The present disclosure relates to an RF probe for use within the field of nuclear magnetic resonance, such as magnetic resonance imaging (MRI) and magnetic resonance spectroscopy (MRS).
The human or animal body is largely composed of water molecules which each contain two hydrogen nuclei or protons. When a person goes inside the powerful static magnetic field of an MR scanner, the magnetic moments of these protons align with the direction of the field. A radio frequency (RF) electromagnetic field is then briefly turned on, causing the protons to alter their magnetization alignment relative to the static field. When the RF field is turned off the protons return to the original magnetization alignment. These magnetization alignment changes create a signal which can be detected by the MR scanner. However, MRI is not limited to imaging of hydrogen nuclei. It is also used for imaging carbon, phosphorus, and other nuclei, e.g. in MRS.
The magnetic resonance frequency of the protons depends on the strength of the applied static magnetic field. The position of protons in the body can be determined by applying additional gradient magnetic fields during the scan which allows an image of the scanned subject to be created. These additional magnetic fields are provided by gradient coils. Subatomic particles have the quantum mechanical property of spin. When these spins are placed in a strong external magnetic field they precess around an axis along the direction of the static field. In the static magnetic fields commonly used in MRI, the energy difference between the nuclear spin states corresponds to a radio frequency photon. Resonant absorption of energy by the protons due to an external oscillating magnetic field will occur at the Larmor frequency for the particular nucleus.
A radio frequency transmitter can create the magnetic field which rotates the net magnetization using a pulse sequence. When the radio frequency pulse is turned off, the transverse vector component produces an oscillating magnetic field generating an RF signal. This can induce a small current in a radio frequency (RF) probe, such as an RF receiver coil. An RF receiver can therefore detect the transverse magnetization as it precesses in the XY plane in the scanner, thereby detecting RF electromagnetic radiation produced by the nuclear relaxation inside the scanned subject.
The RF transmitter and RF receiver probes may be one and the same device which serves as the transmitter of the magnetic fields and receiver of RF energy from the imaged object. Traditionally, these RF transmitting and receiving probes are referred to as RF coils, because they are typically formed as coils or comprise coils. There are various types of RF coils, e.g. volume coils that are configured to surround the imaged object while surface coils are configured to be placed adjacent to the imaged object. Examples of volume coils are birdcage coils (pictured in
An RF coil must resonate, or efficiently store energy, at the Larmor frequency and is therefore typically composed of an inductor, or inductive elements, and a set of capacitive elements. The resonant frequency of an RF coil is determined by the equivalent inductance (L) and capacitance (C) of the circuit.
U.S. Pat. No. 5,107,217 shows an example of a radio frequency antenna for nuclear magnetic resonance tomography apparatus having interior conductors which form a transmission line resonator. A hollow cylindrical waveguide (sheet 2 in
GB 2,159,958 contains an example of prior art embodied in the form of an RF field generating and detecting arrangement (
One health issue within MRI is due to the powerful RF transmitter necessary for generating the RF field for exciting the protons. If the body absorbs the energy, heating occurs. This is quantified as specific absorption rate (SAR). Other issues within magnetic resonance are the eternal quest for improving the resulting image quality and the complexity and fabrication costs of the probe.
One embodiment of the present disclosure relates to an RF probe for magnetic resonance imaging and/or spectroscopy comprising a conductive non-magnetic hollow waveguide having an internal volume and at least one open end, one or more capacitors and at least a first conductive non-magnetic wire, wherein said first conductive wire connects at least one of said one or more capacitors to opposite walls of one open end of the waveguide and wherein said first conductive wire and said one or more capacitors are located outside of said internal volume, wherein the internal volume of the hollow waveguide defines an imaging volume or sample volume. This internal volume of the hollow waveguide preferably defines an imaging volume, e.g. in case of MRI, and/or sample volume, e.g. in case of MRS. Waveguide in the scope of the present invention can be understood as a hollow non-magnetic, conducting pipe or tube and is described in greater detail below.
