JPH0531420B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to an ultrasonic thermotherapy device for treating tumors by localized heating using ultrasonic waves.

[Technical background of the invention and its problems]

Regarding the treatment of malignant neoplasms, so-called cancer, surgical therapy, chemical therapy, radiotherapy, and immunotherapy have traditionally been carried out under the name of multidisciplinary therapy, but in addition to these therapies, there are also treatments that have recently received attention. One method that has been used is heat therapy (hypathermia). This treatment uses heating to take advantage of the fact that the lethal temperature of tumor cells is lower than that of normal cells, and as it is a non-invasive method, it is suitable for treating unresectable lesions. It is considered extremely effective. Thermal therapy is classified into whole body heating, local heating, and regional heating, and among these, ultrasound therapy is focused and irradiated to the deep tumor to selectively heat the tumor site. Local heating methods that perform this are seen as promising.

However, hyperthermia treatment using local heating methods has traditionally been carried out without confirmation that the tumor is being selectively heated, so the treatment is not effective and the evaluation of its effectiveness is unclear. There was a problem.

[Purpose of the invention]

An object of the present invention is to provide an ultrasonic thermotherapy device that can perform treatment while checking the area to be heated by ultrasonic waves.

[Summary of the invention]

In order to achieve the above object, the present invention provides an imaging ultrasound probe that transmits and receives ultrasound waves to obtain tomographic images inside a living body, and an imaging ultrasound probe that focuses and irradiates ultrasound waves onto a desired part of the living body. a heating ultrasonic probe for heating; a driving means for alternately supplying continuous wave and burst wave driving signals to the heating ultrasonic probe; means for detecting a region heated by the heating ultrasonic probe from the output of the imaging ultrasonic probe corresponding to a burst wave of ultrasonic waves emitted by a drive signal; and heating detected by the means. The present invention is characterized by comprising means for displaying information indicating the position of a region on a tomographic image obtained by a signal from the imaging ultrasound probe.

That is, the tumor site in the living body is heated by continuous wave ultrasound among the ultrasound waves emitted from the heating ultrasound probe. The burst wave of ultrasound is emitted so that the region heated by the heating ultrasound probe can be detected as two-dimensional positional information from the output of the imaging ultrasound probe. In this case, the detection of the heated region by the heating ultrasonic probe is more specifically based on the output of the imaging ultrasonic probe, the harmonic components of the ultrasound emitted by the heating ultrasonic probe, Alternatively, it is possible to perform this by detecting a signal component having a predetermined amplitude value or more in synchronization with emission of a burst wave of ultrasonic waves from a heating ultrasonic probe.

〔Effect of the invention〕

According to this invention, thermotherapy can be performed while confirming the region to be heated by heating ultrasound on a tomographic image of the inside of a living body. Therefore, it is possible to perform appropriate treatment with the heating ultrasonic waves correctly focused on the tumor site, and it is also easy to judge the therapeutic effect.

[Embodiments of the invention]

FIG. 1 shows the configuration of an ultrasonic thermotherapy device according to an embodiment of the present invention. A water bath 2 is provided in contact with the body surface of a living body 1, and an imaging ultrasonic probe 3 and a heating ultrasonic probe 4 are disposed within the water bath 2. The water bath 2 is used to match the acoustic impedance between the ultrasound probes 3 and 4 and the living body 1 and to suppress the temperature rise on the surface of the living body 1.

The imaging ultrasound probe 3 and the heating ultrasound probe 4 are supported by a probe position control device 5, and their positional states, for example, the living body 1
The angle with respect to the body surface, etc. is controlled. A position detector 6 is connected to the probe position control device 5 . The position detector 6 includes, for example, each ultrasonic probe 3,
4, each position of each probe 3, 4,
Detect mutual positional relationship (relative position).

The imaging ultrasound probe 3 is a B-mode system 7
At the same time, sector-type electronic scanning is performed to obtain tomographic image information inside the living body 1. Sector-type electronic scanning is a scanning method that is already well known in ultrasound diagnostic equipment, so a detailed explanation will be omitted. For example, when the imaging ultrasound probe 3 is composed of an array transducer, Specifically, the scanning circuit performs focusing and deflection scanning of ultrasound by driving each transducer through a delay circuit, and the signal from each transducer of the probe 3 is transmitted through the delay circuit. After extraction, processing such as amplification and detection is performed to obtain a B-mode image signal (tomographic image signal) 8
It is composed of a signal processing circuit that obtains the following.

