JPH10258054A - Ultrasonic doppler rheometer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily and quickly perform the operation for the moving of a CF mode image display region. SOLUTION: When the bloodstream image for the left half of an organ is displayed, the coordinates for the right half of the organ are input from an operation panel, and by this motion, a moving control unit stops a CF mode scanning, and simultaneously, extends a B mode scanning width to an ultrasonic scanning available region IV, and makes a B mode image of a wide visual field angle and a CF mode image display frame II be displayed. An operator inputs the coordinates of a location after moving while referring the B mode image of an expanded B mode image display region I, to the operation panel, and moves the CF mode image display frame II to a desired area of the organ, and the moving control unit judges that the location after moving of the CF mode image display frame II is a CF mode image display region III, and resumes the CF mode scanning, and makes the CF mode image be displayed in the CF mode image display region III, and at the same time, makes the B mode image be displayed in the B mode image display region I where the B mode scanning width is contracted, so that the CF mode image display region III may be enclosed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ultrasonic Doppler blood flow meter which displays an image of the result of measuring the blood flow in a living body using the Doppler phenomenon of ultrasonic waves in the field of medical instruments. is there.

[0002]

2. Description of the Related Art Conventionally, a color tomographic image displayed in different colors according to the blood flow distribution state in a living body and a black and white two-dimensional tomographic image are superimposed and displayed using the Doppler phenomenon of ultrasonic waves. An acoustic two-dimensional Doppler blood flow meter (color flow device) is known.

FIG. 6 is a block diagram showing a schematic configuration of an ultrasonic Doppler blood flow meter.

[0004] 1 converts the electric signal output by the transmitting means 2 into an ultrasonic pulse and irradiates the ultrasonic signal into a living body (not shown), and receives an echo of the ultrasonic pulse reflected by a living tissue. A probe 3 converts the echo of the ultrasonic pulse into an electric signal and outputs the electric signal. Amplification unit 3 outputs the electric signal output from probe 1 and outputs the echo signal as echo data.

[0005] Reference numeral 4 denotes a B-mode image generating means for performing envelope detection on the echo data output from the receiving means 3 to generate a monochrome two-dimensional tomographic image (hereinafter referred to as "B-mode image"). The phase shift amount of the output echo data is converted into blood flow information, and a color tomographic image (hereinafter, referred to as color) is displayed according to the blood flow distribution such as blood flow velocity, blood flow echo intensity, and blood flow velocity dispersion in the living body. Color flow mode image generating means for generating a “CF mode image” (hereinafter “CF mode image generating means”)
It is).

Reference numeral 6 denotes an image synthesizing means for synthesizing the B-mode image output from the B-mode image generating means 4 and the CF mode image output from the CF mode image generating means 5, and 7 denotes a B-mode image output from the image synthesizing means 6. The monitor 8 displays a composite moving image of the B mode image and the CF mode image. The monitor 8 determines a scanning range of the B mode image and a scanning range of the CF mode image in accordance with an operator's instruction input from the operation panel 9 and performs an operation. This is control means for controlling each component so as to move the B-mode image and the CF-mode image on the screen of the monitor 7 by following the movement of a track ball (not shown) of the panel 9 in real time.

In the conventional example configured as described above,
When the probe 1 is brought into contact with the living body and an ultrasonic pulse is radially emitted from the probe 1 to the living body, the monitor 7 displays the living body in the B-mode image display area I based on the echo of the ultrasonic pulse reflected by the living tissue. Inside the B mode image obtained by scanning the tissue in a fan shape, the blood flow in the living body is placed in a CF mode image display area III surrounded by graphic lines (hereinafter referred to as “CF mode image display frame II”) generated by the control means 8. The CF mode image obtained by scanning the distribution state in a fan shape is positioned as shown in FIG. 7A, and the CF mode image representing the blood flow distribution is displayed over the B mode image representing the shape of the living tissue.

In order to change the CF mode image of the part currently under inspection displayed in the CF mode image display area III to the CF mode image of the part to be newly inspected, the operator operates a trackball or the like. And CF mode image display frame
When II is moved to a new site to be inspected on the screen of the monitor 7, the coordinates of the destination of the CF mode image display area III are input to the control means 8, and the B mode image display area I and the CF mode image display area The III moves on the screen of the monitor 7 following the movement of the trackball in real time.

