Method and device for the separate three-dimensional representation of arteries and veins in an examination object and device

US 8,126,236 B2
Filed: 09/11/2008
Issued: 02/28/2012
Est. Priority Date: 09/21/2007
Status: Active Grant

First Claim

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1. A method for a separate three-dimensional representation of arteries and/or veins of a vascular system in an examination object based upon a tomography x-ray device, comprising:

implementing a mask pass of the x-ray device with N projections at N angular positions about the examination object without a contrast agent;

implementing a first filler pass of the x-ray device about the examination object with M measured projections at M of the N angular positions after an injection of a contrast agent, where M<

N;

implementing a second filler pass of the x-ray device about the examination object with N−

M measured projections at N−

M of the N angular positions directly following the first filler pass;

reconstructing a composite three-dimensional volume data record from an intermediate data record, said intermediate data record being determined from the data records resulting from the mask pass, the first filler pass and the second filler pass by subtraction and combination;

calculating a reprojection data record for arteries by reprojection of the angular positions of the first filler pass from the composite three-dimensional volume data record and/or calculating a reprojection data record for veins by reprojection of the angular positions of the second filler pass from the composite three-dimensional volume data record; and

calculating a three-dimensional volume data record for arteries and/or a three-dimensional volume data record for veins by weighting the composite three-dimensional volume data record taking into account the respective measured projections and the respective calculated reprojections.

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Abstract

Method for three-dimensional representation of arteries and/or veins in an object by a tomography x-ray device is proposed. A mask pass with N projections at N angular positions without contrast agent is implemented. A first filler pass with M projections at M angular positions after injecting a contrast agent, where M<N is implemented, followed by a second filler pass with N−M projections at N−M angular positions. A composite three-dimensional volume data record is reconstructed from an intermediate data record determined from the mask pass, the first and the second filler pass. A reprojection for arteries and/or for veins is calculated by reprojection of the first filler pass and/or of the second filler pass from the composite three-dimensional volume data record. A three-dimensional volume data record for arteries and/or for veins is calculated by weighting the composite three-dimensional volume data record taking into account the respective measured and calculated projection images.

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20 Claims

1. A method for a separate three-dimensional representation of arteries and/or veins of a vascular system in an examination object based upon a tomography x-ray device, comprising:
- implementing a mask pass of the x-ray device with N projections at N angular positions about the examination object without a contrast agent;
  
  implementing a first filler pass of the x-ray device about the examination object with M measured projections at M of the N angular positions after an injection of a contrast agent, where M<
  
  N;
  
  implementing a second filler pass of the x-ray device about the examination object with N−
  
  M measured projections at N−
  
  M of the N angular positions directly following the first filler pass;
  
  reconstructing a composite three-dimensional volume data record from an intermediate data record, said intermediate data record being determined from the data records resulting from the mask pass, the first filler pass and the second filler pass by subtraction and combination;
  
  calculating a reprojection data record for arteries by reprojection of the angular positions of the first filler pass from the composite three-dimensional volume data record and/or calculating a reprojection data record for veins by reprojection of the angular positions of the second filler pass from the composite three-dimensional volume data record; and
  
