JPH08336531A - Ultrasonic diagnostic system - Google Patents

Abstract

PURPOSE: To recognize the contrast effect of an ultrasonic constrast medium quantitatively by presenting the differential image of ultrasonic tomographic image data before the ultrasonic contrast medium is injected to an examinee and ultrasonic image data while and after the ultrasonic contrast medium is injected to the examinee. CONSTITUTION: The tomographic image display circuit system 3 of this ultrasonic diagnostic system is provided with a detection circuit 8 which detects a reception signal from a reception wave phasing amplifier circuit 7 in an ultrasonic wave transmission/reception part 2 and sets it as the luminance information of a tomographic image, and stores real time tomographic image data A obtained from the digital signal of the luminance information in a real time ultrasonic tomographic memory circuit 10. Also, the circuit system 3 stores ultrasonic image data B for reference before the ultrasonic contrast medium is injected to the examinee in an ultrasonic tomographic image memory circuit 11 for reference. The difference of both image data A and B is calculated by a differential image display circuit system 5, and an encoder circuit 13 clarifies the difference between the tomographic images by performing coloring, for example, in red when a differential result shows a positive value and in blue when it shows a negative value.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ultrasonic diagnostic apparatus for evaluating the contrast effect of an ultrasonic contrast agent injected into a subject.

[0002]

2. Description of the Related Art The configuration of a conventional ultrasonic diagnostic apparatus is shown in FIG. As shown in FIG. 4, a probe 1 that transmits and receives ultrasonic waves to and from a subject, drives the probe 1 to generate ultrasonic waves at a predetermined repetition cycle, and processes received reflection echo signals. The ultrasonic transmission / reception section 2 and a tomographic image display circuit system for detecting the received signal processed by the ultrasonic transmission / reception section 2, digitizing the detected signal, and forming this digital signal as a tomographic image of the diagnostic region. 3 and an image display circuit 4 for analog-converting the image data output from the tomographic image display circuit system 3 to display a tomographic image two-dimensionally on a monitor screen.

[0003]

An ultrasonic diagnostic apparatus is one of the techniques for two-dimensionally visualizing the difference in ultrasonic acoustic impedance in a living body by using a reflected signal from the ultrasonic signal transmitted in the living body. Is one. In recent years, a method has been used in which carbon dioxide gas bubbles and the like are stirred in a solvent such as blood and injected into a subject as an ultrasonic contrast agent to obtain an ultrasonic tomographic image.
The above method is a method of observing the movement of the ultrasonic contrast agent contained in blood by utilizing the difference in the acoustic impedance between the biological tissue or blood and the ultrasonic contrast agent. Alternatively, it is one of the methods for evaluating the function of living tissue that has taken in red blood cells.

In a conventional ultrasonic diagnostic apparatus, when it is desired to quantitatively evaluate the contrast effect of an ultrasonic contrast agent injected into a subject, a photograph or VT is taken before the ultrasonic contrast agent is injected.
It was necessary to compare the ultrasound image recorded in R with the ultrasound image recorded in the photograph or VTR during the injection of ultrasound contrast agent. With this method, it was not possible to quantitatively evaluate the contrast effect of the ultrasound contrast agent at the target site in real time.For example, because the ultrasound contrast agent was injected too much, The contrast enhancement effect of the ultrasound contrast agent at the target diagnosis site is sufficient because the ultrasound contrast effect on the target organ appears to be difficult, or the injection amount of the ultrasound contrast agent is too small. There were problems such as not being able to obtain it.

Therefore, an object of the present invention is to provide an image capable of evaluating the contrast effect of an ultrasonic contrast agent in real time.