The RF probe as disclosed herein is thus suitable as RF transmitting and/or RF receiving probe for use in MRI and/or MRS and preferably configured to surround at least a part of the subject of interest. Alternatively, the RF probe could be referred to as a volume probe for magnetic resonance imaging and/or spectroscopy.
There are several inductive components which are capable of storing energy in a magnetic field. These components can be used to generate a magnetic field in RF probes for MRI. One of such components is a conductive non-magnetic hollow waveguide. Such a waveguide has an intrinsic cutoff frequency. Below this cutoff frequency the waveguide can exhibit inductive behavior and concentrate magnetic field inside its interior. This field can then be used to excite a sample or subject in MR. One or more capacitors can be connected to the waveguide such that the structure resonates at a certain predefined frequency of operation—the Larmor frequency—and thereby provide an RF probe suitable for use in MRI. The configuration of the waveguide and the connected capacitor(s) can be selected such that the resonance frequency of the RF probe is below the cutoff frequency of the waveguide.
The presently disclosed RF probe can potentially reduce health risks associated with high field MRI because the SAR is smaller, MR image quality can be improved due to the possibility of increased homogeneity of the magnetic field, and fabrication and operation costs can be reduced due to reduced complexity of the design in comparison to the traditional probes (e.g. RF coils).
The herein disclosed RF probe is thus preferably suitable for magnetic resonance imaging and/or for magnetic resonance spectroscopy.
The invention will now be described in further detail with reference to the drawings in which
MRI scanners require RF shielding nearly 100% of the time. RF shielding must create a complete box with all walls, ceiling, and flooring covered with an RF shield. The RF shield can be made of almost any metal, but the most common types of metals are copper, galvanized steel and aluminum. The RF shield thereby keeps out spurious signals both from foreign transmitters and from the driving electronics of the MRI system itself. As an example, the typical performance required of an MRI shield is to achieve 100 dB of RF signal attenuation at 100 MHz. The RF shield forms a complete box around the MRI system and the RF shield thereby forms a Faraday cage: a closed conductive structure, i.e. an electrically continuous envelope of conductive material that is connected to ground. Everything that is to come into the MRI room must pass through an RF filter or waveguide. RF filters are mounted on the RF shield and create a penetration point for electrical power for lighting or powered outlets within the MRI room. RF filters also accommodate data cables.
In the field of MRI RF shielding waveguides are used as penetrations in the RF shield that allow the passage of non-electric elements into the MRI room without compromising the shielding effectiveness. Water, gas or air all provide a fluid flow, which is non-current-carrying, and thus require a waveguide. Waveguides are typically conductive tubes that attenuate any RF noise entering the tube. The diameter of the waveguide determines the cutoff frequency, i.e. any frequency below the cutoff frequency will be attenuated. Waveguides come in a variety of shapes and sizes depending on the application. A dielectric (such as air) is typically included in the construction of the waveguide in order to maintain electrical isolation between the shielded enclosure and the outside environment. Pictures of copper waveguides in RF shielding for MRI are shown in
In the present disclosure a waveguide is applied in an RF probe for MR. The purpose of an MRI probe is to generate (or sense) a certain magnetic field distribution in a subject or sample. There are several inductive components which are capable of storing energy in a magnetic field. These components can be used to generate a magnetic field in MRI probes. One of such components is a piece of a circular or rectangular metallic waveguide as illustrated in
Using this waveguide as an RF probe for MR requires that the capacitive elements are moved outside the waveguide, and that at least one end of the waveguide is open. Such an opening of the waveguide will typically not result in radiation loss because the waveguide is operating below its cutoff frequency. The opening can be used to place the capacitive elements out of the volume of the waveguide. The resulting structure is shown in
The capacitor can alternatively be substituted by two series connected capacitors (e.g. with doubled value) creating the symmetry in the structure and contributing to the homogeneity of generated fields. This is illustrated in
As stated previously, the capacitive element(s) are selected such that the resonance frequency of the RF probe is below the cutoff frequency of the hollow waveguide. Below cutoff hollow waveguides are e.g. known from microwave filters where circuit elements (capacitors, inductors, or both) are inserted inside the hollow waveguide. With components inside the internal volume of the waveguide the use of such structures as MR probes is prevented since the internal volume of the probe is adapted for the subject or sample that is to be examined. Within the field of magnetic resonance there is usually no room for the circuit elements inside the internal volume of MR probes. In the presently disclosed RF probe the components that allows for below cutoff operation have been located outside of the internal volume of the hollow waveguide such that there is room for (at least a part of) a subject or a sample inside this internal volume.
