JPS6297539A - Blood flow state displaying method in ultrasonic diagnostic apparatus - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

Detailed Description of the Invention (a) Industrial Application Field The present invention allows observation of blood flow dynamics in a living body by utilizing the Doppler effect caused by blood flow when ultrasonic pulses are radiated into the living body. The present invention relates to a method for displaying blood flow dynamics in an ultrasonic diagnostic apparatus.

(b) Prior art and its problems In general, when diagnosing blood flow dynamics inside the heart, the ultrasonic pulsed Doppler method is widely applied. In order to display blood flow dynamics in a living body in color using this ultrasonic pulsed Doppler method, conventional methods have been to display only the mutton blood flow velocity distribution on the tomographic image, or to display the average blood flow velocity on the tomographic image. There are two methods of displaying the dispersion degree and the dispersion degree in an overlapping manner. for example,
The average blood flow velocity and the degree of dispersion are displayed in a superimposed manner on a tomographic image in the following manner.

First, ultrasonic pulses are emitted into the living body at predetermined time intervals,
Tomographic data is collected from an echo signal based on the ultrasound echo reflected from the living body, a Doppler signal is extracted by phase detection of the echo signal, and the extracted Doppler signal is subjected to, for example, fast Fourier transform (FF'T). l
, and calculate its frequency spectrum. Next, the average blood flow velocity and degree of dispersion are calculated for each region within the body from this frequency smoothing. As for the average blood flow velocity, as shown in Figure 3, it corresponds to its positive/negative direction and magnitude; for example, if the blood flow is approaching, it will be red, and if it is moving away, it will be blue. In addition, a color code whose brightness changes depending on the blood flow velocity is set.

Regarding the degree of dispersion, as shown in Figure 4, a single color (green) whose brightness changes sequentially in accordance with the degree of dispersion.
Set the color code. Then, the color codes corresponding to the average blood flow velocity data and dispersion data are read out, and after converting these color codes into color signals, these color signals are mixed and output to the monitor. There is.

However, if the blood flow velocity distribution and the dispersion degree are displayed superimposed on one tomographic image as described above, it becomes difficult to understand the dispersion degree when it is desired to observe the degree of dispersion alone.

The present invention has been made in view of the above circumstances, and an object of the present invention is to enable accurate diagnosis by making it possible to clearly understand the magnitude of the degree of dispersion.

(c) Means for Solving the Problems In order to achieve the above object, the present invention is a method for displaying blood flow dynamics in an ultrasonic diagnostic apparatus, in which ultrasonic pulses are emitted into a living body, and blood flow in a living body is detected. Obtain the frequency spectrum of the Doppler signal by using the Doppler effect caused by the flow,
The method calculates the average blood flow velocity and dispersion degree from this frequency smoothing, and displays the data of the obtained average blood flow velocity and dispersion degree as a color image, and the data is displayed in a color image corresponding to the magnitude of the dispersion degree. A color code whose hue changes sequentially is set, and dispersion data based on this color code is displayed on the tomographic image or the M-mode image separately from the average blood velocity data. ing.

(D) Example The present invention will be described in detail regarding the case where the average blood flow velocity and the magnitude of the degree of dispersion are displayed on a monitor.

FIG. 1 is an explanatory diagram of a color code set according to the degree of dispersion in the method of the present invention, and FIG. 2 is an explanatory diagram of a display example of a color image of blood flow dynamics.

When displaying blood flow dynamics, first, one ultrasound pulse is emitted in the living body at predetermined time intervals, tomographic data is collected from the echo signal based on the ultrasound echo reflected from the living body, and the echo signal is A Doppler signal is extracted by phase detection, and the extracted Doppler signal is subjected to Fast Fourier Transform (FFT) to calculate its frequency spectrum. Subsequently, the average blood flow velocity and degree of dispersion are calculated for each region within the living body from this frequency spectrum. As before, as shown in Figure 3, the average blood flow velocity is mapped to its positive/negative direction and magnitude; for example, when the blood flow is approaching, it is red, and when it is moving away, it is blue. A color code is set that has a hue of , and whose brightness changes depending on the magnitude of the blood flow velocity, and this color code is stored in the color RAM.