[0006]

In order to solve the above problems, an ultrasonic diagnostic apparatus according to the present invention includes a probe for transmitting and receiving ultrasonic waves to and from a subject, and an ultrasonic wave driven by the probe. Is generated for each predetermined repetition period and an ultrasonic wave transmission / reception unit that processes the received reflected echo signal and the reception signal processed by this ultrasonic wave transmission / reception unit are detected, and the signal after the detection is digitized, and this digital signal is detected. It has a tomographic image display circuit system for forming a signal as a tomographic image of a diagnostic region and an image display circuit for two-dimensionally displaying a tomographic image on a monitor screen by converting the image data output from this tomographic image display circuit system into an analog signal. In the ultrasonic diagnostic apparatus, a real-time tomographic image memory circuit for displaying a real-time ultrasonic tomographic image on the tomographic image display circuit system, and before or during injection of an ultrasonic contrast agent A reference tomographic image memory circuit that holds an ultrasonic tomographic image, a difference calculation circuit that calculates a difference between the ultrasonic tomographic image data stored in the real-time tomographic image memory circuit and the reference tomographic image memory circuit, and this difference calculation An encoder circuit that performs color tone and luminance modulation based on the calculation result of the circuit, a real-time ultrasonic tomographic image memory circuit, or an encoder circuit, or a real-time ultrasonic tomographic image memory so that the outputs of both are displayed on a monitor. A circuit and a selector circuit for selecting the output of the encoder circuit are newly provided.

[0007]

Since the ultrasonic diagnostic apparatus according to the present invention is constructed as described above, the operator injects the ultrasonic contrast agent into the subject while observing the ultrasonic tomographic image in real time, and By observing the difference image between the reference ultrasonic tomographic image and the real-time ultrasonic tomographic image stored in the ultrasonic tomographic image memory circuit, the contrast effect of the ultrasonic contrast agent can be quantitatively confirmed in real time. .

[0008]

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

FIG. 1 is a block diagram showing a first embodiment of the ultrasonic diagnostic apparatus of the present invention. This ultrasonic diagnostic apparatus uses ultrasonic waves to obtain a real-time ultrasonic tomographic image of a diagnostic site inside a subject, and also an ultrasonic tomographic image before injecting an ultrasonic contrast agent into the subject or an ultrasonic tomographic image. An ultrasonic tomographic image during injection of an ultrasonic contrast agent is used as a reference ultrasonic tomographic image, and an image of the difference between the real-time ultrasonic tomographic image and the reference ultrasonic tomographic image is obtained, and these are displayed two-dimensionally. Then, as shown in FIG. 1, it comprises a probe 1, an ultrasonic wave transmitting / receiving section 2, a tomographic image display circuit system 3, a differential image display circuit system 5, and an image display circuit 4.

The probe 1 transmits and receives ultrasonic waves toward a diagnostic site in the subject, and internally outputs ultrasonic waves and receives reflected waves from the diagnostic site. An oscillator is provided.

The ultrasonic wave transmitting / receiving section 2 drives the probe 1 to generate an ultrasonic wave at a predetermined repeating cycle and processes the reflected echo signal received by the probe 1. A transmission control circuit 6 that sends a transmission pulse to the probe 1 to control the transmission of ultrasonic waves toward a diagnosis site, and a reflection echo signal that is reflected by the diagnosis site in the subject and received by the probe 1. It is composed of a wave receiving and phasing amplifier circuit 7 which amplifies and phases the signals by aligning the phases.

The tomographic image display circuit system 3 forms a tomographic image of a diagnostic region in the subject from the received signals processed by the ultrasonic wave transmitting / receiving section 2. A detection circuit 8 for detecting the reception signal output from the phase amplification circuit 7 to obtain luminance information of a tomographic image, and this detection circuit 8
The tomographic image brightness information signal output from the A / D conversion circuit 9 for digitizing and the digital tomographic image brightness information output from the A / D conversion circuit 9 are input and two-dimensional A real-time ultrasonic tomographic image memory circuit 10 for forming a real-time tomographic image.

Further, the tomographic image display circuit system 3 has a reference ultrasonic tomographic image memory circuit 11 for storing reference ultrasonic tomographic image data before the ultrasonic contrast agent is injected into the subject.

