JPS58188431A - Ultrasonic diagnostic and treating 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] [Technical Field of the Invention] This invention belongs to the technical field of medical devices for diagnosis and treatment. The present invention relates to an ultrasonic diagnostic treatment device that can perform medical treatment.

[Technical background of the invention and its problems]

Ultrasonic waves are scanned into the subject's body, and reflected echoes from within the subject's body are received to form an ultrasound tomographic image, thereby obtaining useful information for diagnosis, such as the presence or absence of a lesion and the location of the condition. Ultrasonic diagnostic equipment and ultrasound for living organisms. 1! An ultrasonic treatment device for blocking the activity of diseased tissue such as cancer cells or destroying and removing diseased tissue by using the following methods:

An ultrasonic diagnostic treatment device that is combined into an integrated device has been proposed (see Japanese Patent Laid-Open Publication No. 51-24092).

The proposed ultrasonic diagnostic treatment device obtains an ultrasonic tomographic image by emitting ultrasound for biopsy from a probe unit that generates ultrasound for biopsy and therapeutic ultrasound focused at a predetermined position. After confirming the treatment area, switch the emission of ultrasound for biopsy to the emission of therapeutic ultrasound, irradiate the therapeutic ultrasound to the confirmed predetermined position inside the subject to perform treatment, and then repeat the treatment after treatment. The ultrasound emission is switched to the ultrasound emission for biological examination, and the therapeutic effect is confirmed using the obtained ultrasonic tomographic image.

However, according to the proposed ultrasonic diagnostic treatment apparatus, it is possible to confirm the treatment area in advance using an ultrasonic tomographic image using ultrasound for biopsy.

While the therapeutic ultrasound is being emitted into the vagina, it is not possible to confirm whether the therapeutic ultrasound is accurately irradiating the treatment area.

[Purpose of the invention]

This invention was made in view of the above-mentioned circumstances, and it emits therapeutic ultrasound at the same time as displaying an ultrasound tomographic image, and treats a specific region within the subject with ultrasound while observing the ultrasound tomographic image. The purpose of this invention is to provide an ultrasonic diagnostic treatment device that can perform the following steps.

[Summary of the invention]

The outline of this invention for achieving the above object is as follows.

In the ultrasonic diagnostic treatment device, one ultrasonic probe;
A signal processing circuit and a television monitor for displaying ultrasound tomographic images based on the reflected echoes of the ultrasound beam emitted from the ultrasound probe, an ultrasound beam for obtaining ultrasound tomograms in real time, and an ultrasound system for treatment. an ultrasonic beam generating means equipped with a switching means for switching between the ultrasonic beam and generating the ultrasonic beam from the ultrasonic glove; The present invention is characterized in that it includes a control means for controlling the switching means so as to generate the ultrasound tomographic images in real time, and performs ultrasound treatment at the same time as displaying a real-time ultrasound tomographic image.

[Embodiments of the invention]

Fig. 1 is a schematic block diagram showing an embodiment of the present invention, Fig. 2 (α1 is an explanatory diagram showing an ultrasonic probe linearly scanning with an ultrasonic beam, and Fig. 2 (h+ is an explanatory diagram showing an ultrasonic probe that focuses an ultrasonic beam. FIG. 3 is an explanatory diagram showing an ultrasound probe and a television monitor screen displaying an ultrasound tomographic image.

In FIG. 1, 1 is a therapeutic transmission pulse control circuit, 2 is a tomographic image transmission pulse control circuit, 6 is a switching device control circuit, and 4
is a drive element selection switch.

The switch control circuit 3 causes the drive element selection switch 4 to
Several to ten or so transmitters connected to each of a large number, for example, 60 to 120 ultrasonic transducers 5 arranged in an array, are turned on, and the tomographic image transmission pulse control is applied to them. When the signal from circuit 2 is added, 7 in α in Fig. 2
A narrow ultrasonic beam as shown in is emitted. The reflected ultrasound beam is detected by the ultrasound transducer 5 and sent to the receiver 8.
．． After passing through the switch 6, the signal passes through a reception delay line 9 and a signal processing circuit 10, and is input to the W monitor as a brightness signal of the TV monitor 11. Next, the switching device control circuit 3 switches the driving element selection switching device 4 so as to shift the ultrasound transducers 5 one by one, and again the signal from the tomographic image transmission] pulse control circuit 2 is added and the ultrasound A beam is fired.

