Time and memory optimized method of acquiring and reconstructing multi-shot 3D MRI data
First Claim
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1. A method of magnetic resonance imaging comprising:
- (a) exciting magnetic resonance in a volume of interest;
(b) inducing a train of magnetic resonance echoes, said echoes generating magnetic resonance echo signals;
(c) computing an ordered list of k-space views to be sampled;
(d) phase and frequency encoding each magnetic resonance echo of the train into predetermined regions of a three-dimensional k-space in accordance with the ordered view list;
(e) sampling each encoded magnetic resonance echo to create a row of data;
(f) performing a plurality of one-dimensional Fourier transforms along a first direction on each row of data;
(g) assigning and storing the transformed rows of data in one of a plurality of predetermined fast-access memory buffers;
(h) upon sampling a complete plane of k-space, performing a plurality of Fourier transforms along a second direction which is orthogonal to the first direction;
(i) storing the twice-transformed data into an intermediate memory media; and
(j) upon sampling each k-space view in accordance with step (e), performing a plurality of Fourier transforms along a third direction which is orthogonal to the first and second directions, rendering a volumetric image representation.
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Abstract
A three-dimensional fast spin echo (FSE) scan is performed by stepping (220) through a plurality of phase encode k-space views from a computed view list (210). The view list is computed such that (i) magnetic resonance echoes having a selected image contrast are encoded in the center of k-space, (ii) adjacent data lines in k-space have similar contrast, and (iii) common planes of data lines in k-space are completed at regular intervals. As each data line is read, it is Fourier transformed (230) and stored (240) within a fast-access memory (52). Once a plane of data lines is acquired, it is Fourier transformed (250) along a second direction using a plurality of parallel processors (54). The twice-transformed data is stored (260) in conventional memory (56). Once all of the phase encode views on the view list are acquired, a final Fourier transform (60) along a third direction is performed (270), rendering a volumetric image representation. The method of data acquisition uses fewer memory buffers and takes less time than conventional methods.
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Citations
22 Claims
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1. A method of magnetic resonance imaging comprising:
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(a) exciting magnetic resonance in a volume of interest;
(b) inducing a train of magnetic resonance echoes, said echoes generating magnetic resonance echo signals;
(c) computing an ordered list of k-space views to be sampled;
(d) phase and frequency encoding each magnetic resonance echo of the train into predetermined regions of a three-dimensional k-space in accordance with the ordered view list;
(e) sampling each encoded magnetic resonance echo to create a row of data;
(f) performing a plurality of one-dimensional Fourier transforms along a first direction on each row of data;
(g) assigning and storing the transformed rows of data in one of a plurality of predetermined fast-access memory buffers;
(h) upon sampling a complete plane of k-space, performing a plurality of Fourier transforms along a second direction which is orthogonal to the first direction;
(i) storing the twice-transformed data into an intermediate memory media; and
(j) upon sampling each k-space view in accordance with step (e), performing a plurality of Fourier transforms along a third direction which is orthogonal to the first and second directions, rendering a volumetric image representation. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
ordering the k-space views to be sampled such that magnetic resonance echoes having a desired T1 and T2 contrast are encoded within the center of the three-dimensional k-space.
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3. The magnetic resonance imaging method according to claim 2, wherein step (c) further includes:
ordering the k-space views to be sampled such that successive k-space views are within a common plane along the second direction which is orthogonal to the first direction.
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4. The magnetic resonance imaging method according to claim 1, wherein step (c) is performed in response to at least one inputted scan parameter, said scan parameters including (i) primary phase encode resolution;
- (ii) secondary phase encode resolution;
(iii) fractional undersampling;
(iv) echo train length; and
(v) desired contrast.
- (ii) secondary phase encode resolution;
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5. The magnetic resonance imaging method according to claim 1, wherein steps (f), (h), and (j) are performed by a plurality of parallel Fourier transform processors.
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6. The method of magnetic resonance imaging according to claim 1, wherein the sampled portions of the three-dimensional k-space are ellipsoidal in cross-sectional shape.
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7. The method of magnetic resonance imaging according to claim 6, wherein unsampled portions of the three-dimensional k-space are zero-filled.