The differential image display circuit system 5 is a reference ultrasonic tomographic image before injection of the ultrasonic contrast agent stored in the reference ultrasonic tomographic image memory circuit 11 of the tomographic image display circuit system 3 into a subject. Data and real-time ultrasonic tomographic image memory circuit 1
A difference calculation circuit 12 for calculating a difference between real-time ultrasonic tomographic image data stored in 0, and the difference calculation circuit 12
The encoder circuit 13 is provided for displaying the calculation result of 1) on the image display circuit 4 for easy identification. The difference calculation circuit 12 is
This is an arithmetic circuit that subtracts the luminance data of the same position stored in the reference ultrasonic tomographic image memory circuit 11 from the luminance data of an arbitrary position stored in the real-time ultrasonic tomographic image memory circuit 10. . Furthermore, the encoder circuit 1
3 is red when the calculation result of the difference calculation circuit 12 at an arbitrary position is positive, that is, when the brightness of the real-time ultrasonic tomographic image data is higher than the brightness of the reference ultrasonic image data. When the calculation result of the difference calculation circuit 12 is negative, that is, when the brightness of the real-time ultrasonic tomographic image data is smaller than the brightness of the reference ultrasonic image data, the color is colored blue. Further, the brightness of red or blue is set according to the magnitude of the absolute value of the calculation result of the difference calculation circuit 12. As described above, by performing the color tone and the brightness modulation based on the calculation result of the difference calculation circuit 12, it becomes possible to clearly recognize the difference between the two ultrasonic tomographic images, and the discriminating ability of the difference calculation result is improved. .

The image display circuit 4 has real-time ultrasonic tomographic image data stored in the tomographic image display circuit system 3 and real-time ultrasonic tomographic image data calculated in the differential image display circuit system 5. And a selector circuit 14 for selecting or superimposing one or both of the difference image data generated based on the difference between the reference ultrasonic image data,
It comprises a D / A conversion circuit 15 for converting the digital signal output of the selector circuit 14 into an analog signal, and a monitor 16 for displaying the analog signal output of the D / A conversion circuit 15.

By configuring the ultrasonic diagnostic apparatus as described above, it is possible to quantitatively and in real time evaluate the contrast effect of the ultrasonic contrast agent before and after injecting the ultrasonic contrast agent into the subject. .

Another embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a block diagram showing a second embodiment of the ultrasonic diagnostic apparatus of the present invention. This ultrasonic diagnostic apparatus uses ultrasonic waves to obtain a real-time ultrasonic tomographic image of a diagnostic site inside a subject, and also an ultrasonic tomographic image before injecting an ultrasonic contrast agent into the subject or an ultrasonic tomographic image. An ultrasonic tomographic image during injection of an ultrasonic contrast agent is used as a reference ultrasonic tomographic image, and an image of the difference between the real-time ultrasonic tomographic image and the reference ultrasonic tomographic image is obtained, and these are displayed two-dimensionally. Then, as shown in FIG. 2, the probe 1, the ultrasonic transmission / reception unit 2, the tomographic image display circuit system 2, the differential image image display circuit system 5, the image display circuit 4, and the electrocardiographic waveform measurement circuit. 17 and.

The probe 1 transmits and receives ultrasonic waves toward a diagnostic site in the subject, and internally outputs ultrasonic waves and receives reflected waves from the diagnostic site. An oscillator is provided.

The ultrasonic wave transmitting / receiving section 2 drives the probe 1 to generate an ultrasonic wave at a predetermined repetition cycle and processes the reflected echo signal received by the probe 1. A transmission control circuit that sends a transmission pulse to the probe 1 to control the transmission of ultrasonic waves toward a diagnostic site, and a reflected echo signal reflected by the diagnostic site in the subject and received by the probe 1 is amplified. It also comprises a wave receiving and phasing amplifier circuit which aligns the phases to perform phasing.