A reflected signal is received. By repeating this operation one after another, a linear scan of the ultrasound beam is performed and a tomographic image is obtained. On the other hand, the switch control circuit 6 turns on all or many of the drive element selection switches 4,
The therapeutic transmission Noculus control circuit 1 applies a driving pulse to drive the transmitter corresponding to each arrayed vibrator. In this case, the ultrasonic beam 12 is focused at a predetermined depth with a predetermined beam diameter as shown in FIG. form 13. Switch control circuit 3 and tomographic image transmission nox control circuit 2. By controlling the therapeutic transmission pulse control circuit 1 as described above, it is possible to arbitrarily switch between the scanning ultrasound beam for obtaining an ultrasound tomographic image and the therapeutic ultrasound beam.
Treatment can be performed while observing the tomographic images by alternating the switching to the extent that the real-time nature of the ultrasonic tomographic images is not impaired.

The first-order case can be cited as an example of output switching that does not impair the real-time properties of ultrasonic tomographic images. In other words, the ultrasonic scanning time required to obtain one ultrasonic tomographic image is determined by the product of the time it takes for the reflected echo to return after one ultrasonic beam is emitted and the number of scanning lines. For example, if the depth of the object to be examined is 18 depths and the number of scanning lines is 128, the ultrasound scan time is approximately 52 m5.
It is ec.

Therefore, the output of the transmission pulse control circuit 2 for tomographic images between 32 m and yg (-) was sequentially applied to different ultrasonic transducer groups 5 one by one by the switch control circuit 3 to obtain one ultrasonic tomographic image. After that, in the next 527 B sec, the output of the therapeutic transmission pulse control circuit 1 is applied to the ultrasonic transducer 5, and the focal point 13 is
, and thereafter, in the same manner, the tomographic image transmission pulse control circuit 2
By alternating the output of the control circuit 1 and the output of the pulse control circuit 1, 15 ultrasonic tomographic images can be obtained per second without compromising the real-time properties of the ultrasonic tomographic images. Treatment can be performed using the focal point 13 of the ultrasonic beam for 0.5 seconds.In this way, the treatment transmission pulse control circuit 1, the tomographic image transmission pulse control circuit 2, and the switching control circuit 3 , drive element selection switch 4,
The ultrasonic beam generating means 20 is constituted by the transmitter 6 and the transmitter 6. 14 is a caliper control circuit, which moves the caliper 1 to a desired position in the ultrasonic tomographic image displayed on the cathode ray tube 15 of the television monitor 11, as shown in FIG.
6 and outputs a signal indicating the position of the caliper 13 in the ultrasonic tomographic image to the central processing unit (CPIJ) 17. Based on the signal indicating the position of the caliper 13, the central processing unit 17 controls each ultrasound transducer 2 to form a focal point 16 of the ultrasound beam at a position within the subject corresponding to the position of the caliper 13. Calculate the delay time for delaying the applied drive signal. The central processing unit 17 also controls the operation of each part of the ultrasonic diagnostic treatment apparatus, particularly the switching device control circuit 6 and the therapeutic transmission pulse control circuit 1. The timing of the operation of the tomographic image transmission pulse control circuit 2 is controlled.

Next, the operation of the ultrasonic diagnostic treatment apparatus having the above configuration will be described.

First, in order to confirm the lesion to be treated, by turning off a switch (not shown), only the output from the tomogram transmission pulse control circuit 2 is transmitted via the switch 4 to the ultrasonic vibrations in the ultrasonic glove 18. fal in Figure 2.
A linear scan is performed as shown in FIG. 3, and an ultrasonic tomographic image is displayed on the cathode ray tube 15 of the television monitor 11 via the reception delay line 9 and the signal processing circuit 10 based on the obtained reflected echoes as shown in FIG. . The ultrasound probe 18 is appropriately moved over the subject to confirm the lesion 19 as shown in FIG.

Next, a position signal is output from the caliper control circuit 14 by operating a joystick or the like (not shown).

As shown in FIG. 6, the lesion area 19i9 in the ultrasound tomogram
+ Position the caliper 16. While positioning the caliper 16, the caliper control circuit 14 also outputs a caliper 160 position signal to the CPU 17, and the CPU 17 focuses the ultrasound beam 16 on the lesion position within the subject corresponding to the position indicated by the caliper 16. so that it is formed.

A delay time for delaying the drive signal applied to each ultrasonic transducer 5 is calculated, and the calculation result is output to the therapeutic transmission pulse control circuit 1. The therapeutic transmission pulse control circuit 1 outputs a delay signal that excites each ultrasonic transducer 5 based on the calculation result.

