JPH0998961A - Method of image display - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method of image display in order to analyse cerebral functions. SOLUTION: A main image 100, which is a triple display of a chronological function image, a reference image and a map image, is displayed on a unified display 999 together at once with a signal change graph 200 concerning the main image, a concerned region image 300 which is an extended display of a concerned region 120, a signal change graph 400 concerning the concerned region, an image of color bars 500 to classify displayed colors, and an information window 600 to output relevant information. Images of plural concerned regions can be displayed, too. By such method, analysis and diagnosis of cerebral function can be carried out after a data analysis of chronological image, which is obtained by an inspection of cerebral function, within a short period of time.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a technical field relating to an image display method of time series images acquired by an MRI apparatus, angiography (MR angiography) using nuclear magnetic resonance, positron CT and the like. More specifically, it belongs to the technical field of an image display method capable of observing detailed information on the activity of the brain for each pixel in a short time for the purpose of analyzing brain function.

[0002]

2. Description of the Related Art A technique for analyzing brain function using an MRI apparatus has been developed. When measuring the activation area and its degree to the external stimulus of the brain, a large amount of time-series images are taken while applying a stimulus such as light and sound to the subject for a predetermined time. In the analysis of brain function, a method of designating a region of interest in a large number of time-series images and observing a signal change before and after applying a stimulus to the region is common. With respect to the stimulus given to the subject, it is necessary to examine a large number of time-series images in detail in order to observe the time and the position where the signal change occurs in the time-series images. Japanese Patent Publication No. 6-237917 discloses a method for processing time series images obtained by brain function analysis.

According to this report, the difference between the reference image and the time-series image created from the time-series image acquired by the MRI apparatus is calculated, and the time-series difference image is created. One of the created time-series difference images is displayed on the screen, a region of interest on the image is designated, changes in the signal intensity of the region of interest are graphed, and the graph is displayed on the same screen as the image data. If you enter the image number on the graph, the displayed image will be replaced. Furthermore, a moving image can be displayed by inputting a plurality of image numbers. As described above, in the conventional method of displaying a time-series image, as spatial information, an image of a specified time phase in the time-series image is displayed on the screen, and the activation pixels existing in the image are displayed. You can get information.

[0004]

In the above prior art, when a specific pixel is activated in any time phase, the region of interest can be easily determined and the analysis can be performed efficiently. When only the pixels that are activated are designated as the region of interest, it is necessary to designate and display the images of all the time phases one by one, which causes a problem that the analysis cannot be performed efficiently.
Furthermore, recently, a large number of time-series images are taken with the improvement of the performance of the apparatus, and it takes a long time to analyze a complicated time-series image by the conventional display method. Further, when actually analyzing the brain function, it is advantageous to observe the signal change for each pixel by trial and error when determining the activated pixel. However, the conventional display method has a problem that only the entire time-series image or the signal change of the designated region of interest can be displayed.

It is an object of the present invention to provide an image display method capable of analyzing time series images taken by using an MRI apparatus or the like in a short time.

[0006]

A feature of the present invention is that a main image is created by superimposing processing using a time-series functional image created by subjecting a time-series image to specific processing and a reference image. Creating a region of interest image by designating a region of interest based on the main image, designating the main image or pixels of the region of interest image, creating a signal change graph of the same, and displaying it on the same screen as the main image In point. Information of (1) pixels activated in the image of the designated time phase and (2) pixels activated in the image other than the designated time phase are displayed in the image created by the superposition processing. The state of whether or not (1) and (2) are calculation targets of the signal change graph is also displayed at the same time. Thereby, the time series images can be analyzed in a short time.

