NL9402017A - Wireless transmission of high-frequency signals from an NMR surface coil. - Google Patents

Description

Title: Wireless transmission of high-frequency signals from an NMR surface coil.

Field of the invention

The invention relates to systems for magnetic resonance imaging and / or spectroscopy. In particular, the invention relates to methods and apparatus for obtaining a surface coil output signal in an NMR system using a wireless signal transmitter.

Background of the invention

The use of nuclear magnetic resonance imaging (NMR) of the human anatomy in the medical field and spectroscopy are increasingly widespread. Both procedures require the spacing of conductive channels around the object to be examined. After generating signals through these and other conductors under the influence of a very strong magnetic field, an image of the object can be electronically constructed from the high frequency ("RF") response of selected chemical bonds in the object.

Surface coils placed next to the object are intended to optimally block this high frequency response during magnetic resonance imaging ("MRI") or magnetic resonance spectroscopy ("MRS"). Such signals take the form of a circularly polarized or rotated magnetic field with a characteristic frequency in the high-frequency range. The rotation is aligned with the main magnetic field of the MR system. The surface coil device intercepts the high-frequency magnetic field and forms a high-frequency electric signal therefrom. This signal is usually transferred to the guest magnetic resonance system via an output cable, usually a high-frequency coaxial cable.

However, the connection of the coil to the host system by means of a conductive wire or cable limits the convenience and possibly the safety of the patient when such a device is used. The usual output cable puts a conductive cable, often in an undefined place and arrangement, in a powerful high-frequency field with both magnetic and electrical components. As a result, a spread of large high-frequency voltage potentials can occur. In addition, other hazards may be present as high frequency currents can be introduced into the coupled cables. These hazards could potentially result in patient burns or other injuries. Thus, there is a need to obtain the benefits of a surface flushing operation without compromising the convenience and safety caused by the output cable.

Summary of the invention

The object of the invention is to provide means for obtaining an output signal from the surface coil or comparable device in an NMR, MRI or MRS system without the complicated and possible safety problems of an output cable connecting the surface coil to the host MR system.

These and other objects can be realized according to the invention, which includes a nuclear magnetic resonance system capable of transmitting high frequency signals representing magnetic resonance images to a remote location. The system has a surface coil device suitable for generating a high-frequency signal from an object and sends this signal through a port. A modulator is connected to the gate and modulates the high-frequency signal using a carrier with a frequency different from the high-frequency coil signal. The modulated signal is then sent to a transmitter, which transmits the modulated high-frequency signal wirelessly to a remote receiver. The receiver sends the received modulated high-frequency signal to a demodulator, which in turn produces a reconstituted high-frequency signal and sends the reconstituted high-frequency signal to a guest magnetic resonance imaging system.

In a second embodiment, the system has a modulator, transmitter, receiver and demodulator capable of handling a plurality of signals on different channels at different frequencies. A second channel may be provided, for example, to transmit a second high-frequency signal generated by a second surface coil, such as is used at 90 ° phase shift with the first coil, or to transmit data from an additional device. Multiple channels can be used with multiple surface flush systems.

Brief description of the drawings

The invention may be better understood with reference to the detailed description taken in conjunction with the accompanying drawings, wherein like reference numerals designate like elements, and wherein: Fig. 1 is a schematic block diagram of a basic embodiment of the invention; Fig. 2 is a schematic block diagram of a second embodiment according to the invention in which wireless transmission of data of a high-frequency coil signal and an additional device occurs; FIG. 3 is a schematic block diagram of a third embodiment of the invention in which two surface coils transmit respective high-frequency signals on two channels; Fig. 4a is a schematic electrical block diagram of a portion of a radio transmission system of a high-frequency coil signal according to a further embodiment according to the invention; Fig. 4b is a schematic electrical block diagram of a portion of a wireless transmit / receive system in which a modified and reconstituted high-frequency coil signal is translated back to its original frequency; and FIG. 5 is a schematic electrical block diagram of a portion of a wireless transmitting / receiving system of a wireless MR signal in which the detection of an MR signal is immediately performed.

Detailed description of the preferred embodiment

The invention is best understood with reference to Fig. 1, in which a basic MRI / MRS imaging system is generally indicated by 12. The imaging system 12 has two main parts, a coil unit 14 indicated by a dotted box, and an analysis unit 16, indicated by a further dotted box. The unit 16 is physically disconnected or remote from the unit 14. The coil unit 14 has a surface coil device 18. The conductive surface coil device 18 is a standard MRI / MRS coil as is well known in the art. The coil device 18 may be designed to operate at 90 ° phase shift with, for example, another coil or any other number of other coil types sensitive to high frequency waves intended for MRI or MRS. An output signal port 20 of coil 18 is typically a coaxial cable connection. The output signal port 20 emits a high-frequency signal that can be processed to produce an MRI image. The system according to the invention can be connected to a coaxial cable connection 20 of existing magnetic resonance coils.

