JP2830331B2 - Ultrasound diagnostic equipment - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ultrasonic diagnostic apparatus, and more particularly to an ultrasonic diagnostic apparatus that displays biological information based on a reflected signal obtained from a living body.

[Related Art] In an ultrasonic diagnostic apparatus used in the medical field, for example, tomographic data of a heart part is displayed on a monitor in real time, or a blood flow velocity at a specific site is measured by a pulse Doppler method, and this distribution is determined in the same manner as described above. In general, the information is displayed on a monitor. Further, there is a display device in which tomographic data is displayed on a monitor, and a blood flow velocity at a specific site is displayed side by side on a monitor on which the tomographic data is displayed.

Recently, in order to grasp blood flow velocity two-dimensionally,
A two-dimensional blood flow tomography is adopted. This is to synthesize a blood flow velocity with tomographic data and express the blood flow velocity in two dimensions and in real time. That is, tomographic information (gray echo information) and blood flow information (color Doppler information) are digitized and synthesized, respectively, and R, G, B
Is converted to a television signal. The blood flow velocity is displayed so as to be superimposed on a normal tomographic image, and the average velocity profile of the detected blood flow is displayed in color (color flow mapping).

In an ultrasonic diagnostic apparatus employing such a display mode, color display (Doppler display) or gray display (echo display) is performed on each pixel forming an image.
The determination of whether to perform is based on one of the following criteria (a) and (b). (A) When a threshold value is set for a color level, gray (echo information) is displayed for a pixel whose color level is lower than this threshold value (for example, a blood flow velocity is low). In addition, a color (Doppler information) is displayed for a pixel whose color level is higher than the threshold value.

(B) When a threshold value is set for the gray level, a color is displayed for a pixel whose gray level is lower than this threshold value (weak echo). Pixels having a gray level higher than the threshold display gray.

[Problems to be solved by the invention]

In the conventional ultrasonic diagnostic apparatus according to the above-described criteria, the following problem occurs. That is, when the determination criterion of (a) is followed, a low color level is not displayed.
Further, when the determination criterion of (b) is followed, a low gray level is not displayed. Further, according to the determination criterion (b), a region having a high gray level in a blood vessel, such as an arterial system, is displayed in gray, so that the blood flow and the like in this region cannot be displayed in color. Therefore, in the conventional apparatus, information obtained from the ultrasonic reflection signal is limited.

An object of the present invention is to provide an ultrasonic diagnostic apparatus capable of displaying more information.

[Means for solving the problem]

An ultrasonic diagnostic apparatus according to the present invention is an ultrasonic diagnostic apparatus that displays biological information based on an ultrasonic reflected signal obtained from a living body, and includes a tomographic data processing circuit, a blood flow data processing circuit, A circuit and display means are provided.

The tomographic data processing circuit is a circuit that obtains in-vivo tomographic data from a reflected signal. The blood flow data processing circuit is a circuit for obtaining blood flow data in a living body from a reflected signal. The selection circuit compares a tomographic signal obtained from the tomographic data processing circuit with a tomographic threshold value for each pixel, and compares a tomographic signal obtained from the blood flow data processing circuit for each pixel with a first signal.
Compared with the threshold value and the second threshold value, tomographic data is selected when the blood flow signal level is smaller than the first threshold value, and when the blood flow signal level is larger than the second threshold value, the tomographic data is selected. Selecting the flow data, selecting the tomographic data when the level of the blood flow signal is larger than the first threshold value and smaller than the second threshold value and the magnitude of the tomographic signal is larger than the tomographic threshold value; Is larger than the first threshold and smaller than the second threshold and the magnitude of the tomographic signal is smaller than the tomographic threshold, blood flow data is selected. The display means superimposes the tomographic data and the blood flow data by displaying the tomographic data in gray and the blood flow data in color based on the processing of the selection circuit.

[Action]

In the ultrasonic diagnostic apparatus according to the present invention, the tomographic data processing circuit obtains tomographic data in the living body from the ultrasonic reflected signal obtained in the living body. Further, the blood flow data processing circuit can obtain blood flow data in the living body from the ultrasonic reflection signal. Then, the level of the blood flow signal is set to the first level by the selection circuit.
When the value is larger than the threshold value and smaller than the second threshold value, one of tomographic data and blood flow data is selected according to the magnitude of the tomographic signal. The selected data is displayed in gray or color, respectively, as biological information.

As described above, the selection according to the magnitude of the tomographic signal is performed with respect to the blood flow signal of the intermediate level that is larger than the first threshold and smaller than the second threshold, so that only one threshold is set as in the related art. , More information can be obtained from the reflected signal.

