System and method for providing flow-enhanced signal intensity during a functional MRI process

US 8,121,668 B2
Filed: 07/25/2008
Issued: 02/21/2012
Est. Priority Date: 07/25/2007
Status: Active Grant

First Claim

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1. A method for producing, with a magnetic resonance imaging (MRI) system, an image indicative of an imaging volume within a subject, the steps comprising:

a) acquiring from the imaging volume, a saturated image data set that is sensitized to at least one blood flow velocity by directing the MRI system to perform a pulse sequence that includes;

i) applying a tagging saturation radio frequency (“

RF”

) pulse to a localized region within the imaging volume;

ii) repeating step a)i) a plurality of times so that magnetization of blood flowing into the imaging volume at substantially only the at least one selected blood flow velocity from the localized region is substantially saturated;

iii) acquiring the saturated image data set following step a)ii);

b) acquiring from the imaging volume, a non-saturated image data set by directing the MRI system to perform a pulse sequence that acquires the non-saturated image data set such that magnetization of blood flowing into the imaging volume is substantially not saturated;

c) reconstructing a saturated image from the saturated image data set;

d) reconstructing a non-saturated image from the non-saturated image data set; and

e) producing, by subtracting the saturated image from the non-saturated image, a difference image indicative of blood flow in the imaging volume within the subject that occurs at the at least one blood flow velocity.

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Abstract

A method for imaging a brain of a subject includes providing a cognitive task for the subject or measuring resting state blood flow without a cognitive task, applying a saturation pulse sequence to saturate a slice within an imaging volume in the subject, and applying an imaging pulse sequence to acquire data from the imaging volume. A saturated image is acquired shortly after termination of the saturation pulse sequence and a non-saturation image is acquired after spins flowing through the saturated slice have recovered. The saturation image and the non-saturation image are subtracted to generate a blood velocity or perfusion enhanced difference image indicating portions of the brain active during the cognitive task. When measuring resting state blood flow without a cognitive task, the method includes acquiring a calibration scan and performing a quantitative evaluation of the blood velocity perpendicular to the saturated slice.

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14 Claims

1. A method for producing, with a magnetic resonance imaging (MRI) system, an image indicative of an imaging volume within a subject, the steps comprising:
- a) acquiring from the imaging volume, a saturated image data set that is sensitized to at least one blood flow velocity by directing the MRI system to perform a pulse sequence that includes;
  
  i) applying a tagging saturation radio frequency (“
  
  RF”
  
  ) pulse to a localized region within the imaging volume;
  
  ii) repeating step a)i) a plurality of times so that magnetization of blood flowing into the imaging volume at substantially only the at least one selected blood flow velocity from the localized region is substantially saturated;
  
  iii) acquiring the saturated image data set following step a)ii);
  
  b) acquiring from the imaging volume, a non-saturated image data set by directing the MRI system to perform a pulse sequence that acquires the non-saturated image data set such that magnetization of blood flowing into the imaging volume is substantially not saturated;
  
  c) reconstructing a saturated image from the saturated image data set;
  
  d) reconstructing a non-saturated image from the non-saturated image data set; and
  
  e) producing, by subtracting the saturated image from the non-saturated image, a difference image indicative of blood flow in the imaging volume within the subject that occurs at the at least one blood flow velocity.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
- - 2. The method as recited in claim 1 further comprising providing a functional task for the subject to perform during steps a)-b) so that the difference image is indicative of functionally-induced blood flow in the imaging volume resulting from the performance of the functional task.
  - 3. The method as recited in claim 1 in which step a)ii) includes adding a delay time between repetitions of step a)i) so that the saturated image data set acquired in step a)iii) is sensitized to the at least one blood flow velocity.
  - 4. The method as recited in claim 1 in which step a)iii) includes applying flow crusher gradients before the saturated image data set is acquired, and in which step b) includes applying flow crusher gradients before the non-saturated image data set is acquired so that MR signals from blood flowing at velocities above a selected threshold are substantially suppressed in the acquired saturated image data set and non-saturated image data set, respectively.
  - 5. The method as recited in claim 1 further comprising calculating a quantitative blood flow velocity from the difference image.
  - 6. The method as recited in claim 1 further comprising:
    - f) repeating step a) to acquire a second saturated image data set from the imaging volume; and
      