The tomographic image display circuit system 3 forms a tomographic image of a diagnostic region in the subject from the received signals processed by the ultrasonic wave transmitting / receiving section 2. A detection circuit 8 for detecting the reception signal output from the phase amplification circuit 7 to obtain luminance information of a tomographic image, and this detection circuit 8
The tomographic image brightness information signal output from the A / D conversion circuit 9 for digitizing and the digital tomographic image brightness information output from the A / D conversion circuit 9 are input and two-dimensional A real-time ultrasonic tomographic image memory circuit 10 for forming a real-time tomographic image. In particular, the real-time ultrasonic tomographic image memory circuit 10 has an electrocardiographic waveform as shown in FIG.
Acquires real-time ultrasonic tomographic image data in synchronization with the R wave,
The time delay information from the R wave of the electrocardiographic waveform of the collected ultrasonic tomographic image data is also acquired at the same time.

Further, the tomographic image display circuit system 3 is used for accumulating a plurality of reference ultrasonic tomographic image data before injecting an ultrasonic contrast agent into a subject in synchronization with an electrocardiographic waveform. It has an image memory circuit group 11-a. For example, in FIG.
As shown in, when 30 images can be captured during one heartbeat, the ultrasonic tomographic image memory circuit group 11-a for reference is sequentially synchronized with the R wave of the electrocardiographic waveform. Take in.

The differential image display circuit system 5 displays the electrocardiographic waveform before the ultrasonic contrast agent stored in the reference ultrasonic tomographic image memory circuit group 11-a of the tomographic image display circuit system 3 is injected into the subject. Difference calculation circuit 12 for calculating the difference between the synchronized reference ultrasonic tomographic image data and the real-time ultrasonic tomographic image data stored in the real-time ultrasonic tomographic image memory circuit 10.
And the calculation result of the difference calculation circuit 12 is displayed on the image display circuit 4.
An encoder circuit 13 is provided for easy display.

The difference calculation circuit 12 uses the luminance data at an arbitrary position stored in the real-time ultrasonic tomographic image memory circuit 10 for reference, and stores the reference ultrasonic tomographic image memory circuit group 11-a for reference. This is an arithmetic circuit that selects reference ultrasonic tomographic image data of the same time phase on the electrocardiographic waveform from the ultrasonic tomographic image data, and subtracts luminance data at the same position.
That is, in FIG. 5, the real-time ultrasonic tomographic image memory circuit 1
The real-time ultrasonic tomographic image data stored in 0 is the electrocardiographic waveform R
If the data is 3 frames counted from the wave (Real-3), the reference ultrasonic tomographic image memory circuit group 11-a outputs the reference ultrasonic tomographic image data (Ref-3) of the same time phase of the electrocardiographic waveform. Select
The brightness difference between the two image data is calculated.

Further, the encoder circuit 13 is, for example,
When the calculation result of the difference calculation circuit 12 at an arbitrary position is positive, that is, when the luminance of the real-time ultrasonic tomographic image data is higher than the luminance of the reference ultrasonic image data, coloring is performed in red, When the calculation result of the difference calculation circuit is negative, that is, when the brightness of the real-time ultrasonic tomographic image data is smaller than the brightness of the reference ultrasonic image data, coloring is performed in blue, and the difference calculation is further performed. The brightness of red or blue is set according to the magnitude of the absolute value of the calculation result of the circuit 12. In this way, it is possible to clearly recognize the difference between the two ultrasonic tomographic images by performing the color tone and the brightness modulation based on the calculation result of the difference calculation circuit 12.
The discriminating ability of the difference calculation result is improved.

The image display circuit 4 includes real-time ultrasonic tomographic image data stored in the tomographic image display circuit system 3 and real-time ultrasonic tomographic image data calculated in the differential image display circuit system 5. And a selector circuit 14 for selecting or superimposing one or both of the difference image data generated based on the difference between the reference ultrasonic image data,
It comprises a D / A conversion circuit 15 for converting the digital signal output of the selector circuit 14 into an analog signal, and a monitor 16 for displaying the analog signal output of the D / A conversion circuit 15.