[0007]

BEST MODE FOR CARRYING OUT THE INVENTION According to the image display method of the present invention, a time-series image is obtained by repeatedly shooting the same position of an object to be imaged, particularly the brain part, and the time-series image is subjected to predetermined processing, and the processing result is set to pixel In the image display method when analyzing the signal change of the imaging target, using the time-series functional image with the value of and the reference image captured at the same position as the time-series functional image, it was extracted from the time-series functional image. A composite image (hereinafter referred to as the main image) created by displaying various kinds of information as an image or a graph on the same screen, and performing a superimposing process (overwriting process) on the time-series functional image and the reference image, By displaying the signal change graph (hereinafter referred to as the main graph) obtained from the time-series functional image on the same screen and specifying the region of interest in the main image, an image related to the region of interest of the main image (hereinafter referred to as the interest Area image ) And signal change graph of a region of interest (hereinafter, to display a) that area of interest graph in the main image and the same screen.

In the superimposing process, the time-series functional image is enlarged or reduced to match the image size of the time-series functional image with the image size of the reference image. The ROI image is an image in which one or more pixels on the main image are designated by using a mouse device and the ROI of the main image is enlarged and displayed. For the region of interest, the coordinate values of one or more pixels on the main image may be numerically designated using a keyboard device. By designating the region of interest, the boundary line indicating the region of interest is overwritten on the main image. The main image and the region-of-interest image are subjected to predetermined overlay processing using an image (hereinafter, referred to as a map image) that stores attributes of each pixel of the time-series functional image, a time-series functional image, and a reference image. Created.

In the map image, by designating pixels on the main image and the region-of-interest image using a mouse device, the value of the pixel on the map image corresponding to the designated pixel is changed.
The data plotted on the main graph and the region of interest graph are created by performing a predetermined calculation process using the time-series functional image and the map image. In the main graph and the region of interest graph, the horizontal axis represents the time phase or the time corresponding to the time phase, and the vertical axis represents the signal value.

The data plotted on the main graph and the region of interest graph are time-series functional images of pixels for which a predetermined extraction condition is satisfied for each time phase and the corresponding pixel value of the map image is 1. It is created using pixel values. It is preferable to draw a marker indicating the time phase of the image of interest on the main graph. On the main graph, the time phase of the image of interest is specified by the mouse device.

The main image is an image in which the pixels of the time-series functional image are overwritten on the reference image as geometric figures. The ROI image is an image in which the ROI of the reference image is overwritten with the pixels of the ROI of the time-series functional image as a geometric figure. The display color and display shape of the geometrical figure are determined by the pixel value of the displayed pixel, the time phase, and the map image.

In the main image and the region-of-interest image, a pixel (hereinafter referred to as an activated pixel) satisfying a predetermined extraction condition in any one of the time-series functional images is overwritten on the reference image. In the main image and the region-of-interest image, the reference image is overwritten with pixels of the time-series functional image of interest, which satisfy the predetermined extraction conditions (hereinafter referred to as the time-of-interest activation pixels).

If the pixels of the time-series functional image simultaneously satisfy the conditions of the activation pixel and the time-of-interest activation pixel of interest, they are overwritten on the reference image as the time-of-interest activation pixel of interest, and the activation pixel becomes white. Or, it is represented by a black geometrical figure. The time-phase activated pixel of interest is represented by a geometric figure having a color corresponding to the pixel value. An activation pixel or a time-phase activation pixel of interest is a geometric figure whose interior is filled when the pixel value of the map image corresponding to the pixel is 1, and is a geometric figure whose interior is filled when the pixel value is 0. It is represented by a figure.

The displayed image is a magnetic resonance imaging apparatus (MRI).
Device), an image taken by angiography (MR angiography) using nuclear magnetic resonance signals, an image taken by positron CT,
An image reconstructed using measurement data obtained from a biological optical measurement device that uses infrared light, an image reconstructed using measurement data obtained from a biomagnetic measurement device of the brain, etc. Is applied to the processing and display methods of images obtained by these devices that reflect the activity of the brain.

Embodiments of the present invention will be described in detail below with reference to the drawings.

