Self-shielded split gradient coil

Abstract

Gradient coil assemblies for horizontal magnetic resonance imaging systems (MRIs) and methods of their manufacture. Some embodiments may be used with open MRIs and can be used with an instrument placed in the gap of the MRI. In general, concentrations of conductors or radially oriented conductors may be moved away from the gap of the MRI so as to reduce eddy currents that may be induced in any instrument placed within the gap. Systems for directly cooling primary gradient and shield coils may be utilized and various coil supporting structures may be used to assist in coil alignment or to facilitate use of an instrument in the MRI gap.

Claims

1. A system comprising: a horizontal magnetic resonance imaging system (MRI) having a gap; an instrument being located within a portion of the gap for use with the MRI; and a gradient coil assembly comprising: a supporting structure having a first portion and a second portion, each supporting structure portion mounted to a respective one of a first and second main magnet of the MRI having the gap separating the first and second main magnet; a Z gradient shield coil disposed within the supporting structure; and a Z gradient primary coil disposed within the supporting structure between the Z gradient shield coil and a longitudinal axis, wherein a concentration of turns in the Z gradient primary coil is minimized near the gap such that an eddy current effect for the system is less than 0.5% in a 50 cm diameter of spherical volume (DSV).

2. The system of claim 1, wherein electrical connections between the Z gradient primary coil and the Z gradient shield coil are located at least 5 centimeters from the gap.

3. The system of claim 1, wherein the Z gradient primary coil is formed as cylindrical conductors about the longitudinal axis.

4. The system of claim 1, wherein the Z gradient primary coil is directly cooled.

5. The system of claim 4, wherein the Z gradient primary coil includes a hollow conductor.

6. The system of claim 5, further comprising two cooling units.

7. The gradient coil assembly system of claim 1, wherein electrical connections between the Z gradient primary coil and the Z gradient shield coil are located at outer ends of the gradient coil assembly away from the gap.

8. The system of claim 1, wherein the Z gradient primary coil is further configured to have an eddy current effect variation of less than 0.23% in the 50 cm DSV.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Features, aspects, and embodiments of the disclosure are described in conjunction with the attached drawings, in which:

(2) FIG. 1 shows a perspective view of a horizontal open MRI with an instrument located in its center gap region, as can be used with some embodiments of the present disclosure;

(3) FIG. 2 shows a simplified cross-sectional view of some embodiments of the system shown in FIG. 1;

(4) FIG. 3 shows a simplified and expanded cross-sectional view of some embodiments of the gradient coil assembly shown in FIG. 2;

(5) FIG. 4 shows a simplified and expanded cross-sectional view of an alternative embodiment of the gradient coil assembly shown in FIG. 2;

(6) FIG. 5A shows a simplified layout of an embodiment of an X gradient primary coil;

(7) FIG. 5B shows a cross sectional view an embodiment of a conductor used with the embodiment of an X gradient primary coil shown in FIG. 5A;

(8) FIG. 5C shows a chart of current paths for an unfolded single quadrant of the embodiment of an X gradient primary coil shown in FIG. 5A;

(9) FIG. 6A shows a simplified layout of an embodiment of an X gradient shield coil;

(10) FIG. 6B shows a cross sectional view an embodiment of a conductor used with the embodiment of an X gradient shield coil shown in FIG. 6A;

(11) FIG. 6C shows a chart of current paths for an unfolded single quadrant of the embodiment of an X gradient shield coil shown in FIG. 6A;

(12) FIG. 7A shows a simplified layout of an embodiment of a Y gradient primary coil;

(13) FIG. 7B shows a cross sectional view an embodiment of a conductor used with the embodiment of a Y gradient primary coil shown in FIG. 7A;

(14) FIG. 7C shows a chart of current paths for an unfolded single quadrant of the embodiment of a Y gradient primary coil shown in FIG. 7A;

(15) FIG. 8A shows a simplified layout of an embodiment of a Y gradient shield coil;

(16) FIG. 8B shows a cross sectional view an embodiment of a conductor used with the embodiment of a Y gradient shield coil shown in FIG. 8A;

(17) FIG. 8C shows a chart of current paths for an unfolded single quadrant of the embodiment of a Y gradient shield coil shown in FIG. 8A;