The electrocardiographic waveform measuring circuit 17 is a circuit for measuring the fluctuation of the electric potential on the body surface which appears with the pulsation of the heart, and it is known that a characteristic waveform called an R wave appears during the systole of the heart. ing. In the case of a healthy person, since the heart beats in a substantially constant cycle, an ultrasonic tomographic image acquired in a time phase separated from the R wave by a constant time becomes a substantially constant image.

By configuring the ultrasonic diagnostic apparatus as described above, the contrast effect of the ultrasonic contrast agent before and after the injection of the ultrasonic contrast agent into the subject can be quantitatively performed without being affected by the pulsation of the heart. It is possible to evaluate in real time.

Another embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a block diagram showing a third embodiment of the ultrasonic diagnostic apparatus of the invention. This ultrasonic diagnostic apparatus uses ultrasonic waves to obtain a real-time ultrasonic tomographic image of a diagnostic site inside a subject, and also an ultrasonic tomographic image before injecting an ultrasonic contrast agent into the subject or an ultrasonic tomographic image. An ultrasonic tomographic image during injection of an ultrasonic contrast agent is used as a reference ultrasonic tomographic image, and an image of the difference between the real-time ultrasonic tomographic image and the reference ultrasonic tomographic image is obtained, and these are displayed two-dimensionally. Then, as shown in FIG. 3, the probe 1, the ultrasonic wave transmission / reception unit 2, the tomographic image display circuit system 3, the differential image image display circuit system 5, the image display circuit 4, and the electrocardiographic waveform measurement circuit. 17 and.

The probe 1 transmits and receives ultrasonic waves toward a diagnostic site in the subject, and internally outputs ultrasonic waves and receives reflected waves from the diagnostic site. An oscillator is provided.

The ultrasonic wave transmitting / receiving section 2 drives the probe 1 to generate an ultrasonic wave at a predetermined repetition cycle and processes the reflected echo signal received by the probe 1. A transmission control circuit 6 that sends a transmission pulse to the probe 1 to control the transmission of ultrasonic waves toward a diagnosis site, and a reflection echo signal that is reflected by the diagnosis site in the subject and received by the probe 1. It is composed of a wave receiving and phasing amplifier circuit 7 which amplifies and phases the signals by aligning the phases.

The tomographic image display circuit system 3 forms a tomographic image of a diagnostic region in the subject from the received signals processed by the ultrasonic wave transmitting / receiving unit 2. A detection circuit 8 that detects the reception signal output from the phase amplification circuit 7 and uses it as the luminance information of the tomographic image, and an A / D conversion that inputs and digitizes the signal of the tomographic image luminance information that is output from this detection circuit. A circuit 9 and a plurality of real-time ultrasonic tomographic image memory circuits for inputting digital tomographic image luminance information output from the A / D co-conversion circuit 9 and forming a two-dimensional real-time tomographic image Group 10-a. In particular,
The real-time ultrasonic tomographic image memory circuit group 10-a sequentially acquires the real-time ultrasonic tomographic image data in synchronization with the R wave of the electrocardiographic waveform as shown in FIG. 5, and collects the acquired ultrasonic tomographic image data. The time delay information from the electrocardiographic waveform R wave is also acquired at the same time.

Further, the tomographic image display circuit system 3 is used for storing a plurality of reference ultrasonic tomographic image data before the ultrasonic contrast agent is injected into the subject in synchronization with the electrocardiographic waveform. It has an image memory circuit group 11-a. For example, in FIG.
As shown in, when 30 images can be captured during one heartbeat, the ultrasonic tomographic image memory circuit group 11-a for reference is sequentially synchronized with the R wave of the electrocardiographic waveform. Take in.