On the other hand, the heating ultrasonic probe 4 has an acoustic lens attached to its tip, or has a concave tip shape, and the focal point of the emitted ultrasonic waves is determined by its position. There is. The heating ultrasonic probe 4 is supplied with driving signals alternately from a continuous wave generator 11 and a burst wave generator 12 via a switch 10 controlled by a clock pulse generator 9, so that the heating ultrasonic probe 4 is relatively energy-efficient. Continuous wave ultrasound waves and burst wave ultrasound waves with a large intensity are focused and irradiated onto a desired site within the living body 1, that is, a tumor site.

Clock pulse generator 9 also controls hot spot detection circuit 13. The hot spot detection circuit 10 receives a signal from the imaging ultrasound probe 3 as an input, and detects a hot spot within the living body 1, that is, a focal point of the heating ultrasound (heating site). Detection of this hot spot is
For example, the harmonic components of the ultrasound emitted by the heating ultrasound probe 4 are transmitted to the imaging ultrasound probe 3.
This is done by detecting the output of the

It is generally known that when ultrasound propagates through a medium (for example, tissue in a living body), the waveform becomes more distorted as the sound pressure increases. This is because the speed of sound in a medium depends on the magnitude of sound pressure, and the sound speed of a sound wave with a small sound pressure amplitude is C ₀ and the particle speed is V
Then, the sound speed C of a sound wave with a finite sound pressure amplitude is expressed as C=C ₀ +βV. That is, when V>0, C>C ₀ , and when V<0, C<C ₀ . Therefore, when the ultrasonic waves emitted from the ultrasonic probe propagate through a medium, they are distorted and harmonic components are generated. In hyperthermia, the heated region is irradiated with powerful ultrasonic waves, so it is in a state where such nonlinear phenomena are likely to occur. The hot spot detection circuit 13 utilizes such properties of ultrasonic waves to detect a heated region, that is, a hot spot, by detecting harmonic components.

FIG. 2 is a time chart showing the relationship among the timing pulses generated by the clock pulse generator 9, the drive signal supplied to the heating ultrasonic probe 4, and the operating state of the hot spot detection circuit 13. In FIG. 2, a is the waveform of a timing pulse, which operates the controlled circuit at the rising edge. b is a drive signal to the heating ultrasonic probe 4, which becomes a burst wave 23 during the period _t1 and a continuous wave 24 during the period _t2 . c is hot spot detection circuit 1
3, and is intermittently turned on and off as shown in the figure.

First, when the first timing pulse 21 is generated, the hot spot detection circuit 13 is turned on at the rising edge of this pulse. After time Δt, the burst wave driving signal 23 is supplied to the heating ultrasonic probe 4 via the switch 10, and the burst wave ultrasonic wave is emitted from the probe 4. The position of the heating ultrasonic probe 4 is set in advance by the probe position control device 5 so that the ultrasonic waves are focused in the vicinity of the tumor in the living body. By irradiating the tumor area, harmonics are generated as described above. Therefore, by receiving this harmonic with the imaging ultrasonic probe 3 and then detecting it with the hot spot detection circuit 13, the point of maximum amplitude of the harmonic component can be detected as a hot spot.

Next, at the rise of the second timing pulse 22, the hot spot detection circuit 13 is turned off, and a continuous wave drive signal 24 is supplied to the heating ultrasonic probe 4 via the switch 10, and from this probe 4 the tumor is detected. Continuous wave ultrasound waves are emitted that contribute to heating the body. Below, timing pulses 21, 2
The above operation is repeated every time 2 is generated.

In this way, the tumor region is heated by continuous wave ultrasound, and the burst wave ultrasound is emitted.
Hot spots are detected by detecting the harmonics generated at this time. The reason why burst wave ultrasound is used to detect hot spots is that when continuous waves are irradiated, harmonics are also continuously incident on the imaging ultrasound probe 3, so even if harmonics are detected, only 2 of the hot spots This is because dimensional position determination is impossible.

The hot spot detection circuit 13 detects the imaging ultrasonic probe 3 when the burst wave of ultrasonic waves is emitted from the heating ultrasonic probe 4 as described above.
The hot spot detection signal 14 is output at the timing when the harmonic component detected from the output of the hot spot has the maximum amplitude. This hot spot signal 14 is supplied to an adder 15 and is combined with the tomographic image signal 8 from the B-mode system 7. The output signal of the adder 15 is converted into a television video signal by an image processing device 16 using, for example, a digital scan converter, and then supplied to a CRT display (television monitor) 17. The image processing device 16 is supplied with the position information of the ultrasound probes 3 and 4 for imaging and heating from the position detector 6, and thereby the screen configuration of the image of the hot spot and the image of the tumor region, i.e. The relative positions of both images on the tomographic image are determined. As a result, on the screen of the CRT display 17, assuming that FIG. Is displayed. The hot spot image 32 may be displayed, for example, as a bright spot that is brighter than a normal image, or as a special color or a special pattern.

