NON-CONTRAST MRI WITH DIFFERENTIATION OF ISCHEMIC, INFARCT AND NORMAL TISSUE

US 20150216429A1
Filed: 04/17/2015
Published: 08/06/2015
Est. Priority Date: 08/16/2012
Status: Active Grant

First Claim

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1. A magnetic resonance imaging (MRI) system comprising:

an MRI gantry having static and gradient magnet assemblies and at least one radio frequency (RF) coil defining an image volume;

MRI control circuits connected to control components within said MRI gantry and configured to effect MRI data acquisition sequences of RF and gradient magnetic pulses which elicit MRI signals to acquire and process said elicited MRI signals into MR image data;

said MRI control circuits being configured to(a) acquire multi-dimensional MR k-space datausing multiple data acquisition subsequences for each of multiple time to inversion (TI) intervals without using an injected contrast agent;

(b) reconstruct said acquired k-space data into a series of spatial domain MR image data each having different TI intervals;

(c) perform an analysis of TI dependence of signal intensity, based on the series of the spatial domain MR image data;

and(d) store and/or display a result of the analysis.

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Abstract

Elicited MRI signals are processed into MR image data in conjunction (a) with use of an initial spatially-selective RF tag pulse (tag-on) and (b) without use of an initial spatially-selective NMR RF tag pulse (tag-off) in respectively corresponding data acquisition subsequences. Multi-dimensional tag-on and tag-off data acquisition subsequences are used for each of plural time-to-inversion (TI) intervals without using an injected contrast agent. Acquired image data sets are subtracted for each TI interval to produce difference values as a function of time representing blood perfusion for the ROI that differentiates between normal, ischemic and infarct tissues.

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18 Claims

1. A magnetic resonance imaging (MRI) system comprising:
- an MRI gantry having static and gradient magnet assemblies and at least one radio frequency (RF) coil defining an image volume;
  
  MRI control circuits connected to control components within said MRI gantry and configured to effect MRI data acquisition sequences of RF and gradient magnetic pulses which elicit MRI signals to acquire and process said elicited MRI signals into MR image data;
  
  said MRI control circuits being configured to(a) acquire multi-dimensional MR k-space datausing multiple data acquisition subsequences for each of multiple time to inversion (TI) intervals without using an injected contrast agent;
  
  (b) reconstruct said acquired k-space data into a series of spatial domain MR image data each having different TI intervals;
  
  (c) perform an analysis of TI dependence of signal intensity, based on the series of the spatial domain MR image data;
  
  and(d) store and/or display a result of the analysis.
- View Dependent Claims (2, 3, 4, 5, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18)
- - 2. An MRI system as in claim 1, wherein said MRI control circuits are configured to display image data as the result of the analysis for a region of interest (ROI) at each of the multiple TI intervals, the image data defining a plot of relative blood flow as a function of time.
  - 3. An MRI system as in claim 2, wherein said MRI control circuits are configured to acquire said peak flow time and/or relative peak MR signal magnitude values for each of plural myocardium ROIs.
  - 4. An MRI system as in claim 3, wherein said MRI control circuits are configured to display superimposed plots of relative blood flow as a function of time for said plural ROIs.
  - 5. An MRI system as in claim 3, wherein at least one of said ROIs represents a segment of myocardium assigned to one of plural predetermined segments of a Bull'"'"'s Eye display of myocardium.
  - 7. An MRI system as in claim 1, wherein said MRI control circuits are configured to acquire and process said elicited MRI signals into the MR image data in conjunction (a) with use of an initial spatially selective nuclear magnetic resonance (NMR) RF tag pulse (tag-on) in a data acquisition subsequence and (b) without use of an initial spatially selective NMR RF tag pulse (tag-off) in a data acquisition subsequence;
    - said MRI control circuits being configured to(a) acquire the multi-dimensional MR k-space data using said tag-on and tag-off data acquisition subsequences;
      
      (b) reconstruct said acquired k-space data into series of spatial domain tag-on and tag-off MR image data each having different TI intervals; and
      