After this, when the operator turns on a switch (not shown),
Transmission pulses are alternately sent from the therapeutic transmission pulse control circuit 1 and the tomographic transmission pulse control circuit 2 to the switching device, and the switching device control circuit 3 alternately switches the switching device between approximately 62 msgc and 62 msgc in accordance with this timing. and connect these to the ultrasonic transducer 5.
to be applied. Then, from the ultrasonic transducer 5, a linear scan as shown in Fig. 2 (α) and an electronic focus as shown in Fig. 2 (b+) are performed alternately every 32 mzgc. A sound beam is emitted.Then, 15 ultrasonic tomographic images are displayed on the TV monitor based on the reflected echoes from approximately 10 linear scans per minute (0.5 per minute). For a second, a focus 16 is formed on the lesion by the ultrasonic beam, and the lesion is treated.In this case, the thermal effect or destructive effect of the focus 13 depends on the number of ultrasonic transducers 5 to be driven and the transmitter. 6, the number of drives of the ultrasonic transducer 5 and the drive voltage may be appropriately determined depending on the condition of the lesion.

Above, one embodiment of the present invention has been described in detail.

This invention is not limited to the embodiments described above, and can be implemented with various modifications within the scope of the gist of the invention.

The switching operation of the switch 4 in the above embodiment is as follows.

Linear scanning for tomographic images and electronic focusing for treatment were performed alternately, but what would happen if electronic focusing could be performed while displaying ultrasound tomographic images without impairing the real-time nature of the ultrasound tomographic images? For example, the following pressure may be applied. That is, therapeutic electronic focusing is performed once every several linear (11) scans, and switching operations are performed so that 15 or more ultrasonic tomographic images can be obtained per second with this combination as one unit. . With this kind of switching operation, it is possible to obtain ultrasound tomographic images that do not flicker and smooth the body movements of the subject due to breathing, etc., and moreover, it is possible to obtain ultrasound tomographic images that do not flicker, and that allow for smoother body movements such as breathing of the subject. Therefore, accurate treatment can be performed without shifting the focus from the lesion site by one body movement.

Further, although the linear scanning method was used in the above embodiment, the present invention can be suitably implemented using an electronic sector scanning method or a mechanical scanning force method using a ring-shaped ultrasonic transducer.

〔Effect of the invention〕

According to the invention described in detail above, it is possible to emit therapeutic ultrasound that forms an ultrasound focus on the lesion site while displaying an ultrasound tomographic image that includes the lesion site, so that the irradiation position of the therapeutic ultrasound can be Ultrasonic treatment and diagnosis can be performed accurately while checking the effects of irradiation (12) and irradiation.

[Brief explanation of the drawing]

Fig. 1 is a schematic block diagram showing an embodiment of the present invention, Fig. 2 is an explanatory diagram showing an ultrasonic probe linearly scanning an ultrasonic beam, and Fig. 2 IAI is an illustration showing an ultrasonic probe that focuses an ultrasonic beam. FIG. 3 is an explanatory diagram showing an ultrasound glove, and FIG. 3 is an explanatory diagram showing a television monitor screen displaying an ultrasound tomographic image. DESCRIPTION OF SYMBOLS 1... Transmission pulse control circuit for treatment, 2... Transmission pulse control circuit for tomographic images, 6... Switching device control circuit, 4
... Drive element selection switch, 5... Ultrasonic transducer. 6... Transmitter, 7... Ultrasonic beam for tomographic images,
8...Receiver, 9...Delay line for reception, 10...
Signal processing circuit, 11...TV monitor, 12...therapeutic ultrasound beam, 16...ultrasonic focus, 14...
Caliper control circuit, 15... Braun tube, 16...
・Carrick-117...CPU, 1B...
Ultrasonic probe, 19... treatment area, 20...
Ultrasonic beam generation means. Agent Patent attorney Kensuke Chika (and 1 other person) (16)

Claims (1)

[Claims] (1) one ultrasound probe, a signal processing circuit and a television monitor for displaying an ultrasound tomographic image based on reflected echoes of the ultrasound beam emitted from the ultrasound probe;
An ultrasonic beam generating means including a switching means for switching between an ultrasonic beam for obtaining an ultrasonic tomographic image and an ultrasonic beam for treatment from an ultrasonic probe in real time. a control means for controlling the switching means to alternately and selectively switch and generate an ultrasound beam for obtaining an ultrasound tomogram and an ultrasound beam for treatment, and An ultrasonic diagnostic treatment device characterized by displaying an image and performing ultrasonic treatment at the same time. (21) Ultrasonic diagnosis according to claim 1, characterized in that the ultrasonic beam generating means is equipped with a switching device that causes the ultrasonic probe to generate only an ultrasonic beam for obtaining an ultrasonic tomographic image. Treatment device. +31 The ultrasonic beam generating means sets the caliper at a predetermined position in the ultrasonic tomographic image displayed on the TV monitor, based on the caliper position signal output from the caliper control circuit, which corresponds to the caliper position within the subject. 2. The ultrasonic diagnostic treatment apparatus according to claim 1, wherein the ultrasonic beam is generated from the ultrasonic probe so that an ultrasonic focus can be formed at a predetermined portion of the ultrasonic probe.