As described above, according to the present invention, information indicating the position of the hot spot, that is, the focal point of the heating ultrasound waves, is displayed on the tomographic image. Therefore, it is possible to perform thermal treatment while checking the area to be heated, and the therapeutic effect can be significantly improved.

In addition, since hot spots are detected from the output of the imaging ultrasound probe in this invention, even slight body movements or the effects of refraction or reflection of ultrasound may cause the relative difference between the heating ultrasound probe and the tumor site in the living body. Even if the position is shifted, the actual focal point of the heating ultrasonic waves, that is, the true hot spot, can be detected regardless of these influences, and the reliability of the display of the heating area can be greatly increased.

Furthermore, according to the present invention, a burst wave of ultrasound is emitted from the heating ultrasound probe in addition to the continuous wave of ultrasound for heating, and an imaging ultrasound probe corresponding to the burst wave of ultrasound is emitted from the heating ultrasound probe. Since hot spots are detected by detecting signal components such as harmonic components from the output, there is an advantage that two-dimensional position determination of hot spots is easy.

The present invention is not limited to the above-mentioned embodiments; for example, in order to detect a hot spot, a burst wave of ultrasonic waves emitted by a heating ultrasonic probe is used from the output of an imaging ultrasonic probe. Although harmonic components were detected in synchronization with the emission of
The power of the ultrasonic waves emitted from the heating ultrasonic probe is large, and the amplitude of the reflected waves is also large. Therefore, the components of the output of the imaging ultrasonic probe that exceed a predetermined amplitude value are similarly converted into burst wave ultrasonic waves. It is also possible to detect hot spots by detecting them in synchronization with the emission of . Further, in the embodiment, sector type electronic scanning is used to obtain a tomographic image, but other scanning methods such as linear type electronic scanning or mechanical scanning may be used. Furthermore, a method other than the method using an acoustic lens or the like may be used for focusing the ultrasonic waves from the heating ultrasonic probe. In addition, the present invention can be modified and implemented in various ways without departing from the scope of the invention.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing the configuration of an ultrasonic thermotherapy device according to an embodiment of the present invention, FIG. 2 is a time chart for explaining the operation of the embodiment, and FIGS.
b is a diagram showing an example of a display on a display in the same embodiment. 1... Living body, 2... Water bath, 3... Ultrasonic probe for imaging, 4... Ultrasonic probe for heating, 5... Probe position control device, 6... Position detector, 7... B mode System, 8...Tomographic image signal, 9...Clock pulse generator, 10...Switch, 11...Continuous wave generator, 12...Burst wave generator, 13...Hot spot detection circuit (heating ultrasonic wave generator) (focal point detection means), 14... hot spot detection signal, 15... adder, 16... image processing device, 17... CRT display.

Claims (1)

[Scope of Claims] 1. An imaging ultrasound probe that transmits and receives ultrasound waves to obtain tomographic images inside a living body, and a heating system that focuses and irradiates ultrasound waves on a desired part of the living body to heat that part. a heating ultrasonic probe; a driving means for alternately supplying continuous wave and burst wave drive signals to the heating ultrasonic probe; means for detecting a heating region of the heating ultrasound probe from the output of the imaging ultrasound probe corresponding to a burst wave of ultrasound emitted by the ultrasound probe; and a position of the heating region detected by the means. 1. An ultrasonic thermal treatment apparatus comprising: means for displaying information on a tomographic image obtained by a signal from the imaging ultrasonic probe. 2 The means for detecting the area to be heated by the heating ultrasonic probe is to convert the high frequency component of the ultrasound emitted by the heating ultrasonic probe from the output of the imaging ultrasonic probe into the heating ultrasonic probe. 2. The ultrasonic thermal treatment apparatus according to claim 1, wherein the ultrasonic thermal treatment apparatus detects the burst waves in synchronization with the emission of ultrasonic waves from the ultrasonic wave. 3. The means for heating the site with the heating ultrasound probe synchronizes a signal component of a predetermined amplitude value or more from the output of the imaging ultrasound probe with the emission of burst waves of ultrasound from the heating ultrasound probe. The ultrasonic thermal treatment device according to claim 1, wherein the ultrasonic thermal treatment device detects