JPH0619986A - Image diagnostic device - Google Patents

Abstract

PURPOSE:To enable the complicated display of the velocity states of blood or the like by color-coding the sectional image data group of internal circulating fluid in a traveling direction by each prescribed velocity range, synthesizing and displaying three-dimensional image data formed by an arithmetic operation. CONSTITUTION:The sectional image data group 101 along with the traveling direction of the blood is displayed in different brightness respectively corresponding to the velocity of blood flow. The respective sectional image data of the sectional image data group 101 are successively read, the data provided with brightness values corresponding to the ranges of flow velocity 10-20 and more than 20 are fetched to be written in respectively different semiconductor memories and the sectional image data groups 102a and 102b are obtained. Further, the data provided with the brightness value corresponding to the external wall of a blood vessel are fetched and the sectional image data group 102c is obtained. The sectional image data groups are color-coded corresponding to division and constitute three-dimensional display images 103a-103c by the arithmetic operation. Then, the three-dimensional display images are displayed respectively or synthesized to be displayed. Thus, the velocity state of the blood flow can be three-dimensionally analyzed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image diagnostic apparatus,
In particular, the present invention relates to an image diagnostic apparatus that indicates and displays the circulating fluid in the body.

[0002]

2. Description of the Related Art As an image diagnostic apparatus of this type, for example, a two-dimensional display of a blood vessel as viewed from its lateral direction is performed, and blood flowing in the blood vessel is detected, for example, at a blood flow portion at a predetermined speed or less. It is known that a red color is displayed, and a blood flow portion having a predetermined speed or higher is displayed in a dark red color.

As described above, a portion constricted by arteriosclerosis or the like can be visualized from a diagnostic image of blood flow having a flow velocity distribution divided by color.

[0004]

However, the image diagnostic apparatus constructed as described above can obtain only information such as whether the blood flow velocity is high or low at a certain portion in the length direction of the blood vessel. Therefore, there is a problem that the blood flow velocity information is so small that a sufficient diagnosis cannot be made.

The present invention has been made under such circumstances, and an object of the present invention is to display in-body circulating fluid such as blood in its velocity state even in a more complicated surface than ever before. It is to provide an image diagnostic apparatus capable of performing

[0006]

In order to achieve such an object, the present invention basically provides a predetermined range from a plurality of respective cross-sectional image data groups along the running direction of circulating fluid in the body. Dividing means for dividing the body circulation fluid divided for each speed into each cross-sectional image data group extracted, and a color-dividing means for color-dividing each cross-sectional image data divided by this dividing means, Calculation means for separately constructing three-dimensional display image data from each cross-sectional image data color-coded by the color-coding means and three-dimensional display image data separately formed by this calculation means are displayed separately or by combining. And means for doing so.

[0007]

The image diagnostic apparatus constructed as described above is
From a plurality of cross-sectional image data groups along the running direction of the body circulation fluid, the body circulation fluid divided for each speed in a predetermined range is divided into respective cross-sectional image data groups.

Therefore, of the entire liquid flow, only the liquid flow having a velocity within a predetermined range is extracted and divided. The information of each divided velocity is the velocity information in the cross section. Is also included.

The respective liquid streams are color-coded according to the divisions, whereby the liquid streams having a velocity within a predetermined range can be easily recognized by the colors.

Three-dimensional display image data is constructed from the cross-sectional image data group color-coded in this way by calculation for each cross-sectional image data, whereby the three-dimensional display of only the liquid flow portion having a velocity within a predetermined range. Image data can be obtained.

Thereafter, based on the respective three-dimensional display image data, the diagnosis is carried out by displaying them separately or by combining them on the display device.

As is clear from this, the circulating fluid in the body to be diagnosed is displayed three-dimensionally including the velocity distribution of the liquid flow in its cross section, so that the velocity state of the liquid flow is three-dimensionally displayed. Can be analyzed. Therefore, it becomes possible to display the in-vivo circulating fluid in its velocity state even on a more complicated surface than ever before.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS First, FIG. 2 is a schematic configuration diagram showing an embodiment of an ultrasonic diagnostic apparatus to which the present invention is applied.

In FIG. 1, there is an ultrasonic probe 2 which is operated by being brought into contact with a subject 1. The ultrasonic probe 2 is driven by a wave transmitter 3 to irradiate the inside of the subject 1 with ultrasonic pulse waves.