(18) FIG. 9A shows a simplified layout of an embodiment of a Z gradient primary coil;

(19) FIG. 9B shows a cross sectional view an embodiment of a conductor used with the embodiment of a Z gradient primary coil shown in FIG. 9A;

(20) FIG. 9C shows a chart of axial position current paths for a half of the embodiment of a Z gradient primary coil shown in FIG. 9A;

(21) FIG. 10A shows a simplified layout of an embodiment of a Z gradient shield coil;

(22) FIG. 10B shows a cross sectional view an embodiment of a conductor used with the embodiment of a Z gradient shield coil shown in FIG. 10A;

(23) FIG. 10C shows a chart of axial position current paths for a half of the embodiment of a Z gradient shield coil shown in FIG. 10A.

DETAILED DESCRIPTION

(24) The gradient coil assembly of the present disclosure may be used with any type of horizontal magnetic resonance imaging (MRI) system. It is particularly well suited for use with a split solenoid or horizontal open MRI that includes a gap between two horizontal MRI magnet halves. The gradient coil assemblies disclosed herein are further well suited for use with a horizontal open MRI that is used with an additional medical instrument being operated within its gap. FIG. 1 depicts such an arrangement with a horizontal open MRI 100 having a gap region 102. An instrument 104 is mounted in the gap region 102 on a gantry 110. Also depicted are a patient 106 and patient couch 108. In some embodiments, the gantry 110 can be used to reposition the instrument 104 about the patient 106 (i.e., about the Z-axis shown in FIG. 1).

(25) The embodiment of FIG. 1 can include elements of a system of the assignee of the current application, ViewRay, Inc., described, in part, in U.S. Patent Application Publication 2005/0197564 to Dempsey, titled System for Delivering Conformal Radiation Therapy while Simultaneously Imaging Soft Tissue (hereafter Dempsey '564), which is hereby incorporated by reference. For example, the instrument 104 can comprise a radiation therapy device and associated multi-leaf collimator (MFC), which, in combination with a fast-imaging horizontal open MRI, allows for improved radiation therapy that accounts for target location during treatment, as discussed in Dempsey '564. While only a single assembly is shown as the instrument 104 in FIG. 1, some embodiments can include multiple assemblies associated with instrument 104. For example, some embodiments may include three radiation head assemblies (not shown in FIG. 1) mounted in gap 102, distributed about the Z-axis, and rotatable about the Z-axis on the gantry 110. While some aspects of the embodiments disclosed herein are described with respect to the ViewRay system disclosed by Dempsey '564, such aspects are not required for use with the disclosed gradient coil assembly. It is contemplated that the gradient coil assembly disclosed herein may be used in any type of MRI, with or without the use of an associated instrument 104. Furthermore, for systems utilizing an instrument 104, such instruments are not limited to radiation therapy devices such as radiation sources, or a LINAC, but can include any type of instrument used with an MRI.

(26) FIG. 2 is diagrammatic cross-section of the system shown in FIG. 1. The embodiment of FIG. 2 depicts a horizontal open MRI 100 including a pair of main magnets 200a and 200b, separated by gap 102. The MRI is used to image a region of interest 202 above patient couch 108. The MRI 100 can include additional conventional components not shown, for example, an RF system, including RF coils, and potentially one or more shim coils. The coordinate system used in the figures and throughout this disclosure refers to the longitudinal axis through the MRI bore as the Z-axis. The X-axis extends perpendicular to the Z-axis and from side to side of the MRI 100; the Y-axis extends perpendicular to the Z-axis and from the bottom to the top of MRI 100.

(27) An embodiment of the gradient coil assembly 204 disclosed herein is depicted in FIG. 2 along with its associated coolers 206a,b and amplifier 208, described in detail below. In this embodiment, the gradient coil assembly 204 is supported by mounts 212 that may be located both at the outer ends of the main magnets, as well as near the MRI gap. Exemplary mounts are vibration isolating devices such as the IsoDamp C1002 sold by E-A-R Specialty Composites, a division of Aearo Technologies. Gradient coil assembly 204 may be directly mounted to main magnets 200a,b. However, electrical currents in gradient coil assembly 204 in the presence of the main magnetic field (generated by main magnets 200a,b) create torques, forces, and vibrations that can drive vibration and heat into main magnets 200a,b and increase boil-off. Inclusion of mounts 212 both at the outer and gap ends of main magnets 200a,b can provide for improved vibration isolation and reduce the unsupported span of gradient coil assembly 204.