In the following description, an embodiment in which the present invention is applied to an image acquired from an MRI (Nuclear Magnetic Resonance Imaging) apparatus or an image obtained by subjecting the acquired image to predetermined processing will be mainly described. The application target of the present invention is MR
It goes without saying that it is not limited to the I device. First, FIG. 1 shows a display example of an image according to the present invention. In the present invention, the main image 100 created by using the superposition processing 40 described later and the signal change graph 2 for the main image
00, a region of interest image 300 created by enlarging the region of interest frame 120 of the main image 100, a signal change graph 400 regarding the region of interest, a color bar 500 indicating the correspondence between display colors and pixel values, and various information. The information window 600 for output is displayed on the same screen 999. In the present invention, a plurality of regions of interest can be set.

Next, the superposition processing which is one of the features of the present invention will be described with reference to FIG. The superposition processing is performed by the time-series functional image 10, the reference image 20, and the map image 30.
Need 3 images. The respective images will be described below. The time-series functional image 10 is obtained by repeatedly photographing the same position of the subject and performing threshold processing on the acquired time-series image 50.
It is a time-series image in which a pre-processing 60 such as t-test is performed and the processing result is a pixel value. This preprocessing 60 is performed in order to extract the activation area. The reference image 20 is a morphological image obtained by photographing the same position (region) as the time-series image 50. Using this reference image 20, the activation region of the time-series functional image 10 is identified. Time-series functional image 1 described above
0 and the reference image 20 are images obtained from the MRI apparatus or images obtained by subjecting the obtained images to predetermined processing.

On the other hand, the map image 30 is an image created when the time-series functional image 10 is displayed. The map image 30 has the same size as the image size of the time-series functional image 10. Each pixel value of the map image 30 indicates whether or not the signal change of the pixel of the corresponding time-series functional image 10 is plotted in a signal change graph described later. The pixel value of the map image 30 is changed by moving the mouse pointer to the pixel displayed on the main image 100 or the region of interest image 300 and clicking. At this time, when the value of the designated pixel is 1, it is changed to 0, and when the value is 0, it is changed to 1. Further, the main image 100 and the ROI image 300 are rewritten according to the change.

Next, the superposition processing 40 will be described. First, the enlargement ratio is determined to match the image size of the reference image 20 and the image size of the time-series functional image 10. In addition, the time-series functional image 1 is specified by the specifying method described later.
The target image of 0 is decided. In the example shown in FIG. 2, the image of interest is the image 13 of the time phase 3. Next, the time-series functional image 10 is overwritten on the reference image 20 in consideration of the enlargement ratio.

Next, using the map image 30, the display method is determined as follows. Images 11, 12 of each phase
, 16 pixel values of coordinates (x, y) are respectively P11, P
12, ..., P16, especially the coordinates (x, y) of the image of interest
Let the pixel value of P0 be P0. Further, the pixel value of the coordinates (x, y) of the map image 30 is Pmap. Pixel value P11,
When there is a pixel satisfying the activation condition in P12, ..., P16, the reference image 20 is overwritten with a black triangle. In particular, when the pixel value P0 satisfies the activation condition, a quadrangle with a color corresponding to the pixel value P0 is displayed in the reference image 20.
To overwrite. At this time, when Pmap is 1, the display shape is filled, and when Pmap is 0, the display shape is not filled. The following process is performed on all the pixels of the time-series functional image 10. The color corresponding to the pixel value is obtained from the correspondence between the pixel value indicated by the color bar 500 and the display color. Further, in this example, the display shape is a triangle or a quadrangle, but another shape may be used.

The main image 100 shown in FIG. 4 is an example of a composite image created by using the superposition processing 40. In the main image 100, the activated pixels 112, 113, 114, 11
Reference numeral 5 denotes a pixel of the image of the time phase of interest, and the activation pixel 11
Reference numerals 1 and 116 denote pixels of an image other than the time phase of interest. The activated pixels 111, 112, and 115 are images set to 1 in the map image, and the main graph 200 to be described later.
Indicates that the pixel is a calculation target pixel.