The surface coil device 18 generates an output signal through the output signal port 20 in the form of a high-frequency electric signal. A modulator 22 is connected to the gate 20 and modulates a carrier by adding the high frequency signal; the carrier wave has a frequency different from the guest MR system Larmour frequency. The carrier frequency is typically chosen higher than the guest MR system Larmour frequency. The carrier frequency should be chosen so that the modulated signal is quite far from the range of the magnetic resonance detector's sensitivity in order to avoid sound problems. Thus, preferably, the conversion of the frequency resulting from the modulation should be such that the dimensions of the transmit antenna 26 and the receive antenna 28 are acceptably small, and such that the resulting frequency can be easily processed by the demodulator 32.

The carrier modulation can occur with any known modulation method, resulting in preferred frequency transfer, including amplitude modulation (AM), frequency modulation (FM) and phase modulation. Other techniques such as digital transfer and pulse amplitude modulation can also be used.

The carrier wave modulated by the high-frequency signal is sent to a high-frequency transmitter 24 connected to the modulator 22. The output signal of the high-frequency transmitter 24 is emitted as electromagnetic radiation through a transmitter antenna 26 connected to the transmitter 24.

The electromagnetic wave is received by the receiving antenna 28 of the analysis unit 16. The receiving antenna 28 is connected to a high-frequency receiver 30 operating at the same carrier frequency as the transmitter 24. The receiver 30 transmits the received signal to the associated demodulator 32, which is suitable for demodulating or reconstituting the original surface coil output signal applied to the carrier by the modulator 22. The output of the demodulator 32 is transmitted through a surface coil signal port 34 to a guest MRI / MRS system 38. This signal is a reliable reproduction of the original coil output signal, but has reached its destination wirelessly without interconnecting coaxial cables or wires. This makes it possible to place the analysis unit 16 anywhere within the range of the radio reception of the coil unit 14, and not only in the immediate physical near vicinity thereof.

Various additional embodiments of the basic invention can provide specific advantages or possibilities.

A second embodiment of the invention is shown in Figure 2. The same figures indicate like parts as those in the first embodiment. An additional source device 38 is connected to a modulator 22 'through an input port 40. The modulator device 22' can either modulate the additional signal from device 38 into a second channel at a frequency different from the frequency of a main or first transmit channel, or can multiplex the additional signal with the surface coil high frequency signal and modulate the multiplex signal at a single transmit frequency. A demodulator 32 'demodulates correspondingly or two separate channels to receive a reconstructed supplemental signal and a reconstituted high-frequency coil signal, or demultiplexes and demodulates a single wireless signal to obtain it. The reconstituted additional signal is sent through a second output port 42 to an additional target device 22. The additional source device 38 and additional target device 44 may, for example, consist of a monitoring system for the heart, for breathing or associated with the flow, or a monitoring system for the heart, for breathing or associated with the flow.

Fig. 3 shows a multiple coil system, in particular a system comprising two coils 50 and 52, which are designed to operate at 90 ° phase shift in relation to each other or as coils in a series arrangement. The coil 50 generates a first high-frequency signal, which is sent through a first port 54 to a modulator 56, which has a channel A at a first carrier frequency and a channel B at a second carrier frequency different from the first frequency. The coil 52 generates a second high-frequency signal, which is sent via a second port 58 to channel B of the modulator 56.

The modulator 56 transmits the high-frequency signals from channel A and channel B to a radio transmitter 60, which transmits the signals on channels A and B via a broadcast antenna 62. The channel A and B radio waves are received via wireless transmission on a receiving antenna 64, which in turn is connected to a receiver 66. The receiver 66 passes the channel A and B modulated signals to a demodulator 68. The demodulator 68 demodulates the channel A signal to obtain the first reconstituted high-frequency signal generated from the coil 50.

The channel B signal is demodulated by demodulator 68 to obtain a second reconstituted high-frequency signal generated from the coil 52. The first reconstituted high-frequency signal is sent to a gate 70 of a guest MRI system 72 The second reconstituted high-frequency signal is sent to a separate port 74 of the MRI system 72.

For multiple coil systems, where the number of coils is greater than 2, the number of channels can be increased accordingly.

Additional embodiments of the invention are shown in Figs. 4a, 4b and 5, in which the same parts are designated by the same numbers as compared to Fig. 1.