For example, the CF mode image display area III is shown in FIG.
When the trackball is moved diagonally upward and to the right while it is positioned at the left end of the B-mode image display area I as shown in (a), the CF-mode image display area III follows the movement of the trackball and moves to the right. Move diagonally upward. When the CF mode image display frame II is on the B mode image inside the B mode image display area I currently displayed on the screen of the monitor 7 as shown in FIG. The CF mode image at the destination of the image display frame II is immediately displayed in the CF mode image display area III specified by the CF mode image display frame II.

[0010] Further, as shown in FIG. 7C, the CF mode image display frame II is displayed on the screen of the monitor 7 in the B mode.
When the right end of the mode image display area I is exceeded, the B mode image display area I is moved to a position including the destination CF mode image display frame II, and the destination B mode image is moved to the destination B mode. After the image is displayed in the image display area I, the CF mode image at the destination of the CF mode image display frame II is displayed in the CF mode image display frame.
A new image is displayed in the CF mode image display area III designated by II.

[0011]

By the way, in order to improve the frame rate of the image in the B-mode image display area I,
The B mode image display area I must be displayed narrower than the ultrasonic scannable area IV, and the CF mode image display area
In order to improve the frame rate of the III image, the CF mode scanning range must be limited to only the region of interest, and the CF mode image display region III must be limited to a part inside the B mode image display region I and displayed. Therefore, the display range of the B-mode image displayed in the B-mode image display region I and the display range of the CF mode image displayed in the CF mode image display region III are very limited to the operator's region of interest. It is narrowed to the site.

When the moving destination of the CF mode image display frame II is inside the currently displayed B mode image display area I as shown in FIG. By directly moving the CF mode image display frame II to a desired destination while referring to the B mode image displayed in the display area I, displaying the CF mode image of the destination in the CF mode image display area III. Can be.

However, when the moving destination of the CF mode image display frame II is outside the currently displayed B mode image display area I as shown in FIG. CF mode image display frame at the position where the part seems to be
By roughly moving II, the B-mode image display area I is moved along with the movement of the CF-mode image display area III, and the destination B-mode image is displayed in the B-mode image display area I. B displayed in the B-mode image display area I
The CF mode image display frame II must be moved to a desired destination while referring to the mode image, and the CF mode image at the destination must be displayed in the CF mode image display area III. There is a problem that the moving procedure of the CF mode image display frame II is complicated because the moving procedure of the II becomes at least two steps.

The present invention has been made to solve such a problem. When the CF mode image display area moves, the B mode image display area is enlarged to display a B mode image in a moving image. Accordingly, it is an object of the present invention to provide an ultrasonic Doppler blood flow meter in which the operation of moving the CF mode image display frame is simplified.

[0015]

According to the present invention, in order to solve such a problem, the control means moves the CF mode image display area by inputting coordinate values from an operation panel by an operator. A B-mode scanning controller for performing ultrasonic scanning for generating a B-mode image, and a C for performing ultrasonic scanning for generating a CF-mode image.
An F-mode scanning controller is provided to stop the CF-mode scanning and move the B-mode scanning range when moving the CF-mode image display area.

According to the present invention, even in the two-dimensional blood flow display in which the B-mode image display area is limited in order to increase the frame rate, the CF-mode scanning is stopped when the CF-mode image display area is moved, and the B-mode image is displayed. Because the mode scanning range is expanded, the destination of the CF mode image display area can be accurately determined while viewing the B mode image with a high frame rate over a wide range, so that the operability of the ultrasonic Doppler blood flow meter can be determined. And the diagnosis time can be shortened.

[0017]

Embodiments of the present invention will be described below with reference to the drawings. 6 and 7 indicate the same parts.

FIG. 1 is a schematic block diagram showing an embodiment of the present invention, in which a probe 1, a transmitting means 2, a receiving means 3, a B-mode image generating means 4, a CF-mode image generating means 5,
Since the configurations and operations of the image synthesizing means 6, the monitor 7 and the operation panel 9 are the same as those of the conventional ultrasonic Doppler blood flow meter, the description is omitted.

Reference numeral 10 denotes a movement control unit 11 and a CF mode scanning control unit.
It is a control means composed of 12 and a B-mode scanning control unit 13.

When the coordinate data of the CF mode image display frame II is received from the operation panel 9, the CF mode scanning control unit 11
12, CF mode scanning width, CF mode scanning position, C
In addition to instructing the start and stop of the F mode scanning, the B mode scanning width and the B mode scanning position are instructed to the B mode scanning controller 13, and the CF mode image determined by the CF mode scanning width and the CF mode scanning position This operation is described in detail with reference to the flow chart of FIG. 2 in a movement control unit which graphically draws the display frame II and sends it to the image synthesizing means 6.