  calculating a three-dimensional volume data record for arteries and/or a three-dimensional volume data record for veins by weighting the composite three-dimensional volume data record taking into account the respective measured projections and the respective calculated reprojections.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18)
- - 2. The method as claimed in claim 1, wherein M=N/2.
  - 3. The method as claimed in claim 2, wherein every second angular position of the mask pass is used during the first filler pass, the remaining angular positions of the mask pass being used during the second filler pass.
  - 4. The method as claimed in claim 2, wherein the mask pass, the first filler pass and the second filler pass are implemented in the same scan direction.
  - 5. The method as claimed in claim 1, wherein each angular position of the mask pass is used just once either during the first filler pass or during the second filler pass.
  - 6. The method as claimed in claim 5, wherein the mask pass, the first filler pass and the second filler pass are implemented in an alternating manner in different scan directions.
  - 7. The method as claimed in claim 1, wherein each angular position of the mask pass is used just once either during the first filler pass or during the second filler pass.
  - 8. The method as claimed in claim 1, wherein the intermediate data record results froma subtraction of part of the data record obtained during the mask pass, in which part the angular positions correspond to those of the first filler pass, from the data record of the first filler pass to form a first data record,a subtraction of part of the data record obtained during the mask pass, in which part the angular positions correspond to those of the second filler pass, from the data record of the second filler pass to form a second data record, anda combination of the first and second data records.
  - 9. The method as claimed in claim 8, wherein the first filler pass is started at the time of a contrast agent injection into the vessel to be examined and the second filler pass is started at the start of the venous phase.
  - 10. The method as claimed in claim 1, wherein the intermediate data record results froma combination of the data record resulting from the first filler pass and the data record resulting from the second filler pass to form a combined data record, anda subtraction of the data record resulting from the mask pass from the combined data record taking into account corresponding angular positions.
  - 11. The method as claimed in claim 10, wherein the first filler pass is started at the time of a contrast agent injection into the vessel to be examined and the second filler pass is started at the start of the venous phase.
  - 12. The method as claimed in claim 1, wherein for calculating a three-dimensional volume data record for arteries and/or a three-dimensional volume data record for veins by weighting the composite three-dimensional volume data record taking into account the respective measured projections and the respective calculated reprojections the volume data record for arteries is obtained by multiplying the composite three-dimensional data record by the backprojection of a weighted projection data record for arteries, the weighted projection data record for arteries being formed from the quotients of the individual projection images of the first filler pass with the respective projection images of the reprojection data record for arteries produced for corresponding angular positions.
  - 13. The method as claimed in claim 1, wherein for calculating a three-dimensional volume data record for arteries and/or a three-dimensional volume data record for veins by weighting the composite three-dimensional volume data record taking into account the respective measured projections and the respective calculated reprojections the volume data record for veins is obtained by multiplying the composite three-dimensional data record by the backprojection of a weighted projection data record for veins, the weighted projection data record for veins being formed from the quotients of the individual projection images of the second filler pass with the respective projection images of the reprojection data record for veins produced for corresponding angular positions.
  - 14. The method as claimed in claim 1, wherein for calculating a three-dimensional volume data record for arteries and/or a three-dimensional volume data record for veins by weighting the composite three-dimensional volume data record taking into account the respective measured projections and the respective calculated reprojections the volume data record for arteries is obtained by multiplying the composite three-dimensional data record by the backprojection of the projection images of the first filler pass and then dividing it by the backprojection of the reprojection data record for arteries.
  - 15. The method as claimed in claim 1, wherein for calculating a three-dimensional volume data record for arteries and/or a three-dimensional volume data record for veins by weighting the composite three-dimensional volume data record taking into account the respective measured projections and the respective calculated reprojections the volume data record for veins is obtained by multiplying the composite three-dimensional data record by the backprojection of the projection images of the second filler pass and then dividing it by the backprojection of the reprojection data record for veins.
  - 16. The method as claimed in claim 1, wherein the mask pass, the first filler pass and the second filler pass are implemented in the same scan direction.
  - 17. The method as claimed in claim 1, wherein the mask pass, the first filler pass and the second filler pass are implemented in an alternating manner in different scan directions.
  - 18. The method as claimed in claim 1, wherein the first filler pass is started at the time of a contrast agent injection into the vessel to be examined and the second filler pass is started at the start of the venous phase.

19. A device for a separate three-dimensional representation of arteries and/or veins of a vascular system of an examination object, comprising:
- a tomography x-ray device for;
  
  implementing a mask pass with N projections at N angular positions about the examination object without a contrast agent;
  
  implementing a first filler pass about the examination object with M measured projections at M of the N angular positions after an injection of a contrast agent, where M<
  
  N;
  
  implementing a second filler pass about the examination object with N−
  
  M measured projections at N−
  
  M of the N angular positions directly following the first filler pass; and
  
  a computer configured to perform;
  
  reconstructing a composite three-dimensional volume data record from an intermediate data record, said intermediate data record being determined from the data records resulting from the mask pass, the first filler pass and the second filler pass by subtraction and combination;
  
  calculating a reprojection data record for arteries by reprojection of the angular positions of the first filler pass from the composite three-dimensional volume data record and/or calculating a reprojection data record for veins by a reprojection of the angular positions of the second filler pass from the composite three-dimensional volume data record; and
  
  calculating a three-dimensional volume data record for arteries and/or a three-dimensional volume data record for veins by weighting the composite three-dimensional volume data record taking into account the respective measured projections and the respective calculated reprojections.
- View Dependent Claims (20)
- - 20. The device as claimed in claim 19, wherein the tomography x-ray device is a C-arm x-ray device.

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Current Assignee
Siemens Healthineers AG (Siemens AG)
Original Assignee
Siemens AG
Inventors
Härer, Wolfgang, Zellerhoff, Michael
Primary Examiner(s)
Ho, Allen C.

Application Number

US12/283,419
Publication Number

US 20090080736A1
Time in Patent Office

1,265 Days
Field of Search

382/130, 382/131, 382/154, 382260-265, 378/4, 378/8, 378/901, 378/98.12
US Class Current

382/130
CPC Class Codes

A61B 6/466   adapted to display 3D data

A61B 6/481   involving the use of contra...

A61B 6/504   for diagnosis of blood vess...

Y10S 378/901   Computer tomography program...

Method and device for the separate three-dimensional representation of arteries and veins in an examination object and device

First Claim

3 Assignments

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Abstract

Citations

20 Claims

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Method and device for the separate three-dimensional representation of arteries and veins in an examination object and device

First Claim

3 Assignments

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Abstract

Citations

20 Claims

Specification

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