Then, the reflected wave of the ultrasonic pulse wave in the subject 1 is detected by the ultrasonic probe 2 and RF
It is adapted to be input to the amplifier 4. The output from the RF amplifier 4 is detected by the wave detector 5 and input to the video amplifier 6.

Further, the output of the video amplifier 6 is input to the CRT 8 via the scan converter 7.

These operations are performed by the control circuit 9 having a CPU.
In addition to being controlled by the CRT 8, the CRT 8 can display images processed by the image processing unit 10 in various forms.

In this embodiment, particularly, the control circuit 9 and the image arithmetic processing unit 10 create three-dimensional blood flow image information, and the two-dimensional image is obtained by viewing the three-dimensional blood flow image from a desired viewpoint. (A two-dimensional image such as this is referred to as a three-dimensional image in this specification) can be imaged, and a predetermined portion of the three-dimensional image is colored with a color that makes information meaningful.

The processing performed to obtain such an image will be described with reference to FIG. In the figure, it comprises the following four steps.

Step 1. First, a plurality of cross-sectional image data groups 101 along the blood traveling direction are prepared. This sectional image data group 101 is composed of n sheets # 1 to #n.

The sectional image data of # 1 to #n are stored in, for example, a semiconductor memory.

Each sectional image data (# 1 to #n)
Is cross-sectional image data in the blood vessel, and the blood in the outer wall of the blood vessel is displayed with different brightness depending on the blood flow velocity.

That is, it shows that the central portion has high brightness and high speed. Then, it is shown that the brightness is low and the speed is low in the peripheral portion adjacent to the outer wall.

Step 2. Each sectional image data in the sectional image data group 101 is sequentially read from # 1. The data reading in this case is, for example, horizontal reading sequentially from the upper left to the lower right of each cross-sectional image data.
Only the data having the brightness value corresponding to the range of 20 is fetched through the comparator, and the fetched data is written in the same address of different semiconductor memories. In this way, the cross-sectional image data # 1 of the cross-sectional image data group 102a is obtained.

Further, at the time of the above-mentioned reading, only the data having the brightness value corresponding to the range of the flow velocity of 20 or more is fetched through the comparator, and the fetched data is written in the same address of different semiconductor memories. In this way, the sectional image data # of the sectional image data group 102b
1 is obtained.

Further, at the time of the above-mentioned reading, only the data having the brightness value corresponding to the outer wall of the blood vessel is fetched through the comparator, and the fetched data is written in the same address of different semiconductor memories. In this way
The sectional image data # 1 of the sectional image data group 102c is obtained.

In the cross-sectional image data group 101, the reading of each cross-sectional image data from # 2 onward is similarly performed, whereby only the blood flow in the flow velocity range of 10 to 20 is displayed. , A cross-sectional image data group 102b in which only the blood flow in the range of flow velocity 20 or higher is displayed, and a cross-sectional image data group 102c in which only the outer wall of the blood vessel is displayed.

In this case, the blood flow in the cross-sectional image data 102a is displayed in, for example, light red, and the blood flow in the cross-sectional image data 102b is displayed in, for example, dark red. The blood vessels in the cross-sectional image data 102c are displayed semi-transparently in a color other than red, for example.

Step 3. A three-dimensional image is constructed by calculation from each blood flow data of each cross-sectional image data # 1 to #n of the cross-sectional image data group 102a. As a result, the three-dimensional image 1 of the blood flow having a flow speed in the range of 10 to 20 out of the total blood flow 1
03a is configured.

Similarly, a three-dimensional image is constructed by calculation from the blood flow data of each of the sectional image data # 1 to #n of the sectional image data group 102b. As a result, the three-dimensional image 1 of the blood flow in which the flow speed is in the range of 20 or more out of the total blood flow 1
03b is configured.

Further, similarly, a sectional image data group 102c
A three-dimensional image is constructed by calculation from the blood flow data of each of the sectional image data # 1 to #n. As a result, the three-dimensional image 103c of only blood vessels excluding blood is formed.

Step 4. One of the three-dimensional images 103a and 103b configured as described above is selected and the CRT is selected.
Display on the surface. In this case, by synthesizing and displaying the three-dimensional image 103c, it becomes possible to clarify the positioning of the blood flow having the flow velocity in the predetermined range with respect to the blood vessel.