First, the movement control unit 11 operates the operation panel 9 to
When it is detected that the coordinate data of the F-mode image display frame II has been input, it is determined whether or not the operator has changed the coordinate data (step S1).

If the coordinate data is not changed by the operator (step S1), the CF scanning flag is checked (step S2). Since the CF scanning flag is ON in the initial state, the coordinate data by the operator is changed. It is determined again whether or not a change has been made (step S2).

If the coordinate data has been changed (step S1), a timer (not shown) is started and the value t ₀ of the counter (not shown) is counted up at regular intervals, for example, every 0.01 second. Then (step S3), the CF scanning flag is turned off, and the CF mode scanning control unit 12 is instructed to stop the CF mode scanning (step S4).

Then, when the movement control unit 11 outputs a B mode scan width enlargement notification, the B mode scan control unit 13 enlarges the B mode scan width to expand the display range of the B mode image of the organ to be examined. (Step S5).

Further, the CF mode scanning control section 12 sets the CF mode scanning width and the scanning position according to the coordinate change amount output from the operation panel 9 (step S6).

Then, the movement control unit 11 writes the CF mode image display frame II on the graphic screen according to the CF mode scanning width and the scanning position newly set in the CF mode scanning control unit 12, and then combines the graphic screen with the image. Means 6
To superimpose on the B-mode image and display it on the monitor 7 (step S7), it is determined again whether or not coordinates have been input (step S1).

Therefore, if no coordinates have been entered, C
Since the F scanning flag is OFF (step S2), it is determined whether or not the value t _{0 of} the counter started in step S3 has exceeded a predetermined value T ₁ (step S8).

When the value t _{0 of} the counter does not exceed the predetermined value T ₁ , it is determined that a coordinate movement operation is being performed (step S 8), and it is determined whether or not coordinates have been input. The process is performed again (step S1).

If the counter value t ₀ exceeds the predetermined value T ₁ , it is considered that the movement of the coordinates by the operator has been completed (step S8), and the counter value t ₀ is determined. After finishing the count up (step S9),
After referring to the CF mode scanning width and the CF mode scanning position set in step S6, the B mode scanning width and the B mode scanning position are set so as to include the CF mode image display frame II (step S10). The CF scanning flag is turned on to instruct the CF mode scanning control unit 12 to restart the CF mode scanning (step S11).

The constant T ₁ may be set so that the time measured by the counter value t ₀ is about 0.05 to 0.5 seconds.

FIG. 3 is a flowchart for explaining the operation of the CF mode scanning control unit 12.

First, the CF mode scanning in the range of the CF mode image display frame II is started with reference to the CF mode scanning width and the CF mode scanning position set by the movement control section 11 (step S20).

Therefore, the CF scanning flag set in the movement control unit 11 is monitored, and if the CF scanning flag is not OFF (step S21), the monitoring of the CF scanning flag set in the movement control unit 11 is performed again. Is performed (step S21).

If the CF scanning flag is OFF (step S21), the CF mode scanning is stopped (step S21).
22) The CF mode image is erased from the monitor 7.

Thereafter, the CF scanning flag designated by the movement control unit 11 is monitored again. If the CF scanning flag is turned on (step S23), the CF mode scanning width and the CF mode scanning width reset by the movement control unit 11 are set. C according to CF mode scanning position
The F-mode scanning is performed again (step S20).

FIG. 4 is a flowchart for explaining the operation of the B-mode scanning controller 13.

First, the B-mode scanning in the range is started with reference to the B-mode scanning width and the B-mode scanning position set in the movement control section 11 (step S30).

Therefore, B set in the movement control unit 11
It monitors whether the mode scanning width and the B mode scanning position have been changed, and if there is any change (step S31), performs B mode scanning according to the B mode scanning width and the B mode scanning position reset in the movement control unit 11. (Step S30).

FIG. 5 is a diagram for explaining an image display method when the CF mode image display frame is moved.

FIG. 5A is an ultrasonic Doppler blood flow image,
Since the mode scanning width is limited to only the left half of the organ that is the region of interest, a moving image with a high frame rate is displayed in the B-mode image display region I.

Here, when the operator inputs the coordinates of the right half of the organ from the operation panel 9 in order to obtain a blood flow image of the right half of the organ, the movement control unit 11 stops the CF mode scanning. At the same time, the B mode scanning width is set to the ultrasonic scannable area IV.
5 (b)], a B-mode image with a wide viewing angle is displayed in the enlarged B-mode image display area I, and a CF mode image display frame II is displayed. Since only the B-mode scanning is performed in the enlarged B-mode image display area I, a B-mode image with a high frame rate can be obtained.

