traveling wave are also known. Due to the heart movement and the associated displacement of the blood volume, the adaptation of the antenna element changes 18A to the signal line 30 , whereby a correspondingly modulated return wave to the network analyzer 26 is sent back. In the network analysis technique, this signal is also referred to as scattering or S-parameter S ₁₁ . One in the network analyzer 26 also included signal analysis unit 41 decomposes the returning wave into its real and imaginary parts, which are then processed individually or together to form a measurement signal. The measuring signal is then at the output 42 of the network analyzer 26 issued.

3 shows an embodiment of the invention, in which instead of the reflection modulated by the heart movements transmission behavior between two antenna elements 18A and 18B is measured. The two antenna elements 18A and 18B are over the signal line 30 or via another signal line 46 with the high frequency receiver 17 connected. As with the signal line 30 will also be the signal line 46 via switch 48 . 50 . 52 switched according to the currently desired mode. The drawn switching position corresponds to the operating mode for measuring the heart movement. In the other switching position, not shown, of the antenna elements 36 and 44 received magnetic resonance signals via the preamplifier 38 and 50 to the radio frequency receiving system 17 be transmitted. The in the network analyzer 26 contained signal analysis unit 41 in this case evaluates the transmission signal, which is changed by the heart movement, that is to say attenuated or amplified and / or phase-shifted, with its real and imaginary parts. In the network analysis technique, this signal is also referred to as scattering or S-parameter S ₁₂ .

The in the 4 and 5 illustrated embodiments of the invention are characterized in that no switches are used and that parts of the receiving system 17 of the magnetic resonance apparatus for signal processing of the heart movement signal to be used with.

According to the embodiment 4 is a high-frequency signal generator 56 provided, via a directional coupler 58 with the antenna element 36 connected is. The high frequency signal generator is similar to the high frequency signal generator 40 in the network analyzer 26 , The high frequency signal generator 56 sends as a signal a traveling wave with a frequency that the working frequency of the magnetic resonance device and thus also the resonance frequency of the antenna element 18A equivalent. Amplitude and phase of the traveling wave are known. Similar to the embodiment of 2 the heart movement reflects a corresponding modulated wave through the preamplifier 38 the input of the radio frequency receiving system 17 is supplied. The in high frequency receiving system 17 The existing demodulator and digitizer demodulates and digitizes the signal received as a return wave and decomposes it into its real and imaginary parts. The two components real and imaginary part or a signal derived therefrom are then at the output 42 the controller 20 made available.

The embodiment according to 5 differs from the embodiment according to 4 in that not the reflection, but the transmission modulated by the heart movement between the antenna elements 18A and 18B is evaluated. The two antenna elements 18A . 18B are each via a preamplifier 38 respectively. 58 with the input of the radio frequency receiving system 17 connected. Between the high frequency signal generator 56 and the preamplifier 38 is a directional coupler 58 arranged, over which the antenna element 18A the signal to be modulated is supplied. According to the coupling between the two antennas 18A and 18B becomes the antenna 18A supplied signal in amplitude and / or phase position changed by the antenna element 18B received and over the preamp 58 the high frequency receiving part 17 fed. After a corresponding signal processing, similar to the embodiment according to 4 is the signal modulated according to the heart movement at the output 42 issued.

The above embodiments have in common that the frequency of the high-frequency generator 26 . 56 generated signal is identical to the operating frequency of the magnetic resonance device. The embodiments described below after the 6 to 9 on the other hand use different working frequency for the high of the working frequency of the magnetic resonance device frequency signal generator 26 . 56 ,

So shows 6 an embodiment with a network analyzer 60 whose operating frequency differs, for example, by 20% from the operating frequency of the magnetic resonance apparatus. Larger differences between the two frequencies are also possible, the decoupling of the two signals is then easier. A double-resonant antenna element 62 , which has resonance points both at the operating frequency of the high-frequency generator as well as the working frequency of the magnetic resonance device, is directly connected to a network analyzer 60 connected. The magnetic resonance signal is transmitted in a conventional manner via the preamplifier 38 the radio frequency receiving unit 17 fed. The network analyzer 60 sends a traveling wave to the double-resonant antenna element 62 , Changes in the characteristic impedance caused by the cardiac motion, in turn, produce a correspondingly modulated return wave from the network analyzer 50 evaluated and as a useful signal at the output 42 is delivered.

7 shows a further embodiment, which also works with a different from the operating frequency of the magnetic resonance device operating frequency for detecting the heart movement. However, unlike the embodiment, there is 6 no reflection measurement, but a transmission measurement provided. This is another double-resonant antenna element 64 provided with the first double-resonant antenna element 62 about the part of the patient to be imaged 6 is coupled. The double-resonant antenna element 64 is connected to the transmission input of the network analyzer 60 connected. At the exit 42 is from the network analyzer 60 then output a corresponding processed signal, whereupon the heart movement is formed.