Next, the main graph 200 displaying the signal change of the time-series functional image 10 will be described with reference to FIG. The main graph 200 is composed of a horizontal axis 202 indicating a time phase, a vertical axis 203 indicating a signal intensity, plot data 201 indicating a signal change of the time-series functional image 10, and a marker 204 indicating a time phase of a target image. ing. Plot data 201
Is a plot of values obtained by arithmetically averaging the pixel values of the activated pixels 111, 112, and 115 that are the calculation targets of the main graph of the main image 100. Other than this, the plot data 201 may be created for each time phase using the number of activated pixels, simple addition of pixel values of activated pixels, or the like. The marker 204 indicates the time phase of the attention image displayed on the main image 100. When the time phase is specified on the graph using the input device, the marker 204 moves to the specified time phase. In the example of FIG. 3, when the position of the time phase 2 is specified using the mouse device, the marker 204 moves from the position of the time phase 3 to the position of the time phase 2. Due to the movement of the marker 204, the time phase of the target image becomes 2, and accordingly the main image 1
00, the region of interest image 300 is rewritten.

Next, the region of interest will be described with reference to FIG.
A plurality of regions of interest can be set on the main image 100. For example, as shown in FIG. 4, when two points of the main image 100 are designated by using a mouse device, a rectangular region of interest can be set with one point as the upper left point and the other as the lower right point. When one region of interest is set, a boundary line indicating the region of interest is drawn on the main image 100 with a solid line, and the region of interest image 300 and the signal change graph 400 regarding the region of interest are used as the main image 100 as a composite image of the region of interest. Display on the same screen. An image obtained by enlarging the region of interest of the main image 100 is displayed as the region of interest image 300. Taking FIG. 4 and FIG. 5 as an example, the ROI frame 120 and the ROI image 300 show the same region.

Next, the ROI graph 400 will be described with reference to FIG. The ROI graph 400 includes a horizontal axis 402 indicating a time phase, a vertical axis 403 indicating signal strength, and plot data 401. The plot data 401 is calculated by the same processing as the plot data 201 of the main graph. The activation pixel 112 filled in with black is the target of the graph calculation, and the pixel value of each activation phase of the activation pixel 112 is plotted in the ROI graph 400.

As described above, in the embodiment, the images of the temporal phase of the time series image 50 and the time series functional image 10 are described in two dimensions, but the image display method of the present invention can be processed in three dimensions. Also, although the description has been made mainly on the time-series image obtained from the brain function measurement, the present image display method can be applied to the time-series image for which functional information other than the brain function measurement is obtained.

FIG. 6 is a schematic configuration diagram of a magnetic resonance apparatus to which the method of the present invention is applied. In FIG. 6, 621 is a magnet that generates a static magnetic field H ₀ , 622 is a measurement target, 623 is a coil for generating a high-frequency magnetic field and detecting a magnetic resonance signal generated from the measurement target 622, and 624, 625, and 626 are x. It is a gradient magnetic field generation coil that generates a gradient magnetic field in the axial direction, the y-axis direction, and the z-axis direction. 627, 62
Reference numerals 8 and 629 denote the gradient magnetic field generating coils 624 and 62, respectively.
5, a gradient magnetic field driving device for supplying a current to 626.
The gradient magnetic field generating coil and the gradient magnetic field driving device are collectively referred to as a gradient magnetic field system. Reference numeral 630 is a calculator for calculating the measured data, and 631 is a display for displaying the calculation result of the calculator 630.

Next, an outline of the operation of this inspection apparatus will be described.
High-frequency magnetic field H for exciting the nuclear spins of the measurement target 622
_{In the} modulator ₁ , the high frequency generated by the synthesizer 632 is waveform-shaped and power-amplified by the modulator 633, and a current is supplied to the coil 623 to generate it. Coil driving device 627, 6
The gradient magnetic field generating coils 624, 625, 626 supplied with current from 28, 629 generate a gradient magnetic field and modulate the magnetic resonance signal from the measurement target 622. This modulated signal is received by the coil 623, amplified by the amplifier 634, detected by the detector 635, AD converted, and then calculated by the computer 6.
30 is input. After the calculation, the computer 630 displays the calculation result on the display 631. It should be noted that the computer 630 controls each device so that it operates at a preprogrammed timing and intensity. Among these programs, a program that describes the high frequency magnetic field, the gradient magnetic field, the timing and intensity of signal reception, is called a pulse sequence.