As stated, a waveguide in the scope of the present invention can be understood as a hollow non-magnetic conducting pipe or tube and the intended functionality of the waveguide is to provide below cut-off operation together with appropriate selected capacitors. There are several possible shapes of the waveguide to obtain the desired functionality, e.g. in the form of a pipe. Further, the side surface of the waveguide/pipe, i.e. the side surface that extends in the axial extension of the waveguide/pipe, is preferably one closed surface. This means that it shapes an internal closed volume inside the waveguide/pipe. However, the ends of the waveguide/pipe may be open; the waveguide of the presently disclosed RF probe has at least one open end. An example of a pipe is a hollow cylinder. This example can be seen in
In
With a pipe/tube design with the side surface that extends in the axial extension of the pipe being a closed surface, or a surface being partly or completely meshed as described, the desired below cut-off operation can be achieved and a homogenous generated field can be generated with the appropriate selection of capacitors, which can be used to excite a sample or subject in MR.
The principle of the presently disclosed RF probe is illustrated in
In one embodiment the hollow waveguide comprises two open ends. Symmetric RF probes with two open ends may improve the homogeneity of the applied RF field.
In a further embodiment at least two capacitors are provided wherein said first conductive wire connects two of said capacitors to opposite walls of one open end of the waveguide. An example of this is illustrated in
In yet a further embodiment at least two capacitors and at least a second conductive non-magnetic wire are provided, wherein the second wire connects at least one of said capacitors to opposite walls of the opposite end of the waveguide. A more homogeneous field may be provided if one or more capacitors are provided at both ends of a linear waveguide. Thus, at least four capacitors may be provided wherein said second conductive wire connects two of said capacitors to opposite walls of the opposite end of the waveguide. And likewise at least eight capacitors may be provided, wherein said second conductive wire connects four of said capacitors to the opposite end of the waveguide, said four capacitor connections preferably distributed evenly around the rim of said opposite end of the waveguide.
The conductive wire and the capacitive elements are located outside of the internal volume of the waveguide. Thus, the first and/or the second conductive non-magnetic wire may be placed in axial extension of the waveguide. E.g. as illustrated in
In one embodiment of the present disclosure the hollow waveguide is straight and/or elongated, e.g. cylindrical as illustrated in
Likewise the cross-section of the hollow waveguide may take any shape, however preferably the cross-section is convex. Thus, the cross-section may be elliptical, such as circular. The cross-section of the hollow waveguide may form a polygon, preferably an equilateral and/or convex polygon, a polygon such as a triangle, square, pentagon, hexagon, heptagon, etc.
In one embodiment of the present disclosure the hollow waveguide and/or the first and second conductive wires are manufactured in a non-magnetic metal, such as copper, aluminium, or steel.
In one embodiment of the present disclosure the hollow waveguide and/or the conductive wire(s) is a self-supporting structure. E.g. is manufactured in copper, the material is strong enough to be self-supporting. However, it may be advantageous to provide the waveguide with a thin surface. Thus, the waveguide and/or the first and second conductive wires may be mounted on a dielectric support structure, e.g. as illustrated in
In order to excite (or sense) the field in the presently disclosed RF probe standard excitation schemes can be used. E.g. magnetic loops positioned perpendicular to the magnetic field vector, or monopoles parallel to the electric field vectors, can be introduced to the waveguide. However, these conventional excitation schemes are not convenient since this would require placing the excitation elements in the internal volume of the RF probe. A more efficient way is to apply (or collect) a signal between the waveguide and the conductive wire, e.g. between the waveguide and the conductive ring as illustrated in
The presently disclosed RF probe can potentially offer the following advantages over the prior art:
The health risk in MRI is quantified by the Specific Absorption Rate (SAR) values; the lower the SAR the smaller the health risk.