The differential image display circuit system 5 displays the electrocardiographic waveform before the ultrasonic contrast agent stored in the reference ultrasonic tomographic image memory circuit group 11-a of the tomographic image display circuit system 3 is injected into the subject. A difference calculation circuit 1 for calculating the difference between the synchronized reference ultrasonic tomographic image data and the real-time ultrasonic tomographic image data stored in the real-time ultrasonic tomographic image memory circuit group 10-a.
2 and an encoder circuit 13 for easily displaying the calculation result of the difference calculation circuit 12 on the image display circuit 4.

The difference calculation circuit 12 is stored in the reference ultrasonic tomographic image memory circuit group 11-a from the luminance data at an arbitrary position stored in the real-time ultrasonic tomographic image memory circuit group 10-a. This is an arithmetic circuit that selects reference ultrasonic tomographic image data of the same time phase on the electrocardiographic waveform from the reference ultrasonic tomographic image data, and subtracts the luminance data at the same position. That is, in FIG. 5, if the real-time ultrasonic tomographic image data stored in the real-time ultrasonic tomographic image memory circuit group 10-a is data of three frames (Real-3) counted from the R wave of the electrocardiographic waveform, From the reference ultrasonic tomographic image memory circuit group 11-a,
Reference ultrasonic tomographic image data for the same time phase of the electrocardiographic waveform (Ref-3)
Is selected, and the brightness difference between the two image data is calculated.

Further, the encoder circuit 13 is, for example,
When the calculation result of the difference calculation circuit 12 at an arbitrary position is positive, that is, when the luminance of the real-time ultrasonic tomographic image data is higher than the luminance of the reference ultrasonic image data, coloring is performed in red, When the calculation result of the difference calculation circuit is negative, that is, when the brightness of the real-time ultrasonic tomographic image data is smaller than the brightness of the reference ultrasonic image data, coloring is performed in blue, and the difference calculation is further performed. The brightness of red or blue is set according to the magnitude of the absolute value of the calculation result of the circuit 12. By thus performing the color tone and the brightness modulation based on the calculation result of the difference calculation circuit 12, the ability to discriminate the difference calculation result between two ultrasonic tomographic images is improved.

The image display circuit 4 has real-time ultrasonic tomographic image data stored in the tomographic image display circuit system 3 and real-time ultrasonic tomographic image data calculated in the differential image display circuit system 5. And a selector circuit 14 for selecting or superimposing one or both of the difference image data generated based on the difference between the reference ultrasonic image data,
It comprises a D / A conversion circuit 15 for converting the digital signal output of the selector circuit 14 into an analog signal, and a monitor 16 for displaying the analog signal output of the D / A conversion circuit 15.

The electrocardiographic waveform measuring circuit 17 is a circuit for measuring the fluctuation of the electric potential on the body surface that appears with the pulsation of the heart, and it is known that a characteristic waveform called an R wave appears during the systole of the heart. ing. In the case of a healthy person, since the heart beats in a substantially constant cycle, an ultrasonic tomographic image acquired in a time phase separated from the R wave by a constant time becomes a substantially constant image.

By configuring the ultrasonic diagnostic apparatus as described above, the contrast effect of the ultrasonic contrast agent before and after the injection of the ultrasonic contrast agent into the subject can be quantitatively performed without being affected by the pulsation of the heart. It is possible to evaluate in real time. Further, as shown in FIG. 6, the real-time ultrasonic tomographic image memory circuit group 10-a and the reference ultrasonic tomographic image memory circuit group 1
By repeatedly reading the image stored in 1-a,
It is possible to observe in detail the difference image in the same time phase of the electrocardiographic waveform of both memory circuit groups. This makes it possible to reduce the restraint time of the subject and reduce the degree of invasion of the subject. In addition, as shown in FIG.
The ultrasonic tomographic image data of the time phase separated from the R wave by a certain time is sequentially stored in the real-time ultrasonic tomographic image memory circuit group, and the ultrasonic wave of the same time phase stored in the reference ultrasonic tomographic image memory circuit group is stored. By performing the difference calculation with the tomographic image, it is possible to observe in detail the temporal change in the contrast effect of the ultrasonic contrast agent due to the pulsation of the heart.