The embodiment according to 8th differs from the embodiment according to 6 just in that a common signal line 30 both for the signal of the network analyzer 60 as well as for the magnetic resonance signal is used. Over a first crossover 66 will be the one from the network analyzer 60 discharged traveling wave on the line 30 coupled. In front of the output of the preamplifier 38 comes with a second crossover 68 the signal of the outgoing wave from the line 30 decoupled and on the double-resonant antenna element 62 guided. The from the double-resonant antenna element 62 reflected return wave is via the second crossover 68 back on the line 30 coupled in and over the first crossover 66 correspondingly decoupled and the reflection measuring input of the network analyzer 60 fed.

This in 9 illustrated embodiment in turn measures in contrast to the embodiment according to 8th the transmission between the two antenna elements 62 and 64 , The from the network analyzer 60 emitted traveling wave is over the first crossover 66 on the signal line 30 given, and with the second crossover 68 decoupled again and the double-resonant antenna element 62 fed. The antenna element 64 recorded and modulated by the heart movement signals are then via a third crossover 70 on a signal line 72 given and over the fourth crossover 74 the transmission input of the network analyzer 50 fed. The transmission signal is from the network analyzer 60 then evaluated by amount and phase or by real and imaginary part and at the output 42 delivered as a useful signal.

Examples of the waveform modulated by cardiac motion are in FIGS 10 and 11 shown. It is in both figures to the reflection signal S ₁₁ that with its real part 82 and his imaginary part 84 over a period of 10 s. The unit for the amplitude modulation is 0.05%. While the reflection factor in 10 is a measurement with breath hold technology, is at 11 shown how the respiratory movement affects the measurement signal. There, in addition to the first 6 seconds of the measurement recording, a modulation in the signal caused by the respiratory motion can be detected. Breathing is stopped only in the last 4 seconds. However, the heart movement signal can be filtered out with a corresponding signal processing from the mixed signal of respiratory and cardiac motion, because the frequency positions of the two signals are different. Filtering as well as correlation techniques for separating the two signals from each other are suitable.

Out the corresponding filtered out heart movement signal then, for example, according to amount formation of real and imaginary part derive a trigger signal for the image acquisition sequence. Of the Trigger time is derived from the heart movement signal by for example, after a moving averaging of the signal the zero crossing of the heart movement signal is detected. additionally can still increase the accuracy of the triggering time an adjustable delay for the zero-crossing signal be provided.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited non-patent literature

• - Graesslin et al .: "An Alternative Concept of Non-sequence Interfering Patient Respiration Monitoring", published in Proc. Intl. Soc. Mag. Reson. Med., Vol. 16, 2008, p. 202 [0006]

Claims (7)

Device for detecting heart movements in a diagnostic magnetic resonance apparatus with a local receiving antenna system ( 18 ) characterized in that with the local receive antenna system ( 18 ) a high-frequency signal generator ( 40 . 56 ) and a signal analysis unit ( 41 ), the signal analysis unit ( 41 ), changes of electrical properties of the local receive antenna system ( 18 ), which are caused by the heart movements, and from this a signal corresponding to the heart movements ( 80 . 82 ) to extract. Device according to Claim 1, characterized in that the high-frequency signal generator ( 40 . 56 ) and the signal analysis unit ( 41 ) with an antenna element ( 18A . 62 ) of the local receive antenna system ( 18 ), wherein the electrical property of the reflection factor of the antenna element ( 18A . 62 ). Device according to Claim 1, characterized in that the high-frequency signal generator ( 40 . 56 ) and the signal analysis unit ( 41 ) with different antenna elements ( 18A . 18B . 62 . 64 ) of the local receive antenna system ( 18 ), wherein the electrical property of the transmission factor between the antenna elements ( 18A . 18B . 62 . 64 ). Device according to one of claims 1 to 3, characterized in that the local receiving antenna system ( 18 ) is formed double-resonant, wherein the first of the resonance frequencies of an operating frequency of the magnetic resonance apparatus and the second of the resonance frequencies of an operating frequency of the high-frequency signal generator ( 40 . 56 ) corresponds. Apparatus according to claim 4, characterized in that the high-frequency signal generator ( 40 . 56 ) via a first crossover ( 66 ) with a signal line ( 30 ), the signal line ( 30 ) both for the transmission of the operating frequency of the magnetic resonance apparatus as well as the operating frequency of the high-frequency signal generator ( 40 . 56 ) and that the local receive antenna system ( 18 ) via a second crossover ( 68 ) with the signal line ( 30 ) is connected to the extraction and / or coupling of signals with the operating frequency of the high-frequency signal generator ( 40 . 56 ). Device according to one of claims 1 to 3, characterized in that the operating frequency of the high-frequency signal generator ( 40 . 56 ) is equal to the operating frequency of the magnetic resonance device and that the signal analysis unit ( 41 ) over parts of the receiving system ( 17 ) of the magnetic resonance apparatus with the local antenna system ( 18 ) connected is. Apparatus according to claim 6, characterized in that the high-frequency signal generator ( 40 . 56 ) via a coupler ( 58 ) with the local receive antenna system ( 18 ), the coupler ( 58 ) between the receiving system ( 17 ) of the magnetic resonance apparatus and of the local receiving antenna system ( 18 ) is arranged.