MR image quality depends on homogeneity of the field. The estimated homogeneity of the field (defined as a ratio between minimum and maximum of the field) for the present RF probe in the z direction is over 61% in comparison to 43% for the traditional birdcage probe as illustrated in
The presently disclosed RF probe requires much less circuit components compared to e.g. the birdcage probe. This is an important economical aspect since MR compliant components are often costly.
Prior to MR imaging a fine tuning for optimal operation is often required for an RF probe with the subject/sample inside the probe. It is found that with the presently disclosed probe this fine tuning is easier than the traditional birdcage probe. This can save a considerable amount of operation time during the preparations to the scanning procedure and it can also reduce the required time for a patient to be inside the scanner.
It is furthermore noted that the models for the traditional birdcage probes are comparatively complicated. The presently disclosed RF probe allows for more simplified and robust analysis which can significantly reduce the development time and cost.
The cutoff frequency fc of a circular waveguide can be calculated as
where c is a speed of light, a is the radius of the waveguide, ∈r is the relative permittivity of the waveguide filling (1 for air).
Waveguides behave inductively below cutoff. The capacitance of the RF probe can therefore be chosen such that the structure resonates at a desired frequency f0 using Thomson formula:
where L is the equivalent inductance of the waveguide.
Below cutoff waveguide analysis can be conveniently formulated in terms of conventional network concepts. This formulation can then be used for analytical modeling of the structure. In the following analysis, currents and voltages are employed as measures of the fields within the below cutoff structure. The network analysis may be effected on an impedance basis.
Symmetric RF probes with two open ends can be used to construct probes with longer length by cascading several identical RF probes, i.e. connecting them in series as illustrated in
The impedance matrix for the section of a below cutoff waveguide, [Zi], is given by (cf. Pozar: “Microwave Engineering”, Wiley; 4th ed.):
Here Z0(w) is the characteristic impedance, γw is the propagation constant, and li is the length of the corresponding waveguide section i, with i=1, 2, 3, . . . .
In order to apply transmission line theory to waveguides, the propagation constant and characteristic impedance of the particular guide configuration should be determined, as can be seen from the equation above.
The propagation constant of the circular waveguide is γw=α+jβnm where
The cutoff frequency can be determined as
where α is the radius of the waveguide.
The attenuation constant is α=αd+αc.
Attenuation due to the material filling the waveguide (subject to image) can be calculated as
Attenuation due to conductor loss in waveguide can be calculated as
where k=ω√{square root over (μ∈)} is the wave number, and
is the cutoff wave number. p′nm=1.841.
The intrinsic impedance of the material filling the waveguide can be calculated as η=√{square root over (μ/∈)}.
The surface resistance of the metal can be calculated as
where σ is the conductivity of the employed metal. The value for copper is 5.8e7 S/m. It has been found that the most accurate results are achieved using power-voltage definition for the characteristic impedance of the waveguide.
The matrix for the capacitive elements [ZC] is defined by the impedance of the capacitor, simply 1/jωC, where C is the value of the capacitors. Using the model described above, the parameters of the present RF probe (diameter, length, and capacitance values) can be found iteratively.
One exemplary RF probe is shown in
The RF probe can be connected to an MR system with a cable. A standard coaxial cable 4 is used in this realization refer to
The presently disclosed RF probe may be configured to provide both linear and circularly polarized fields. Both polarizations are typically used in MR but circular polarization allows for better sensitivity than the linear polarization. One or two signal sources (i.e. cables) are required for linear field, as it is shown in
Two RF probe prototypes for different volumes have been fabricated as shown in
Number | Date | Country | Kind |
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13190433.6 | Oct 2013 | EP | regional |
The present application is a continuation of PCT/EP2014/073085 filed Oct. 28, 2014, which claims priority of European Patent Application 13190433.6 filed Oct. 28 2013, the entire contents of which are incorporated herein by reference.
Number | Date | Country | |
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Parent | PCT/EP2014/073085 | Oct 2014 | US |
Child | 15141257 | US |