Further, the three-dimensional images 103a, 1 respectively
All of 03b and 103c may be combined and displayed. In this case, the distribution of the blood flow velocity can be clearly distinguished by color coding.

The operation flow of the control circuit (CPU) 9 operating in the image processing apparatus 10 in such processing will be described with reference to FIG.

In the figure, S1. There is slice information stored in the memory #n (1 to n), and the pixel is read from the memory # 1 with n being 1.

S2. It is determined whether or not the brightness of the read pixel is within a certain range (for example, a range from 10 to 20).

S3. Pixels with brightness in the range are "1"
Information.

S4. Pixels that do not have brightness in that range
0 ”information.

S5. In the memory prepared separately,
The 1 "information is stored in the same address as before the conversion, and the" 0 "information is stored in the same address before the conversion.

S6. It is determined whether or not all the pixels have been read out, and if not yet read out, S1. Then, the same steps are repeated for the pixel to be read next.

S7. When all pixels are read, n
= N + 1, that is, the pixel of the next memory is read out.

S8. It is determined whether each slice information has been read.

S9. When each slice information is read, a three-dimensional image is constructed by calculation based on the information stored in each separate memory.

S10. When the image is displayed on the CRT, it is processed so that an appropriate color is applied.

Such an operation is performed in S2. By changing the set brightness value in, another predetermined range (for example, 2
Only blood having a flow rate of 0 or more) can be extracted.

As is clear from the embodiment described above,
According to this ultrasonic diagnostic apparatus, first, from each of a plurality of cross-sectional image data groups along the traveling direction of blood, the blood divided at each speed within a predetermined range is divided into each cross-sectional image data group. It is supposed to do.

Therefore, of the whole blood flow, only the blood flow having a velocity within a predetermined range is extracted and divided. The information of each divided velocity is the velocity information in the cross section. Is also included.

The respective bloodstreams are color-coded according to the divisions, whereby the bloodstreams having a velocity within a predetermined range can be easily recognized by the colors.

Three-dimensional display image data is constructed from the cross-sectional image data group color-coded in this way by calculation for each cross-sectional image data, whereby the three-dimensional display of only the blood flow portion having a velocity within a predetermined range. Image data can be obtained.

After that, based on the respective three-dimensional display image data, the diagnosis is performed by displaying them separately or by combining them on the display device.

As is clear from this, the blood to be diagnosed is displayed three-dimensionally including the blood flow velocity distribution in its cross section, so that the blood flow velocity state is three-dimensionally analyzed. be able to. Therefore, it becomes possible to display even more complicated surfaces than before in the speed state of blood.

In the above embodiment, the blood flow velocity distribution is
Although the description has been made on the two categories of 10 to 20 and 20 or more, it goes without saying that the categories may be further subdivided.

In the above-mentioned embodiment, blood is shown as the circulating fluid in the body, but it is needless to say that it is not limited to this and may be lymph fluid or the like.

In the above-mentioned embodiment, the ultrasonic diagnostic apparatus is shown, but the present invention is not limited to this, and N
It can also be applied to an MR apparatus or an X-ray CT apparatus.

[0055]

As is apparent from the above description,
According to the image diagnostic apparatus of the present invention, it becomes possible to display a body fluid such as blood in a speed state even in a more complicated surface than ever before.

[Brief description of drawings]

FIG. 1 is an explanatory diagram showing an example of processing steps of an image diagnostic apparatus according to the present invention.

FIG. 2 is a schematic block diagram showing an embodiment of an image diagnostic apparatus according to the present invention.

FIG. 3 is a flowchart showing an embodiment of the operation of the CPU operating in the image processing unit of the image diagnostic apparatus according to the present invention.

[Explanation of symbols]

 101 cross-sectional image data group 102 cross-sectional image data group (divided) 103 three-dimensional image

Claims (1)

[Claims] 1. A division for dividing each of a plurality of cross-sectional image data groups along the running direction of the intracorporeal circulating fluid into each cross-sectional image data group in which the intracorporeal circulating fluid divided for each speed within a predetermined range is extracted. Means, color dividing means for color-dividing the respective cross-sectional image data divided by the dividing means according to the division, and three-dimensional display image data separately from the respective cross-sectional image data color-divided by the color dividing means. An image diagnostic apparatus comprising: a computing means; and means for displaying the three-dimensional display image data separately formed by the computing means separately or by combining them.