〔Example〕

FIG. 1 shows a schematic configuration of an ultrasonic diagnostic apparatus according to one embodiment of the present invention.

In FIG. 1, a probe 1 includes a plurality of micro-vibrators and is connected to a transmission / reception control circuit 2.
The transmission / reception control circuit 2 includes a high-frequency pulse oscillator for transmitting an ultrasonic beam, a receiver for receiving and processing a reflected echo,
It is composed of a delay circuit for performing electronic scanning, a delay amount selection circuit, and the like. The output of the transmission / reception control circuit 2 is connected to an echo signal reception circuit 3 and a blood flow information calculation circuit 4.

The echo signal receiving circuit 3 is a circuit for obtaining tomographic data (gray information) of a living body. Echo signal receiving circuit 3
Includes a reception shaping circuit that performs a waveform shaping process on a received signal. The output of the echo signal receiving circuit 3 is connected to a gray / color selecting circuit 5.
The blood flow information calculation circuit 4 is a circuit for obtaining blood flow data (color information) of a living body based on the Doppler shift frequency. The blood flow information calculation circuit 4 includes a reception shaping and detection circuit for performing reception shaping and detection. The output of the blood flow information settlement circuit 4 is connected to a gray / color selection circuit 5.

Next, a schematic configuration of the gray / color selection circuit 5 is shown in FIG.

In FIG. 2, gray information G and color information C from the echo signal receiving circuit 3 and the blood flow information calculating circuit 4 are input to the multiplexer 8. The multiplexer 8 is a circuit for passing either gray information or color information in accordance with a switching signal described later. The gray / color selection circuit 5 includes comparators 9 to 11. The gray information G is input to the comparator 9, and the color information C is input to the comparisons 10 and 11, respectively. Each comparator 9 to 11, respectively threshold G _A, C _B, is C _A is input. Incidentally, C _A is set to a value larger than C _B. As the color information C, any one of the flow velocity, the flow velocity power, and the dispersion is input to the circuit 5 according to the user's selection. For this reason, each of the threshold values G _A , C _B , and C _A can be changed according to conditions such as the type of the color information C, the Doppler sample rate, and the region of interest.

Comparator 9, the relationship between the gray information G and the threshold value G _A to be input, and outputs a "1" when the G <G _A. The comparator 10 receives the input color information C and the threshold C _B
And outputs "1" when the ≧ C _B | relationship with the | C. The comparator 11 receives the input color information C and the threshold C _A
Relationship with the, | C | and outputs "1" when the ≧ C _A.

Outputs of the comparators 9 and 10 are connected to an AND circuit 12. The output of the AND circuit 12 is connected to the OR circuit 13. The output of the comparator 11 is connected to the OR circuit 13. The output of the OR circuit 13 is connected to the AND circuit 14. In addition, a C + G display mode signal is input to the AND circuit 14. The output of the AND circuit 14 is input to the s input of the multiplexer 8 as a switching signal. The multiplexer 8 allows the color information C to pass when the output of the AND circuit 14 is “1”.
When the output of 14 is "0", the gray information G is passed.

 Next, the operation will be described.

First, the high frequency pulse oscillator of the transmission / reception control circuit 2 is driven, and a high frequency pulse is applied to the probe 1. Thereby, the ultrasonic beam is transmitted from the probe 1 into the living body.
The reflected echo reflected in the living body is received by the probe 1,
The signal is input to the transmission / reception control circuit 2. The reflected echo signal that has undergone predetermined processing in the transmission / reception control circuit 2 is input to the echo signal reception circuit 3 and the blood flow information calculation circuit 4. The reflected echo signal input to the echo signal receiving circuit 3 is subjected to signal processing such as amplification and waveform shaping, and is input to the gray / color selection circuit 5. The reflected echo signal input to the blood flow information calculation circuit 4 is subjected to signal processing such as amplification, waveform shaping, and detection processing, and is input to the gray / color selection circuit 5.

In the gray / color selection circuit 5, the output (gray information G) of the echo signal receiving circuit 3 is input to the multiplexer 8. Also, the gray information G from the echo signal receiving circuit 3
Is input to the comparator 9. On the other hand, the blood flow information calculation circuit 4
Is input to the comparators 10 and 11. Each of the comparators 9 to 11 compares the input signal with the threshold and outputs “0” or “1”, respectively.