In Figure 4a, a frequency converter 80 is interposed between the surface coil device 18 and the modulator 22, so that the high frequency coil signal 20 appears at its input. The frequency conversion of high-frequency signals converts the MR coil signal, which is typically about 64 megahertz and has a bandwidth of approximately 50 kilohertz, to a frequency of approximately half megahertz. The converted high-frequency coil signal is sent on line 82 to modulator 22, which modulates the converted high-frequency signal into a carrier for subsequent wireless transmission.

The converted and modulated signal can be received and easily demodulated, as in Fig. 1, or alternatively, a device as shown in Fig. 4b can be provided. In Fig. 4b, the transmitted high-frequency coil signal, after demodulation, passes through a line 84 to a further signal converter 86, so that the signal can be converted back to a frequency of 64 megahertz. The reconstituted high-frequency coil signal then passes to the guest MRI system 36 through line 34.

Fig. 5 shows a further embodiment according to the invention, in which the high-frequency coil signal appearing at input 20 is received by an MR receiver 88. The MR receiver 88 receives the high-frequency coil signal at input 20 and immediately detects the magnetic resonance information contained therein. An MR signal instead of the high-frequency coil signal appears at its output 90. The MR signal has a core frequency of 0 hertz. The MR signal is passed to modulator 22 as before for further modulation, transmission, reception, demodulation and use by the guest MRI system.

The above described embodiments are only illustrative of the principles of this invention. Other arrangements and advantages can be deduced by those skilled in the art without departing from the spirit and purpose of the invention. Accordingly, the invention is not intended to be limited to the detailed description described above, but only to the essence and object of the claims which follow below.

Claims (20)