[0041]

Since the present invention is constructed as described above,
When injecting an ultrasonic contrast agent into a subject and observing its ultrasonic contrast effect, the ultrasound stored in the reference ultrasonic tomographic image memory circuit before injecting the ultrasonic contrast agent into the subject is observed. Presenting differential images of the ultrasonic tomographic image data and the ultrasonic image data during and after the injection of the ultrasonic contrast agent stored in the real-time ultrasonic tomographic image memory circuit into the subject. This makes it possible to quantitatively grasp the contrast effect of the ultrasonic contrast agent. In addition, by using the electrocardiographic waveform measurement circuit, it is possible to present a difference image between the real-time ultrasonic tomographic image and the reference ultrasonic tomographic image that have the same time phase on the electrocardiographic waveform and are less affected by the heart pulsation. Is possible. As a result, an image with high diagnostic value can be obtained.

[Brief description of drawings]

FIG. 1 is a block diagram showing a first embodiment of an ultrasonic diagnostic apparatus according to the present invention.

FIG. 2 is a block diagram showing a second embodiment of the ultrasonic diagnostic apparatus according to the present invention.

FIG. 3 is a block diagram showing an ultrasonic diagnostic apparatus according to a third embodiment of the present invention.

FIG. 4 is a block diagram showing a conventional ultrasonic diagnostic apparatus.

FIG. 5 is a time chart for explaining the second embodiment.

FIG. 6 is a time chart for explaining a third embodiment.

FIG. 7 is a time chart for explaining a third embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Probe 2 Ultrasonic wave transmitting / receiving section 3 Tomographic image display circuit system 4 Image display circuit 5 Differential image display circuit 6 Transmission control circuit 7 Received wave phasing amplification circuit 8 Detection circuit 9 A / D conversion circuit 10 Real-time ultrasonic wave Tomographic image memory circuit 11 Ultrasonic tomographic image memory circuit for reference 12 Difference calculation circuit 13 Encoder circuit 14 Selector circuit 15 D / A conversion circuit 16 Monitor

Claims (2)

[Claims] 1. A probe for actually transmitting and receiving ultrasonic waves, an ultrasonic transmitting / receiving unit for controlling ultrasonic transmission of the probe and phasing a signal received from the probe, and a real-time ultrasonic wave. A real-time ultrasonic tomographic image memory circuit for forming a tomographic image, and a reference ultrasonic tomographic image for forming a reference ultrasonic tomographic image before or during injection of an ultrasonic contrast agent into a subject A tomographic image display circuit system having a memory circuit, a circuit for calculating the difference between the image data stored in the real-time ultrasonic tomographic image memory circuit and the reference ultrasonic tomographic image memory circuit, and a color signal of the calculation result. An ultrasonic diagnostic apparatus comprising: a differential image display circuit system having an encoder circuit for converting the image into an image; and an image display circuit for displaying outputs of the tomographic image display circuit system and the differential image display circuit system. 2. A probe for actually transmitting and receiving ultrasonic waves, an ultrasonic transceiver for controlling ultrasonic transmission of the probe and phasing a signal received from the probe, and a real-time ultrasonic wave. A plurality of real-time ultrasonic tomographic image memory circuits for constructing a tomographic image,
And a tomographic image display circuit system having a plurality of reference ultrasonic tomographic image memory circuits for forming a reference ultrasonic tomographic image before or during injection of an ultrasonic contrast agent into a subject, A differential image display circuit system having a circuit for calculating the difference between the image data stored in the ultrasonic tomographic image memory circuit and the reference ultrasonic tomographic image memory circuit, and an encoder circuit for converting the calculation result into a color signal of color; An ultrasonic diagnostic apparatus comprising: an image display circuit for displaying outputs of a tomographic image display circuit system and a differential image display circuit system; and an electrocardiographic waveform measuring circuit for measuring an electrocardiographic waveform.