Now, for example, if the color information C and the gray information G are C _B ≦
| C |, and C _A and G <C _A. At this time, "1" is output from the comparator 9, "1" is output from the comparator 10, and "0" is output from the comparator 11. Then, the outputs of the comparators 9 and 10 are input to the AND circuit 12. Then, the AND circuit
12 outputs "1". The output of the AND circuit 12 is input to the OR circuit 13. On the other hand, the output from the comparator 11 is input to the OR circuit 13. As a result, "1" is output from the OR circuit 13, and this output is input to the AND circuit 14. On the other hand, the C + G display mode signal “1” is input to the AND circuit 14. Therefore, "1" is output from the AND circuit 14. The output from the AND circuit 14 is input to the s input of the multiplexer 8. As a result,
The multiplexer 8 is switched so that the color information C passes through the multiplexer 8. As a result, color information C is output from the gray / color selection circuit 5 (see FIG. 3 (*)). The output of the gray / color selection circuit 5 is input to the display signal generation circuit 6. The display signal generation circuit 6 processes the input signal into a signal that can be displayed on the CRT of the display 7 and outputs a display signal. Display 7
Receives the display signal and displays blood flow information (color information C) on the CRT.

The description of the case where the color information C and the gray information G have values other than those described above is omitted, but FIG. 3 shows a summary of all of them. From FIG. 3, the following are derived as criteria for determining whether the color information C is displayed on the display 7 or the gray information G is displayed. That, i) color information C level is greater than the threshold value C _A, the color information C is outputted.

ii) Color Information C level of C _B ≦ | C | C in the case of _A, when the level of the gray information G is G <G _A output color information C, also gray information G when the G ≧ G _A Is output.

iii) color information C level of | C | if the C _B is irrespective gray information G gray level G is output.

In general, in a display mode in which a color image and a gray image are displayed in a superimposed manner, a main purpose is to find a blood flow or a flow of a body fluid. Therefore, it is preferable to display a high color level prior to a gray image. It can be said that the above criterion (i) meets this requirement. In general, a region having a low gray level is a liquid that does not reflect ultrasonic waves. Therefore, in this region, color information indicating a flow should be displayed prior to gray information. According to the criterion (ii), a low color level can be displayed in such an area.

Furthermore, when the color level is very low, it can be considered that it is not flow velocity information, in which case gray information should be displayed. Criterion (iii) meets this requirement. Thus, in this embodiment, much information can be obtained from the reflected echo signal.

[Other embodiments]

In the embodiment, the color information C or the gray information G is displayed according to the criterion shown in FIG. 3, but the application of the present invention is not limited to this, and a criterion different from that in FIG. 3 may be adopted. Good. Further, the number of thresholds may be increased.

〔The invention's effect〕

According to the ultrasonic diagnostic apparatus of the present invention, the selection circuit that selects one of the tomographic data and the blood flow data in accordance with the magnitude of the tomographic signal is provided, so that more information can be displayed. Become.

[Brief description of the drawings]

FIG. 1 is a schematic block diagram of an ultrasonic diagnostic apparatus according to an embodiment of the present invention, FIG. 2 is a schematic block diagram of a gray / color selection circuit employed in the embodiment apparatus, and FIG. FIG. 9 is a diagram showing criteria for determining an image. 3 ... Echo signal receiving circuit, 4 ... Blood flow information calculation circuit,
5. Gray / color selection circuit.

Claims (1)

(57) [Claims] 1. An ultrasonic diagnostic apparatus for displaying biological information based on an ultrasonic reflected signal obtained from a living body, wherein: a tomographic data processing circuit for obtaining tomographic data in the living body from the reflected signal; A blood flow data processing circuit for obtaining blood flow data in a living body, and comparing a tomographic signal obtained from the tomographic data processing circuit with a tomographic threshold value for each pixel and a blood flow signal obtained from the blood flow data processing circuit. The level of the blood flow signal is compared with the first threshold value and the second threshold value for each pixel.
When the level is smaller than the threshold value, the tomographic data is selected, and when the level of the blood flow signal is higher than the second threshold value, the blood flow data is selected, and the level of the blood flow signal is higher than the first threshold value. When the magnitude of the tomographic signal is smaller than the threshold value and the magnitude of the tomographic signal is greater than the tomographic threshold value, tomographic data is selected, and the level of the blood flow signal is greater than the first threshold value, less than the second threshold value, and A selection circuit that selects blood flow data when the size is smaller than the tomographic threshold value; based on the processing of the selection circuit, the tomographic data is displayed in gray, and the blood flow data is displayed in color, whereby the tomographic data is displayed. And a display means for superimposing and displaying blood flow data.