JP2006223449A - Cross section display device and its program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To facilitate the grasping of a position of the cross section of a double-oblique image. <P>SOLUTION: This cross section display device generates and displays a cross section image formed by cutting a subject at a predetermined cross section using three-dimensional voxel data which indicate the internal structure of the subject and changes the direction of the cross section, however, when the cross section image becomes the double-oblique image, rotates the cross section to return the image into a single-oblique image and displays it. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a cross-section display device that displays a cross-section of voxel data representing a spatial distribution of an object as a three-dimensional image, and a program therefor.

  In recent years, it has become possible to obtain cross-sectional image data that accurately represents the anatomical structure of a human body using a CT apparatus or the like, and reconstruct a three-dimensional stereoscopic image using a plurality of cross-sectional image data taken at different cross-sectional positions. Things have been done.

  In general, the three-dimensional display method for medical images is handled as a three-dimensional array of voxels having pixel values corresponding to the structure of the subject, and the main display method is to use an arbitrary three-dimensional array of voxels using cross-sectional transformation (MPR). Some display the cross section.

  When making a diagnosis using image data captured by a CT apparatus or the like, the diagnosis is performed by observing a cross-sectional image created using the MPR process. In many cases, an Axial image, a Coronal image, a Sagittal image, and the like appearing on a plane parallel to the plane and two planes orthogonal to the plane are created. However, when making a diagnosis, there is a request to observe an arbitrary cross-sectional image called an oblique image, and when a shadow that looks like a tumor is found, the inclination of the cross-section is changed using a mouse or the like in the vicinity. Oblique images are observed.

  Oblique images are created according to the operation of changing the inclination of the cross-section using a mouse, etc., but it is possible to grasp the oblique image that appears in the cross-section in which the cross-section is tilted during repeated operations. It may disappear. Therefore, conventionally, a dice display is performed so that a part of the display screen corresponds to the entire coordinate axis and the direction of the cross section, or a split surface display is performed by a method proposed in the cited document 1. Thus, it is possible to recognize which cross-sectional image the displayed oblique image is.

Alternatively, the MPR image and the three-dimensional image can be set and the spatial position can be easily grasped, so that the MPR image of the three orthogonal planes and the voxel intersecting the three orthogonal planes are displayed, and the MPR image of the three orthogonal planes is displayed. In a space having the same coordinate system as that of the image three-dimensional voxel, a method has been proposed in which a map of a corresponding position is displayed and an MPR image is recognized intuitively (for example, cited reference 2).
JP-A-1-98084 JP 2001-101450 A

  However, even when using the methods described in the above cited references 1 and 2, it is possible to grasp which cross section was observed while repeatedly performing various operations and changing the direction of the cross section of the oblique image. It may disappear. In particular, in the case of a double oblique image, it often happens that it becomes impossible to know which cross-sectional image of the subject is being observed.

  Therefore, an object of the present invention is to provide a display device, a display method, and a program for easily grasping a tomographic position of a double oblique image.

A cross-sectional display device of the present invention is a cross-sectional image display means for generating a cross-sectional image obtained by cutting the subject at a predetermined cross-section using three-dimensional voxel data representing the internal structure of the subject and displaying the cross-sectional image on a display unit.
A cross-sectional direction input means for inputting a cross-sectional direction of the cross-sectional image to be displayed;
An instruction input means for inputting an instruction to return the cross-sectional image displayed on the display unit from a double oblique image to a single oblique image;
Cross-sectional direction acquisition means for acquiring the cross-sectional direction of the cross-sectional image displayed on the display unit;
When an instruction to return from a double oblique image to a single oblique image is input by the instruction input unit, the cross-sectional direction acquisition unit acquires the cross-sectional direction of the cross-sectional image displayed by the display unit, and the direction is determined to be a double oblique image. When indicating that the image is an image, the image is rotated around a predetermined point on the cross section to obtain a cross section to be a single oblique image, and the single oblique image of the cross section is generated and displayed on the cross sectional image display means. And a single oblique image display means.