(28) FIG. 3 shows an expanded, more detailed cross-sectional diagram of an embodiment of gradient coil assembly 204. This embodiment of gradient coil assembly 204 contains X, Y, and Z shield coils (300, 302, 304 respectively) and Z, X and Y primary gradient coils (306, 308, 310 respectively). The embodiment also contains connections 312 between each of the respective coil pairs (connecting X shield coil 300 to X primary coil 310, Y shield coil 302 to Y primary coil 308, and Z shield coil 304 to Z primary coil 306) located at the outer ends of gradient coil assembly 204 (away from the gap 102). The coils 300-310 are disposed within a supporting structure 314, which may be made from a material such as an epoxy resin.

(29) As an example, in some implementations of this embodiment, the inner diameter of the gradient coil assembly 204 can be about 800 mm and the outer diameter can be about 1044 mm, in combination with an MRI 100 having a gap 102 that is approximately 200 mm wide and where the length between the outer ends of the gradient coil assembly 204 is about 2190 mm. These dimensions are provided merely as an example and should not be considered limiting, as the dimensions may vary.

(30) The disclosed gradient coil assembly 204 may be formed as two separate halves, so as to leave the gap 102 open for uninhibited physical access to the patient 106. Such an open configuration allows for use with an additional instrument 104, for example, a radiation treatment system. However, it is not necessary for the gap 102 to remain completely open, as long as any obstruction does not result in excessive attenuation of, for example, a radiation beam that may be emitted from instrument 104. In the present embodiment, the gradient coil assembly 204 is of singular construction, having a gap portion 316 of supporting structure 314. The gap portion 316 traverses the gap 102 and is a thin, uniform structure constructed for uniform and minimal radiation attenuation (for example, less than 5% attenuation in the case where a 60Co -ray source is used). In the preferred embodiment, gap portion 316 is a portion of a continuous inner former that can be made from material that is stable in the radiation environment, for example, an epoxy-fiberglass or epoxy-carbon fiber structure. Its thickness can be, for example, approximately 5 mm, and its density can be, for example, less than or equal to 2 g/cm3. One advantage of this continuous structure is that opposite sides of gradient coil assembly 204 are naturally aligned, eliminating troublesome two-part gradient alignment issues and associated asymmetric eddy currents and imaging fields. Another advantage of the instant embodiment is improved mechanical damping and support, mechanically balancing and stabilizing the forces and torques experienced by the gradient coils in operation. It is contemplated that gap portion 316 can be provided with access ports cut into it or can be removed after the installation of gradient coil assembly 204.

(31) FIG. 4 depicts an alternative embodiment for the gap portion of supporting structure 400, which contains gradient coils traversing the gap 102. Z gradient coils are naturally gapped, but in this embodiment, primary X and Y coils 308 and 310 can be continuous across the gap 102 and can be made, for example, from aluminum (e.g., sheet coils or wound conductors directly cooled). Aluminum is an example of a conductor with lower density than copper and will thus be beneficial in applications where the gradient coil assembly is used with an instrument 104 delivering radiation therapy to region 202. An important aspect of this embodiment is that supporting structure 400 has a radiation attenuation that matches the attenuation of the included conductors, so that attenuation will be consistent across the structure. In the case of aluminum coils, supporting structure 400 could include an epoxy-filament wound tube with, for example, glass or carbon filaments and appropriate fillers such as alumina between the coils. The uniform attenuation of this alternative design will facilitate accurate radiation delivery and dose calculations.

(32) The alternative embodiment of FIG. 4 will have greater beam attenuation (for the case including a radiation therapy device as instrument 104) due to its increased thickness and inclusion of gradient coils. However, this embodiment has the advantage of increasing the usable field of view of the MRI because it will not experience the loss of linearity of gradient field strength associated with a split design and will avoid the problem of radial rollover of the transverse gradient fields.