[0028]

According to the present invention, the brain function can be analyzed and diagnosed in a short time.

[Brief description of drawings]

FIG. 1 is a diagram showing a display example of an image according to the present invention.

FIG. 2 is a diagram illustrating a process of superimposing images of a time-series functional image, a reference image, and a map image according to the present invention.

FIG. 3 is a diagram showing an example of a main graph displaying a signal change of a time-series functional image.

FIG. 4 is a diagram showing an example of a main image created by using the overlay processing of the present invention.

FIG. 5 is a diagram showing an example of a region-of-interest image of the present invention and a region-of-interest graph including a horizontal axis indicating a time phase and a vertical axis indicating signal intensity.

FIG. 6 is a diagram showing a configuration example of an MRI apparatus which is an example to which the present invention is applied.

[Explanation of symbols]

10 ... Time-series functional image, 11-16 ... Image of each time phase, 2
0 ... Reference image, 30 ... Map image, 40 ... Overlay processing, 50 ... Time series image, 60 ... Preprocessing, 100 ... Main image, 111-116 ... Display example of activated pixels by this method, 120 ... Region of interest Frame, 200 ... Main graph, 201 ...
Plot data, 202 ... Horizontal axis, 203 ... Vertical axis, 204
Marker, 300 ... Region of interest image, 400 ... Region of interest graph, 401 ... Plot data, 402 ... Horizontal axis, 403
... vertical axis, 500 ... color bar, 600 ... information window, 621 ... static magnetic field generating magnet, 622 ... measurement target,
623 ... High-frequency magnetic field generation and signal detection coil, 62
4, 625, 626 ... Coil for generating gradient magnetic field, 627,
628, 629 ... Coil drive device, 630 ... Calculator, 6
31 ... Display, 632 ... Synthesizer, 633 ...
Modulator, 634 ... Amplifier, 635 ... Detector, 999
…screen.

Continuation of the front page (51) Int.Cl. ⁶ Identification number Reference number within the agency FI Technical indication location G09G 5/36 520 G06F 15/70 455B (72) Inventor Yukari Onodera 1-280 Higashi Koikeku, Kokubunji, Tokyo Hitachi Central Research Laboratory (72) Inventor Kenichi Okajima 1-280 Higashi Koigokubo, Kokubunji, Tokyo Inside Hitachi Central Research Laboratory

Claims (27)