      (c) subtract said acquired tag-off and tag-on MR image data for each of plural TI intervals to produce difference image data.
  - 8. An MRI system as in claim 1, wherein said MRI control circuits are configured to perform said analysis of TI dependence of signal magnitude for any region of interest (ROI).
  - 9. An MRI system as in claim 1, wherein said MRI control circuits are configured to perform said analysis of TI dependence of signal magnitude for a ROI chosen by an operator.
  - 10. An MRI system as in claim 1, wherein said MRI control circuits are configured to display a curve showing TI dependence of the signal intensity as the result of the analysis.
  - 11. An MRI system as in claim 1, wherein said MRI control circuits are configured to perform said analysis of TI dependence of signal magnitude and differentiates between states of any ROI based on peak flow times and/or relative peak MR signal magnitude values calculated from the series of the MR image data.
  - 12. An MRI system as in claim 11, wherein said MRI control circuits are configured to differentiate between normal, ischemic, and infarct tissues.
  - 13. An MRI system as in claim 1, wherein said MRI control circuits are configured to change temporal resolution of the TI intervals.
  - 14. An MRI system as in claim 7, wherein values of said difference data as a function of time produce peak flow time and/or relative peak MR signal magnitude data, or lack thereof, which also differentiates revascularized infarct tissue from normal, ischemic and infarct tissues, and wherein said MRI control circuits are configured to store and/or display image data of the ROI having values which are different for revascularized, normal, ischemic and infarct tissue.
  - 15. An MRI system as in claim 7, wherein said tag-on data acquisition subsequences are effected alternately with said tag-off data acquisition sequences.
  - 16. An MRI system as in claim 11, wherein said peak flow time for normal tissue has an earlier occurring peak flow time as compared to the peak flow time for ischemic tissue, and wherein said MRI control circuits are configured to distinguish between normal and ischemic tissue based on this temporal difference.
  - 17. An MRI system as in claim 16, wherein said peak flow time for revascularized tissue has an earlier occurring peak flow time as compared to the peak flow time for normal tissue and/or ischemic tissue, and wherein said MRI control circuits are configured to identify revascularized tissue based on this temporal difference.
  - 18. An MRI system as in claim 11, wherein said relative peak MR signal magnitude value for normal tissue has a relatively higher peak flow value as compared to the peak MR flow value for ischemic tissue, and wherein said MRI control circuits are configured to distinguish between normal and ischemic tissue based on this difference in relative signal magnitude.

6. A magnetic resonance imaging (MRI) method comprising:
- (a) acquiring multi-dimensional MR k-space data using multiple data acquisition subsequences for each of multiple time to inversion (TI) intervals without using an injected contrast agent;
  
  (b) reconstructing said acquired k-space data into a series of spatial domain MR image data;
  
  (c) performing an analysis of TI dependence of signal intensity based on the series of the MR image data; and
  
  (d) storing and/or displaying a result of the analysis.

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Current Assignee
Toshiba Medical Systems Corporation (Canon Inc.)
Original Assignee
Toshiba Medical Systems Corporation (Canon Inc.), Kabushiki Kaisha Toshiba (Toshiba Corporation)
Inventors
MIYAZAKI, MITSUE, Zhou, Xiangzhi, Hoshino, Tsutomu

Granted Patent

US 9,585,575 B2
Time in Patent Office

Days
Field of Search
US Class Current

1/1
CPC Class Codes

A61B 2576/023   for the heart

A61B 5/0263   using NMR

A61B 5/055   involving electronic [EMR] ...

A61B 5/7289   Retrospective gating, i.e. ...

G01R 33/56366   Perfusion imaging

G06T 2207/30048   Heart; Cardiac

G06T 2207/30104   Vascular flow; Blood flow; ...

G06T 7/0016   involving temporal comparison

NON-CONTRAST MRI WITH DIFFERENTIATION OF ISCHEMIC, INFARCT AND NORMAL TISSUE

First Claim

2 Assignments

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Abstract

5 Citations

18 Claims

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NON-CONTRAST MRI WITH DIFFERENTIATION OF ISCHEMIC, INFARCT AND NORMAL TISSUE

First Claim

2 Assignments

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0 Petitions

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Accused Products

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Abstract

5 Citations

18 Claims

Specification

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Solutions

Use Cases

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