Further, the program of the present invention provides a computer,
Cross-sectional image display means for generating a cross-sectional image obtained by cutting the subject at a predetermined cross-section using three-dimensional voxel data representing the internal structure of the subject and displaying the cross-sectional image on a display unit;
A cross-sectional direction input means for inputting a cross-sectional direction of the cross-sectional image to be displayed;
An instruction input means for inputting an instruction to return the cross-sectional image displayed on the display unit from a double oblique image to a single oblique image;
Cross-sectional direction acquisition means for acquiring the cross-sectional direction of the cross-sectional image displayed on the display unit;
When an instruction to return from a double oblique image to a single oblique image is input by the instruction input unit, the cross-sectional direction acquisition unit acquires the direction of the cross-section of the cross-sectional image displayed by the display unit, and the direction is the double oblique. When indicating that the image is an image, the image is rotated around a predetermined point on the cross section to obtain a cross section to be a single oblique image, and the single oblique image of the cross section is generated and displayed on the cross sectional image display means. It functions as a single oblique image display means.

  “Section image display means” displays a section of a subject in a desired direction, has a function of converting and displaying a section such as MPR (Multi-Planner Reconstruction), and is perpendicular to the center axis of the subject. Some display a coronal section (a section along the central axis). In addition, this may have an MPVR function.

  Further, it is desirable that the cross section to be the single oblique image is a cross section having the smallest rotation angle from the cross section of the double oblique image.

  According to the present invention, when observing while gradually changing the cross-sectional position of the tomographic image, when the double oblique image is obtained, the cross sectional image displayed is changed to the single oblique image so that the displayed cross sectional image becomes the subject. It becomes easy to grasp which position is.

  Further, when returning to a single oblique image, it becomes easier to understand which position of the subject is observed by generating a single oblique image having a cross section with the smallest rotation angle from the cross section of the double oblique image.

  Hereinafter, a cross-sectional display device of the present invention will be described in detail with reference to the drawings. As shown in FIG. 1, the cross-sectional display device 1 of the present invention generates an image obtained by cutting the subject in a predetermined cross section using three-dimensional voxel data A representing the spatial distribution of the internal structure of the object, and displays the display unit. 11, a cross-sectional image display unit 10 to display on the display unit 11, a cross-sectional direction input unit 20 to input a cross-sectional direction of the cross-sectional image displayed on the display unit 11, and an instruction to return the displayed cross-sectional image from a double oblique image to a single oblique image The instruction input means 30 for inputting the cross section, the cross section direction acquisition means 40 for acquiring the direction of the cross section of the cross section image displayed on the display unit 11 when the instruction to return to the single oblique image is input, and the cross section direction acquisition means 40 When showing that the acquired cross-sectional direction is a double oblique image, obtain a cross-section that becomes a single oblique image by rotating around a predetermined point on the cross-section, The surface image display means 10 and a single oblique image display unit 50 for display by generating a single oblique image.

  As shown in FIG. 2, the three-dimensional voxel data A is volume data composed of three-dimensionally arranged pixels obtained by photographing a subject with a CT apparatus, an MRI apparatus, an ultrasonic diagnostic apparatus (echo) or the like. is there.

  The cross-sectional image display means 10 uses an MPR (Multi-Planner Reconstruction) process or the like, an axial image that appears on the XY plane that appears when the three-dimensional voxel data A is cut out at an arbitrary cross-section S, and a coronal that appears on the XZ plane. An image, a sagittal image appearing on the YZ plane, and an oblique image appearing on an oblique cross section are created and displayed. The relationship between the subject and the coordinate axes is as shown in FIG.

  The section direction input means 20 inputs the direction of the section S of the image displayed on the display unit 11 such as a display device. For example, as shown in FIG. 4, the operator designates the center point Pc using a pointing device such as a mouse, and the direction of the arrow of the cross section S about the center point Pc while viewing the image displayed on the display device. To determine the direction of the cross section. Hereinafter, the display unit 11 will be described as a display device.

  The instruction input means 30 inputs an instruction for returning the direction of the cross section S displayed on the display device 11 from the double oblique image to the single oblique image.

  Hereinafter, the operation of the cross-sectional display device 1 in the present embodiment will be described.