Then, the operator refers to the enlarged B-mode image of the B-mode image display area I and moves the operation panel 9 to the operation panel 9 until the CF-mode image display frame II moves to a desired part of the organ. Is input (see FIG. 5C). Then, the time T ₁ after the CF mode image display frame II moves to a desired part of the organ and the operator finishes inputting the coordinates.
After the elapse of the time, the movement control unit 11 sets the CF mode image display frame
The destination of II is determined to be the CF mode image display area III, and C
The F mode scanning is restarted to display a CF mode image of a high frame rate, and at the same time, a high frame is displayed in the B mode image display area I in which the B mode scanning width is reduced so as to include the CF mode image display area III. Rate Ultrasound 2
A dimensional blood flow image is displayed.

As described above, according to one embodiment of the present invention, when the CF mode image display area III is moved, the B mode scan width is expanded to the ultrasonic scannable area IV to provide a wide viewing angle. Displays the B-mode image, so that the operator can determine the diagnosis site while observing the whole organ, thereby improving the operability of the ultrasonic Doppler blood flow meter and shortening the diagnosis time.

When moving the CF mode image display frame II,
Since the CF mode scanning is stopped and only the B mode scanning is performed, a B mode image with a high frame rate can be obtained, and the region of interest can be specified more accurately.

Further, when it is desired to observe only the B-mode image, if the input of the coordinates is slightly perturbed, only the B-mode image can be instantaneously displayed on the monitor 7. It also has the convenience that the mode image display area III can be moved and the display between the CF mode image and the B mode image displayed on the monitor 7 can be easily switched.

[0046]

As described above, according to the present invention,
When moving the CF mode image display area, the B mode image with a wide viewing angle is displayed on the monitor at a high frame rate, so that the diagnosis site can be accurately determined while observing the whole organ, and There is an effect that the operability of the ultrasonic Doppler blood flow meter is improved and the diagnosis time can be shortened.

[Brief description of the drawings]

FIG. 1 is a schematic block diagram according to an embodiment of the present invention.

FIG. 2 is a flowchart illustrating an operation of a movement control unit according to the embodiment of the present invention.

FIG. 3 is a flowchart illustrating an operation of a CF mode scanning control unit according to the embodiment of the present invention.

FIG. 4 is a flowchart illustrating an operation of a B-mode scanning control unit according to one embodiment of the present invention.

FIG. 5 is a diagram illustrating an image display method when the CF mode image display frame is moved according to the embodiment of the present invention.

FIG. 6 is a block diagram of a conventional ultrasonic Doppler blood flow meter.

FIG. 7 is a diagram illustrating an image display method when a CF mode image display frame is moved in a conventional ultrasonic Doppler blood flow meter.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Probe, 2 ... Transmission means, 3 ... Receiving means, 4
... B mode generating means, 5 ... CF mode generating means, 6 ...
Image synthesis means, 7: Monitor, 9: Operation panel, 10
... Control means, 11 ... Move control unit, 12 ... CF mode scan control unit, 13 ... B mode scan control unit, I ... B mode image display area, II ... CF mode image display frame, III ... CF mode image display area, IV: Ultrasonic scanable area.

Claims (2)

[Claims] 1. A transmitting means for transmitting an ultrasonic pulse into a living body to be examined, a receiving means for receiving an echo of the transmitted ultrasonic pulse, an envelope detection of the received echo signal, and a monochrome tomographic image And a CF mode for generating a color tomographic image representing a blood flow information distribution such as a blood flow velocity, a blood flow echo intensity, and a blood flow velocity dispersion in the subject from the echo signal. Image generating means, image synthesizing means for displaying the tomographic images output from the B-mode image generating means and the CF-mode image generating means in a superimposed manner,
An ultrasonic Doppler blood comprising: coordinate input means for inputting a scanning position moving command from an operator; and control means for controlling a range for performing B-mode scanning and a range for performing CF mode scanning in accordance with input data from the coordinate input means. In the flow meter, when the coordinate input is received from the coordinate input means, the control means considers the time as a coordinate change period and outputs a CF.
An ultrasonic Doppler blood flow meter characterized in that only the B-mode scanning is performed by stopping the mode scanning, and the B-mode scanning range is expanded more than the B-mode scanning range during the non-coordinate change period. 2. The ultrasonic Doppler blood according to claim 1, wherein the control means extends the coordinate change period by a predetermined time even when the coordinate change input from the coordinate input means ends. Flow meter.