Nuclear magnetic resonance coil system suitable for operating in a guest magnetic resonance Larmour frequency for resonance imaging or spectroscopy of an object, comprising: - a surface coil device suitable for generating a high-frequency signal through a gate; a modulator connected to the gate for modulating a carrier with the high-frequency signal, which carrier has a first frequency different from the high-frequency signal; a transmitter connected to the modulator for transmitting the modulated high-frequency signal near the first frequency; a receiver remote from the transmitter for wirelessly receiving the modulated high-frequency signal near the first frequency; a demodulator connected to the receiver for wirelessly receiving the modulated high-frequency signal near the first frequency; and - a guest magnetic resonance system connected to the demodulator for receiving the reconstituted signal thereof. System according to claim 1, characterized in that the first frequency is a higher frequency than that of the guest magnet is resonant larmour frequency. System according to claim 1, characterized in that it further comprises: an additional source device adapted to detect data from the object and connected to the modulator, which is capable of generating a modulated additional signal displaying the additional data ; the transmitter is adapted to transmit the modulated supplemental signal on a second frequency different from the first frequency; the receiver is capable of receiving the modulated additional signal; the demodulator is capable of assembling a demodulated supplementary signal; and an additional target device is connected to the demodulator to receive the demodulated additional signal therefrom. System according to claim 3, characterized in that the object is a patient; the additional source device includes a monitoring or control system for the heart. System according to claim 3, characterized in that the object is a patient; the additional source device includes a respiration monitoring or control system. System according to claim 3, characterized in that the additional source device comprises a monitoring or control system associated with the current. System according to claim 1, characterized in that the modulator is adapted to modulate a second high-frequency signal, the transmitter is capable of transmitting the modulated second high-frequency signal at a second frequency different from the first frequency, and the receiver is capable of receiving the modulated second high-frequency signal, and the demodulator is capable of demodulating a modulated second high-frequency signal. System according to claim 7, characterized in that a second surface coil generates a second high-frequency signal; the demodulated second high-frequency signal is transferred by the demodulator to the guest magnetic resonance system. System according to claim 8, characterized in that the first and second surface coils are capable of operating at 90 ° phase shift. System according to claim 8, characterized in that the first and second surface coils act as parts of a series circuit. System according to claim 1, characterized in that the transmitter is a radio transmitter and the receiver is a radio receiver. System according to claim 1, characterized in that it further comprises: a second source device connected to the modulator; the second source device is adapted to transmit a second source signal; the modulator receives the second source signal; a modulator multiplexer multiplexes the high frequency signal with the second source signal; the modulator sends a modulated and multiplex signal to the transmitter; the receiver receives the modulated and multiplex signal and passes it on to the demodulator, the demodulator demultiplexes and demodulates the modulated and multiplex signal to obtain a reconstituted high-frequency signal and a reconstituted second source signal; and a target device connected to the demodulator for receiving the reconstituted second source signal. System according to claim 12, characterized in that the object is a patient; the second source is an additional device suitable for viewing data from the patient. System according to claim 13, characterized in that the additional device is a monitoring or control system for the heart, a monitoring or control system for respiration, or a monitoring or control system associated with the flow. System according to claim 12, characterized in that a second source is a second surface coil; the target device is a second high-frequency signal port of the guest magnetic resonance system. Nuclear magnetic resonance system capable of operating at a guest magnetic resonance Larmour frequency for resonance imaging or spectroscopy of an object, comprising: - a first surface coil capable of generating a first high-frequency signal through a first port; a second surface coil suitable for generating a second high-frequency signal through a second port; - a modulator connected to the first and second ports for modulating a first carrier with the first high-frequency signal, said first channel carrier having a first frequency different from the first high-frequency signal, and for modulating a second carrier with the second high-frequency signal, the second channel carrier having a second frequency different from the first high-frequency signal; a transmitter connected to the modulator for transmitting the first and second modulated high-frequency signals near the first and second frequencies, respectively; a remote receiver from the transmitter for wirelessly receiving the first and second modulated high-frequency signals; a demodulator connected to the receiver for demodulating the first modulated high-frequency signal to obtain a reconstituted first high-frequency signal; and - a guest magnetic resonance system connecting a first port to the demodulator for receiving the reconstituted first high-frequency signal and connecting a second port to the demodulator for receiving the reconstituted second high-frequency signal. Method for functioning of a magnetic resonance imaging or spectroscopy system, comprising the following steps: - generating a high-frequency signal from a high-frequency coil arranged next to an object; - modulating the high-frequency signal using a frequency different from the high-frequency signal; - transmitting the modulated high-frequency signal via a wireless transmission; - receiving the modulated high-frequency signal; demodulating the received modulated high-frequency signal to obtain a reconstituted high-frequency signal; and - transmitting the reconstituted high-frequency signal to a guest magnetic resonance system. Nuclear magnetic resonance system suitable for operating on a guest magnetic resonance Larmour frequency for resonance imaging or spectroscopy of an object, comprising: - a surface coil device suitable for generating a high-frequency signal through a gate; a frequency converter connected to the gate for converting the frequency to a lower frequency and supplying a modified high-frequency signal to its output; - a modulator connected to the output of the frequency converter for modulating a carrier with the modified high-frequency signal, which carrier has a first frequency different from the modified high-frequency signal; a transmitter connected to the modulator for transmitting the modulated and modified high-frequency signal near the first frequency; a remote receiver from the transmitter for wirelessly receiving the modulated and modified high-frequency signal near the first frequency; a demodulator connected to the receiver for demodulating the modulated and modified high-frequency signal to obtain a reconstituted modified high-frequency signal; and - a guest magnetic resonance system connected to the demodulator for receiving the reconstituted modified high-frequency signal therefrom. Nuclear magnetic resonance system suitable for operating on a guest magnetic resonance Larmour frequency for resonance imaging or spectroscopy of an object, comprising: - a surface coil device suitable for generating a high-frequency signal through a gate; a frequency converter connected to the gate for converting the frequency to a lower frequency and supplying a modified high-frequency signal to its output; - a modulator connected to the output of the frequency converter for modulating a carrier with the modified high-frequency signal, which carrier has a first frequency different from the modified high-frequency signal; a transmitter connected to the modulator for transmitting the modulated and modified high-frequency signal near the first frequency; a remote receiver from the transmitter for wirelessly receiving the modulated and modified high-frequency signal near the first frequency; a demodulator connected to the receiver for demodulating the modulated and modified high-frequency signal to obtain a reconstituted modified high-frequency signal; - a second frequency converter connected to the demodulator for receiving the reconstituted modified high-frequency signal therefrom; the second frequency converter resets the frequency of the reconstituted modified high-frequency signal to the frequency of the high-frequency signal, thereby obtaining a reconstituted high-frequency signal; and - a guest magnetic resonance system connected to the second frequency converter for receiving the reconstituted high-frequency signal therefrom. Nuclear magnetic resonance system suitable for operating on a guest magnetic resonance Larmour frequency for resonance imaging or spectroscopy of an object, comprising: - a surface coil device suitable for generating a high-frequency signal through a gate; an MR receiver connected to the gate for directly detecting magnetic resonance information in the high-frequency signal, generating an MR signal in response to the detection of magnetic resonance information, and providing the MR signal at an output thereof; - a modulator connected to the output of the MR receiver for modulating a carrier wave with the MR signal, which carrier wave has a first frequency different from the MR signal; a transmitter connected to the modulator for transmitting the modulated MR signal near the first frequency; a remote receiver from the transmitter for wirelessly receiving the modulated MR signal near the first frequency; a demodulator connected to the receiver for demodulating the modulated MR signal to obtain a reconstituted MR signal; and - a guest magnetic resonance system connected to the demodulator for receiving the reconstituted MR signal therefrom.