(33) Turning now to FIGS. 5-10, and with reference to FIG. 3, specific embodiments of the gradient and shield coils will be explained in greater detail. The present embodiment is described with reference to a horizontal open MRI having an instrument 104 employed in the gap, although it is understood that many aspects of the disclosure may be applied to single magnet MRIs used without associated instruments. The instrument 104 of the present example can be, for example, the radiation therapy device previously discussed, although it is understood that many other treatment or imaging modalities may be used with the present disclosure such as biopsy needles, ablation devices, surgical devices, ultrasound, PET, SPECT, CT, LINAC and others.

(34) The radiation device of the present example comprises three equally spaced Cobalt 60 heads with associated multi-leaf collimators (MLCs), for example, as disclosed in Dempsey '564 and incorporated herein by reference. The MLCs are typically composed of computer-controlled tungsten leaves that shift to form specific patterns, blocking portions of the radiation beams and shaping them according to a predetermined treatment plan. These MLCs are preferably placed close to or within gap 102 and are typically made of tungsten with aluminum housings, both conductive materials. When such materials are placed in the vicinity of the time varying currents of gradient coil assembly 204, eddy currents will be induced in them. Eddy currents induced in instrument 104 will result in power dissipation in the device and can also interfere with imaging. In the case of MLCs, heat may cause thermal expansion of individual leaves and interfere with their operation. Other instruments including conductive materials that may be used with the disclosed system would be faced with similar problems.

(35) The presently disclosed gradient coil assembly 204 reduces these issues, in part, by moving common concentrations of conductors away from the gap 102. For example, gradient-to-shield interconnects in horizontal split gradients are typically located adjacent the radial surfaces of the gradient coil assemblies facing the gap 102. However, the presently disclosed gradient coil assembly 204 moves such connectors 312 away from the gap 102. For example, the connectors may be preferably spaced at least 50 mm from gap 102, although the present disclosure contemplates that the connectors may be closer than 50 mm from the gap 102. In the embodiments depicted in FIGS. 3 and 4, the connections 312 are located at the outer edges of gradient coil assembly 204. Moving concentrations of current created by radially oriented conductors away from the gap 102 will reduce eddy currents induced in any instrument 104. In addition, concentrations of longitudinally oriented conductors or loops are minimized near the gap 102 and the eyes of fingerprint coils are preferably located at least 50 mm from gap 102. Furthermore, while prior horizontal split magnet gradient coils have included radially oriented loops along the region of gap 102, the present disclosure preferably moves any such radially oriented conductors at least 50 mm from gap 102. In the exemplary embodiments disclosed in FIGS. 5-10, the gradient and shield coils are substantially cylindrical in shape. While a cylindrical shape is preferred, the disclosed coils can be other shapes that do not result in additional conductor and current concentrations near the gap 102.

(36) Referring now to the exemplary X gradient primary coil 308 depicted in FIG. 5A, the coil includes 11 forward and 2 reverse turns in each of its identical quadrants. The connections between turns (for example, juggles) are not depicted as is common in the art. The centroids of the current paths (all single turns) are shown in FIG. 5C. The X gradient primary coil 308 includes reverse turns at its ends away from gap 102 to compensate for thrust and torque forces. Among other things, this compensation reduces forces on the thin, continuous gap portion of supporting structure 316 (or 400) described as part of this embodiment. The Y gradient coil 310 similarly includes 11 forward and 2 reverse turns as shown in FIGS. 7A and 7C. The shield coils for both the X and Y gradients (300 and 302) of this embodiment include 5 turns in each of their identical quadrants as shown in FIGS. 6A, 6C, 8A, and 8C. The Z-gradient primary coil (306) of this embodiment has 42 total turns as shown in FIGS. 9A and 9C and the Z gradient shield coil has 28 total turns as shown in FIGS. 10A and C. Additional parameters for some implementations of the exemplary coils discussed herein are detailed in Table 1 below.