  First, when diagnosis is performed using an image obtained by CT imaging, an axial image, coronal image, and sagittal image in which the position of the cross section of the subject can be easily grasped are generated by the cross-sectional image display means 10, and FIG. An image as shown in a) is displayed on the display device 11. When an operator such as a doctor observes the displayed image and finds a shadow that seems to be a lesion, the center point Pc for rotating the section on the section is determined by the section direction input means 20 in order to confirm the size and shape of the lesion. The cross section is rotated by tilting the cross section around the center point Pc, and an oblique image that appears on the cross section is generated by the cross section image display means 10 and displayed on the display device 11. The oblique image in the upper right of FIG. 5A is an oblique image. This oblique image is an image that appears on a cross section in which the cross section of the coronal image (or sagittal image) is inclined in the direction of the straight line L on the XY plane (axial image). (See FIG. 5B).

  In this manner, a double oblique image may be obtained while gradually changing the direction of the cross section while viewing the image displayed on the display device 11. For example, as shown in FIG. 6, the cross section of the double oblique image intersects the XY plane (axial image) at a straight line L1, further intersects the XZ plane (coronal image) at a straight line L2, and straight lines from the YZ plane (sagittal image). Although it is a cross section intersecting at L3, it is difficult to grasp at which position and in which direction the subject is cut. Therefore, once the double oblique image is converted back to the single oblique image, it is easy to grasp the position of the subject.

  Therefore, when the image displayed on the display device 11 is a double oblique image, for example, the operator “returns to single oblique” displayed on the display device 11 using a pointing device such as a keyboard or a mouse. An instruction is input by the instruction input means 30 by pressing a button or the like (not shown).

  When an instruction is input to return to the single oblique image, the cross-sectional direction acquisition unit 30 obtains the direction of the cross-section currently displayed on the display device 11. The direction of the cross section can be expressed using the normal vector N of the cross section. Further, the normal vector N = (Nx, Ny, Nz) is obtained from the outer product of two vectors v1 = (X1, Y1, Z1) and v2 = (X2, Y2, Z2) on the cross section by the following formula (1 ).

N = (Nx, Ny, Nz) = v1 × v2
= (Y1, Z2-Z1, Y2, Z1, X2-X1, Z2, X1, Y2-Y1, X2) (1)
Specifically, for example, as shown in FIG. 6, when the XY plane and the cross section intersect with a straight line L1, and the XZ plane and the cross section intersect with a straight line L2, a vector v1 representing the directions of the intersecting straight lines L1 and L2 = (L1 _X , L1 _Y , 0), v2 = (L2 _X , 0, L2 _Z ), the normal direction N of the cross section is as shown in Expression (2).

N = (Nx, Ny, Nz) = (L1 _Y · L2 _Z , L1 _X · L2 _Z , L1 _Y · L2 _X ) (2)
In the cross section of the double oblique image, all the components of the normal vector N have values other than 0. However, in the cross section of the single oblique image, one of the components of the normal vector N is 0. Further, when the component of the normal vector N has a value only for the Z component and the X component and the Y component are 0, it becomes an axial image that appears on the XY cross section, and only the Y component has a value, and the X component and the Z component are 0. In this case, a coronal image appears on the XZ cross section, and only the X component has a value. When the Y component and the Z component are 0, a sagittal image appears on the YZ cross section.

Therefore, the single oblique image display means 50 obtains the normal vector N of the displayed cross section by the cross section direction acquisition means 40, and when all the components of the normal vector N have values other than 0, they are currently displayed. If the cross-sectional image is a double oblique image, and if it is a double oblique image, a vector obtained by setting one of the components Nx, Ny, and Nz of the normal vector N to 0 is a single oblique image. Obtained as the normal direction of the cross section of In this case, there are three possible directions for the single oblique image. However, when changing from a double oblique section to a single oblique section, it is not preferable that the observed section changes significantly. A vector in which the component having the smallest absolute value of the components Nx, Ny, and Nz is set to 0 is defined as a single oblique direction. The single oblique section is a section rotated about the center point Pc used when the section is rotated by the section direction input means 20. Specifically, for example, when the normal vector N _dou of the double oblique section is N _dou = (0.1, 0.5, 0.86), the normal vector N _sin when returning to the single oblique section is N _sin = (0, 0.5 , 0.86).