      g) reconstructing a second saturated image from the second saturated image data set.
  - 7. The method as recited in claim 6 further comprising calculating a volumetric blood flow rate using the saturated image reconstructed in step c), the second saturated image reconstructed in step g), and the non-saturated image reconstructed in step d).
  - 8. The method as recited in claim 7 in which the volumetric blood flow rate is calculated on a voxel-by-voxel basis according to:

9. A method for imaging an imaging volume within a subject with a magnetic resonance imaging (MRI) system, the steps comprising:
- a) acquiring from the imaging volume, a first saturated image data set by directing the MRI system to perform a pulse sequence that includes applying a tagging saturation radio frequency (RF) pulse to a localized region within the imaging volume before acquiring the first saturated image data set;
  
  b) acquiring from the imaging volume, a first non-saturated image data set by directing the MRI system to perform a pulse sequence that acquires the first non-saturated image data set such that magnetization of blood flowing into the imaging volume is substantially not saturated;
  
  c) acquiring from the imaging volume, a second saturated image data set by directing the MRI system to perform a pulse sequence that includes repeatedly applying a tagging saturation RF pulse to the localized region within the imaging volume so that magnetization of blood flowing into the imaging volume at substantially only the at least one selected blood flow velocity from the localized region is substantially saturated before acquiring the second saturated image data;
  
  d) acquiring from the imaging volume, a second non-saturated image data set by directing the MRI system to perform a pulse sequence that acquires the second non-saturated image data set such that magnetization of blood flowing into the imaging volume is substantially not saturated;
  
  e) reconstructing a calibration saturated image from the first saturated image data set;
  
  f) reconstructing a calibration non-saturated image from the first saturated image data set;
  
  g) reconstructing a saturated image from the second saturated image data set;
  
  h) reconstructing a non-saturated image from the second non-saturated image data set;
  
  i) calculating a quantitative signal enhancement from the calibration saturated image, the calibration non-saturated image, the saturated image, and the non-saturated image.
- View Dependent Claims (10, 11, 12, 13, 14)
- - 10. The method as recited in claim 9 in which the acquired second saturated image data set is sensitized by adding a delay time between the repeated applications of the tagging saturation RF pulse in step c).
  - 11. The method as recited in claim 9 further comprising applying flow crusher gradients before the second saturated image data is acquired in step c) and before the second non-saturated image data set is acquired in step d) so that MR signals from blood flowing at velocities above a selected threshold are substantially suppressed in the second saturated image data and the second non-saturated image data set.
  - 12. The method as recited in claim 9 further comprising calculating a quantitative blood flow velocity from the quantitative signal enhancement.
  - 13. The method as recited in claim 9 further comprising calculating a volumetric blood flow rate from the quantitative signal enhancement.
  - 14. The method as recited in claim 13 in which the volumetric blood flow rate is calculated on a voxel-by-voxel basis according to:

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Current Assignee
University of Illinois
Original Assignee
Board of Trustees of The University of Illinois
Inventors
Sutton, Bradley P., Ching, Bryce L., Ciobanu, Luisa
Primary Examiner(s)
Chen, Tse
Assistant Examiner(s)
REMALY, MARK DONALD

Application Number

US12/179,994
Publication Number

US 20090088626A1
Time in Patent Office

1,306 Days
Field of Search

600/407, 600/410, 600/419
US Class Current

600/419
CPC Class Codes

G01R 33/4806   Functional imaging of brain...

G01R 33/4838   using spatially selective s...

G01R 33/56308   Characterization of motion ...

G01R 33/56366   Perfusion imaging

System and method for providing flow-enhanced signal intensity during a functional MRI process

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System and method for providing flow-enhanced signal intensity during a functional MRI process

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