(37) TABLE-US-00001 TABLE 1 Example Coil Characteristics Property X Gradient Y Gradient Z Gradient Mean radius (Primary) 414.31 408.21 421.86 [mm] Mean radius (Shield) 516.45 510.35 502.80 [mm] Conductor Thickness 7 mm 7 mm 8 mm [mm] 5.1 mm 5.1 mm 8 mm hollow hollow hollow conductor conductor conductor Number of Turns 11fwd/2rev 11fwd/2rev 28 (total) (Primary) (per quadrant) (per quadrant) Number of Turns 5 (per 5 (per 28 (total) (Secondary) quadrant) quadrant) Total Electrical Coil 1533.81 1533.81 1407.38 Length (Primary) [mm] Total Electrical Coil 1274.74 1264.74 1533.80 Length Secondary [mm] DC Resistance (Primary) 68.29 68.28 52.98 [m] DC Resistance (Secondary) 33.18 33.18 42.09 [m] DC Resistance (Total) 101.47 101.46 95.07 [m] Inductance [H] 227.10 224.38 356.325 Non-Linearity [%] 2.81/3.23/ 2.37/5.2/ 4.14 over 17.5 cm/25 21.69 25.46 cm/30 cm Non-Uniformity [%] 33.35 32.89 11.0 over 17.5 cm Radial Rollover Z = 0.0 mm 27.7 cm 27.1 cm No Z = 25 mm 28.0 cm 27.4 cm rollover Z = 50 mm 30.0 cm 29.7 cm Z = 75 mm 34.1 cm 33.6 cm Z = 100 mm No rollover No rollover Gradient Strength 16.0 16.0 16.0 [mT/m] Current [A] for 528.93 510.40 356.29 G = 16 mT/m Sensitivity [T/m/A] 30.25 31.348 44.91 Slew rate [mT/m/ms] at 228.44 237.00 227.76 G = 16 mT/m and V = 1800 V Rise Time [s] 76.82 73.24 78.71 Net Thrust Force [N] at 6.92 4.64 2.34 G = 16 mT/m Net Torque on each half 79.6 72.43 0.0 [N*m] at G = 16 mT/m Eddy Current Effect <1.0% <1.0% <0.5% (50 cm DSV) Eddy Current Effect 0.42% 0.42% 0.23% Variation (50 cm DSV)

(38) To meet performance specifications on the order of those in Table 1, including a 16 mT/m gradient strength and slew rate of approximately 200 mT/m/ms, a current driver with high voltage and current capability is desirable. In the instant embodiment, gradient coil assembly 204 can be driven with an amplifier 208 such as a Siemens SQ gradient amplifier capable of delivering 65 OA maximum current and 2000V maximum voltage, although other amplifiers or multiple amplifiers could be used. The high current and current densities existing in the coils of the present disclosure are preferably cooled by direct cooling through the core of each coil. The instant embodiment employs separate coolers (206a and 206b) at each end of MRI 100 and each primary and shield coil is made with a hollow core as shown in cross section FIGS. 5B, 6B, 7B, 8B, 9B and 10B. The dimensions of the X and Y primary and shield coil cross sections in this embodiment can be the same, for example with a 7 mm by 5.1 mm width and height, and a 4.6 mm by 2.6 mm center lumen. The dimensions of the exemplary Z primary and shield coils can be, for example, 8 mm by 8 mm with a 6 mm diameter center lumen. While direct cooling can be used in the present example, other methods of cooling known in the art, such as indirect cooling, or a combination of direct and indirect cooling, may be used.

(39) While various embodiments in accordance with the disclosed principles have been described above, it should be understood that they have been presented by way of example only, and are not limiting. Thus, the breadth and scope of the invention(s) should not be limited by any of the above-described exemplary embodiments, but should be defined only in accordance with the claims and their equivalents issuing from this disclosure. Furthermore, the above described advantages are not intended to limit the application of any issued claims to processes and structures accomplishing any or all of the advantages.

(40) Additionally, section headings shall not limit or characterize the invention(s) set out in any claims that may issue from this disclosure. Specifically, and by way of example, although the headings refer to a Technical Field, such claims should not be limited by the language chosen under this heading to describe the so-called technical field. Further, the description of a technology in the Background is not to be construed as an admission that technology is prior art to any invention(s) in this disclosure. Neither is the Summary to be considered as a characterization of the invention(s) set forth in issued claims. Furthermore, any reference to this disclosure in general or use of the word invention in the singular is not intended to imply any limitation on the scope of the claims set forth below. Multiple inventions may be set forth according to the limitations of the multiple claims issuing from this disclosure, and such claims accordingly define the invention(s), and their equivalents, that are protected thereby.