  If the position vector of a point existing on the single oblique section at this time is Q, the single oblique section can be expressed as the following equation (3).

(Q-Pc) · N _sin = 0 (3)
Nx _sin / X + Ny _sin / y + Nz _sin / z- (Nx _sin / Pcx + Ny _sin / Pcy + Nz _sin / Pcz) = 0
Where Q = (x, y, z)
Pc = (Pcx, Pcy, Pcz): vector of the position of the center point N _sin = (Nx _sin , Ny _sin , Nz _sin ): normal vector of single oblique section The single oblique image display means 50 is represented by the above formula (3) A single oblique image appearing on the cross-section represented by the above is generated using the cross-sectional image display means 10 and displayed on the display device 11.

  In the above description, when changing from a double oblique section to a single oblique section, the center point Pc set when the section is rotated by the section direction input means 20 is rotated around the center point Pc, and the double oblique section is returned to the noodle oblique section. However, when an instruction is input by the instruction input unit 30 to change from a sibble oblique section to a noodle oblique section, a center point to rotate the section may be set.

  As described above in detail, when the displayed image is a double oblique image, when an instruction is given to return to the single oblique image, the cross section is rotated in the direction in which the change from the double oblique image is the smallest and the single oblique image is obtained. By displaying the image, the position of the oblique cross-section being displayed can be easily grasped.

Schematic configuration diagram of tomographic imaging device Diagram for explaining volume data A diagram for explaining the relationship between a subject and coordinate axes Diagram for explaining rotation of cross section Diagram for explaining the relationship between an axial image, coronal image, sagittal image and single oblique image Diagram for explaining the relationship between axial, coronal, sagittal, and double oblique images

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Section display apparatus 10 Section image display means 20 Section direction input means 30 Instruction input means 40 Section direction acquisition means 50 Single oblique image display means

Claims (3)

Cross-sectional image display means for generating a cross-sectional image obtained by cutting the subject at a predetermined cross-section using three-dimensional voxel data representing the internal structure of the subject and displaying the cross-sectional image on a display unit;
Cross-sectional direction input means for inputting a cross-sectional direction of the cross-sectional image to be displayed;
An instruction input means for inputting an instruction to return the cross-sectional image displayed on the display unit from a double oblique image to a single oblique image;
Cross-sectional direction acquisition means for acquiring the cross-sectional direction of the cross-sectional image displayed on the display unit;
When an instruction to return from a double oblique image to a single oblique image is input by the instruction input unit, the cross-sectional direction acquisition unit acquires the cross-sectional direction of the cross-sectional image displayed by the display unit, and the direction is determined to be a double oblique image. When indicating that the image is an image, the image is rotated around a predetermined point on the cross section to obtain a cross section that becomes a single oblique image, and the single oblique image of the cross section is generated and displayed on the cross sectional image display means. A cross-sectional display device comprising single oblique image display means.   2. The cross-sectional display device according to claim 1, wherein a cross section of the single oblique image returned from the double oblique image is a cross section having the smallest rotation angle from the cross section of the double oblique image. Computer
Cross-sectional image display means for generating a cross-sectional image obtained by cutting the subject at a predetermined cross-section using three-dimensional voxel data representing the internal structure of the subject and displaying the cross-sectional image on a display unit;
A cross-sectional direction input means for inputting a cross-sectional direction of the cross-sectional image to be displayed;
An instruction input means for inputting an instruction to return the cross-sectional image displayed on the display unit from a double oblique image to a single oblique image;
Cross-sectional direction acquisition means for acquiring the cross-sectional direction of the cross-sectional image displayed on the display unit;
When an instruction to return from a double oblique image to a single oblique image is input by the instruction input unit, the cross-sectional direction acquisition unit acquires the direction of the cross-section of the cross-sectional image displayed by the display unit, and the direction is the double oblique. When indicating that the image is an image, the image is rotated around a predetermined point on the cross section to obtain a cross section to be a single oblique image, and the single oblique image of the cross section is generated and displayed on the cross sectional image display means. A program that functions as a single oblique image display means.