On the other hand, regarding the degree of dispersion, as shown in FIG. 1, a color code is set in which the hue changes sequentially in accordance with the magnitude of the degree of dispersion. For example, the hue is set to change sequentially from blue, blue-green, green, yellow, and red as the degree of dispersion gradually increases. Then, this color code is stored in the color RAM.

Then, by giving the already determined average blood flow velocity data and dispersion data as addressing signals to each color RAM, color codes corresponding to the average blood flow velocity data and dispersion data are obtained from the color RAM. After reading and converting these color codes into color signals, they are output to the monitor. At this time, the display of the degree of dispersion based on the color code of FIG. 1 is displayed on the tomographic image separately from the display of the average blood flow velocity based on the color code of FIG.

In other words, as shown in Figure 2, the monitor display screen is
For example, the screen on the left side of the diagram displays the average surface velocity distribution on the tomographic image, and the screen on the right side displays the degree of dispersion on the tomographic image. For example, if we take the display of blood flow dynamics inside the heart, the average blood flow velocity distribution on the left screen will be red when the blood is approaching, and blue when the blood is moving away. The brightness is changed and displayed according to the magnitude of the flow velocity. Regarding the degree of dispersion, if the flow is laminar near the valve orifice and becomes turbulent as it approaches the apex, the screen on the right will show blue near the valve orifice (i.e. low dispersion) and red at the apex ( In other words, the degree of dispersion is large)
The hue changes sequentially from blue-green to green to yellow.

In this way, only the magnitude of the dispersion degree is displayed separately from the average blood flow velocity distribution on the tomographic image, so it is easy to understand changes in the dispersion degree at the diagnostic site by observing changes in hue. can.

Note that it is a matter of course that the hues that correspond to the direction of the average blood flow velocity are not limited to this embodiment. In addition to displaying the degree of dispersion and the average blood flow velocity distribution on the same monitor by dividing the screen as in the above embodiment, the degree of dispersion and the average blood flow velocity distribution may be displayed on each separately provided monitor. . Further, in the above embodiment, the degree of dispersion is displayed on the tomographic image, but it is also possible to display the degree of dispersion on the M-mode image.

(E) Effects As described above, according to the present invention, a color code is set whose hue changes sequentially in accordance with the degree of dispersion, and
Since the dispersion data based on this color code is displayed on the tomographic image or the M-mode image separately from the average blood velocity data, the magnitude of the dispersion can be observed independently. becomes possible. Therefore, since the degree of dispersion can be clearly grasped, excellent effects such as enabling more accurate diagnosis are exhibited.

[Brief explanation of drawings]

Figures 1 and 2 show examples of the method of the present invention. Figure 1 is an explanatory diagram of color codes set according to the degree of dispersion, and Figure 2 is a color image of blood flow dynamics. Fig. 3 is an explanatory diagram of the color code set to display the direction and magnitude of the average blood flow velocity, and Fig. 4 is an explanatory diagram of the conventional display example of the dispersion degree. FIG. 2 is an explanatory diagram of color codes set in .

Claims (1)

[Claims] (1) Emit an ultrasonic pulse into the living body, use the Doppler effect caused by blood flow in the living body to obtain the frequency spectrum of the Doppler signal, and calculate the average blood flow velocity and dispersion, respectively, from this frequency spectrum. , a method of displaying the data of the obtained average blood flow velocity and dispersion degree in a color image, a color code is set whose hue changes sequentially in correspondence with the magnitude of the dispersion degree, and this color code is A method for displaying blood flow dynamics in an ultrasonic diagnostic apparatus, characterized in that data on the degree of dispersion based on the average blood flow velocity is displayed on a tomographic image or an M-mode image separately from the data on the average blood flow velocity.