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8. The method of magnetic resonance imaging according to claim 1, wherein step (j) is performed from the center of k-space outward, producing an initial low-resolution volumetric image representation.
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9. In a magnetic resonance imaging apparatus in which a main magnetic field is generated through a volume of interest, radio frequency pulses are transmitted for exciting and inverting magnetic resonance dipoles within the volume of interest to generate a train of magnetic resonance echoes, gradient magnetic fields are generated to phase and frequency encode the magnetic resonance echoes, and a receiver receives and demodulates the magnetic resonance echoes to produce a series of k-space views, a method of magnetic resonance data acquisition includes:
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receiving at least one inputted scan parameter;
dividing a three-dimensional k-space into a plurality of regions, each region to be filled by data from one echo of the train of echoes;
computing an optimized data collection command list in response to the at least one inputted scan parameter, said data collection command list including a plurality of phase encode instructions to fill rows of k-space which lie in common planes;
in accordance with the optimized data collection command list stepping through the plurality of phase encode views, each view producing a row of data;
Fourier transforming each row of data as it is collected;
storing the once transformed data in a plurality of fast-access memory buffers;
upon collection of one complete plane of k-space data, performing a second Fourier transform on the data;
storing the twice transformed data in a magnetic media memory; and
upon collecting all of the phase encode views on the command list, performing a third Fourier transform on the data. - View Dependent Claims (10, 11, 12, 13, 14)
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15. A magnetic resonance volume imaging method comprising:
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exciting a plurality of multi-echo imaging sequences, each sequence having n echoes, where n is a plural integer, the n echoes having n progressively changing contrast levels, each echo being read out along a frequency encode axis and being phase encoded along first and second phase encode axes perpendicular to the frequency encode axis and each other;
phase encoding the echoes such that echoes with a preselected level of contrast are encoded closest to a center of k-space, echoes with a contrast farthest from the preselected contrast are phase encoded closest to a periphery of k-space, and echoes with other contrasts are phase encoded proportionately in between;
reading out echoes to form data lines;
one-dimensionally Fourier transforming each data line;
storing the one-dimensionally transformed data lines until a full plane of data lines is stored;
Fourier transforming the stored plane of data lines in a second dimension;
storing the two-dimensionally transformed planes of data lines until a full volume of data lines is stored;
Fourier transforming the full volume of data lines in a third dimension to create a volumetric image representation. - View Dependent Claims (16, 17, 18)
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19. A magnetic resonance apparatus comprising:
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a main magnet for generating a temporally constant magnetic field through an examination region;
a radio frequency transmitter for exciting and inverting magnetic resonance dipoles within the examination region to generate a train of magnetic resonance echoes;
gradient magnetic field coils and a gradient magnetic field pulse amplifier for generating at least phase and read magnetic field pulses in orthogonal directions across the examination region;
a receiver for receiving and demodulating the magnetic resonance echoes to produce a series of k-space views;
a view-order processor which computes a view list of phase encode k-space views to be sampled;
a scan controller which steps through the view list, said scan controller controlling the gradient pulse amplifier and radio frequency transmitter to generate a plurality of fast spin echo (FSE) pulse sequences;
a plurality of Fourier transform processors which perform a plurality of one-dimensional Fourier transforms along three orthogonal directions on the received k-space views;
a fast-access memory for selectively storing once Fourier transformed k-space views; and
a magnetic media memory portion for storing twice Fourier transformed k-space planes. - View Dependent Claims (20, 21, 22)
means for optimizing the order of the view list according to a desired T1 and T2 contrast; and
means for optimizing the order of the view list in order to fill rows of k-space which lie in common planes.
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Specification
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Current AssigneeMarconi Medical Systems, Inc. (Koninklijke Philips N.V.)
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Original AssigneePhilips Medical Systems (Cleveland) Incorporated (Koninklijke Philips N.V.)
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InventorsAnand, Christopher K., Halamek, James A., Steckner, C. Michael
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Primary Examiner(s)ARANA, LOUIS M
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Application NumberUS09/719,000Time in Patent Office587 DaysField of Search324/307, 324/309, 324/306, 324/312, 324/314, 324/300US Class Current324/309CPC Class CodesG01R 33/4822 in three dimensions