[Claims] 1. A time series image is acquired by repeatedly shooting the same position of a shooting target, and the time series image is subjected to predetermined processing,
An image display method used when analyzing a signal change from the imaging target by using a time-series functional image having a processing result as a pixel value and a reference image obtained by photographing a form at the same position as the time-series functional image. In the image display method, a plurality of pieces of information extracted from the time-series functional image are displayed on the same screen as an image or a graph. 2. A main image, which is a composite image created by subjecting the time-series functional image and the reference image to superimposing processing, and a main graph, which is a signal change graph obtained from the time-series functional image, are the same. The image display method according to claim 1, wherein the image is displayed on the screen. 3. By designating a region of interest in the main image, a region of interest image that is an image related to the region of interest of the main image and a region of interest graph that is a signal change graph of the region of interest are the same as the main image. The image display method according to claim 1, wherein the image is displayed on the screen. 4. The superimposing processing is to enlarge or reduce the time-series functional image to match the image size of the time-series functional image with the image size of the reference image. The image display method described in 2. 5. The region of interest image is an image obtained by enlarging and displaying the region of interest of the main image.
The image display method described in 1. 6. The main image and the region-of-interest image are predetermined using a map image, which is an image storing attributes of each pixel of the time-series functional image, the time-series functional image, and the reference image. The image display method according to claim 2 or 3, wherein the image display method is created by performing the superimposing processing of. 7. The data plotted on the main graph and the region of interest graph are predetermined using the time-series functional image and a map image that is an image storing attributes of each pixel of the time-series functional image. The image display method according to claim 2 or 3, wherein the image display method is created by performing the calculation process of. 8. The image display method according to claim 2, wherein the main image is an image in which the pixels of the time-series functional image are overwritten on the reference image as geometric figures. 9. The region of interest image is an image in which the region of interest of the reference image is overwritten with the pixels of the region of interest of the time-series functional image as a geometrical figure.
The image display method described in 1. 10. The display color and display shape of the geometrical figure are determined by a map image that is an image that stores the pixel value of the pixel to be displayed, the time phase, and the attribute of each pixel of the time-series functional image. The image display method according to claim 8 or 9, wherein: 11. In the main image and the region of interest image,
10. An activation pixel, which is a pixel that satisfies a predetermined extraction condition in an image of any one of the time-series functional images, is overwritten on the reference image.
The image display method described in 1. 12. In the main image and the region of interest image,
The time-domain functional image of interest of the time-series functional image is overwritten on the reference image with a time-domain active pixel of interest that is a pixel that satisfies a predetermined extraction condition. Image display method described in. 13. When the pixels of the time-series functional image simultaneously satisfy the conditions of the activation pixel and the time-of-interest activation pixel of interest, the reference image is overwritten as the time-of-interest activation pixel of interest. The image display method according to claim 8 or 9, characterized by the above-mentioned. 14. The activated pixel is represented by a white or black geometrical figure.
The image display method according to any one of 1. 15. The image display method according to claim 8, wherein the time-phase activated pixel of interest is represented by a geometric figure having a color corresponding to a pixel value. 16. The pixel value of a map image, which is an image that stores the attribute of each pixel of the time-series functional image corresponding to the pixel, is 1 when the pixel value of the activated pixel or the noted time-phase activated pixel is 1. 14. The image display according to any one of claims 8 to 13, characterized in that the interior is filled with a geometric figure, while when the pixel value is 0, the interior is represented with a filled geometric figure. Method. 17. The image according to claim 2, wherein the main graph and the region of interest graph have a horizontal axis as a time phase or a time corresponding to the time phase and a vertical axis as a signal value. Display method. 18. The data plotted on the main graph and the region-of-interest graph are the time-series functional images, satisfy a predetermined extraction condition for each time phase, and have attributes for each pixel of the time-series functional image. 18. The image display method according to claim 17, wherein the image is stored using a pixel value of a pixel having a corresponding pixel value of 1 in a map image that is an image storing the image. 19. The image display method according to claim 17, wherein a marker indicating the time phase of the image of interest is drawn on the main graph. 20. The image display method according to claim 17, wherein the time phase of the image of interest is designated by the mouse device on the main graph. 21. The image display method according to claim 3, wherein in the region of interest, one or more pixels are designated on the main image by using a mouse device. 22. The image display method according to claim 3, wherein, in the region of interest, coordinate values of one or more pixels are numerically designated on the main image by using a keyboard device. 23. The image display method according to claim 3, wherein a boundary line indicating a region of interest is overwritten on the main image by designating the region of interest. 24. In the map image, when a pixel is designated on the main image and the region of interest image using a mouse device, the value of the pixel on the map image corresponding to the designated pixel is changed. The image display method according to claim 6, wherein. 25. The time-series image display method according to claim 1, wherein the display image is an image captured by a nuclear magnetic resonance imaging apparatus (MRI apparatus). 26. The display image according to any one of claims 1 to 24, wherein the display image is an image captured by angiography (MR angiography) using nuclear magnetic resonance. Time series image display method. 27. The time-series image display method according to claim 1, wherein the display image is an image photographed by positron CT.