JPS62277971A - Physical remedy apparatus utilizing holography technique - 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] 3. Detailed Description of the Invention The present invention utilizes holography technology that can expand information in three-dimensional space, and through the geometric expansion of its wave energy, This invention relates to a medical device that uses a method of imparting energy to a group of material particles and thereby confining and moving the material.

The technical method underlying the present invention is detailed in Japanese Patent Application No. 59-123630 entitled "Method for imparting energy to matter using holography technology and apparatus therefor". The technology will be summarized below, and the parts necessary for the present invention will be described in particular. For the sake of simplicity, electromagnetic waves and holography will be described, but basically the same applies to acoustic holography.

First, regarding holography itself, it is as follows. Holography technology, invented in 1948 by British scientist David Gabor, can create three-dimensional stereoscopic images. This three-dimensional image includes a virtual image and a real image, but the real image is more useful here. That is, holography using laser light can realize a real image of a standing tree in space. However, in addition to this, if a laser (electromagnetic wave with a short wavelength) that passes through an object is used, a three-dimensional real image can also be realized in a three-dimensional area within the object.

Second, as a technology that further develops the first holography technology, there is a method of applying energy to a substance using the ``holography technology''.

The 0-division, progressive, multiple, and rice shells described in the section ``Divide-progressing multiple rice shells'' shown in ``And its device'' have four functions: light film - multiple rice shells - progressive multiple light shells → It develops into a splitting and progressive multiple light shell.Masu rice shell 2 is like a hollow pinbong ball made of a collection of light focal points 1 using holography technology. The celluloid part is like a shell of light made of a collection of light focal points 1. Figure 1 shows its cross section, and the shell has a thickness d and a diameter of a rice shell 2. Recently, when a group of material particles 3 are put inside the rice husk 2, an explosion and implosion phenomenon as shown in Fig. 2 occurs.When the 0 particles 3 touch the rice husk, the particles 3 are heated.Then, due to the heating, the particles 3 is accelerated;
Approximately half of it explodes 4 towards the outside, and the remaining half implodes 5 towards the inside. The zero-order multi-light film, which allows inertial confinement of the material particle group 3 by this method, is a method for improving the efficiency of rice husks. As shown in Figure 3, the first light shell Kl
1/2 of the particles come out. In the second light shell, 1/2 of the total particles, that is, 1/4 of the particles, appear outside of 2. Below 9, similarly, 1/2 of the total particles appear outside the 0th light shell KO. coming out. Therefore, when n-lo, the number of particles exiting the multiple light film is 1/2°'=1/1.024 of the total. Similarly, when n = 20, it is about 1/1,050,000, and when n = 30, it is about 10 (i7° 1/3,000,000. The sixth-order progressive multilayer rice shell, which can confine particle groups inside, is a method to improve the efficiency of the multilayer film.As shown in Figure 4, the outside of the n-th light shell Kn of the multilayer film is nith + I rice husk Kn
+1 is generated and continuously moved inward to the position of the n-th light shell Kn. Then, the n+l rice husk Kn
Approximately 1/2 of the material particles between +1 and the n-th light shell Kn fit inside 6 Similarly, the n-th light shell Kn is
Move to the position of light shell Kn-1 so that 1 in the first light shell reaches the 0th light shell KO and disappears. This is a advancing multiple rice shell, and if the value of n, the advancing speed of the rice shell, etc. are appropriate, the material particles 3 can be almost completely confined inside it.

Next, the dividing progressive multiple rice husk is a method of stabilizing the progressive multiple rice husk.

As shown in Figure 5, the internal pressures Q1 and Q2 of material particles are often not the same, so if left as is, the fluctuations will become large and the particles will scatter explosively. Divide the progressively multiple rice husks into several units,
The splitting multiple rice husk is made by varying the confining pressure for each splitting unit in response to each pressure Q. By this method, the entire optical film can be kept in shape, so that material particles can be stably packed inside it. Here, this multiple light film (abbreviation for splitting progressive multiple rice shell)
The same applies below) uses a laser, so it naturally involves heating.

Hereinafter, the present invention will be described with reference to embodiments, in which the holographic technology is used to perform hyperthermia therapy for cancer (generally heating from 42 degrees Celsius to 44 degrees Celsius), and how cancer cell tissue is crushed and killed. can do.

FIG. 6 illustrates a method of heating a cancer cell set w110 inside a person t*9 using holography technology. If the reproduction light 6 is irradiated onto the hologram 8, the diffracted light 7
The focal point P is imaged through.

This is possible when the electromagnetic waves used are transparent to the human body. Therefore, point P can be heated to kill cancer cell tissue. At this time, in the figure, the light flux gathers at the angle θ, so if θ is large, P
Areas other than the focal point are not heated strongly, so normal cells located outside the focal point are safe. here,
There are two methods for heating the entire cancer cell tissue.
The real image 11 is made to have the same size as the cancer cell tissue 10 and is superimposed on the cancer cell tissue 10. In this way, cancer cell tissue can be heated and killed.

Next, since holographic real images can be realized at multiple locations simultaneously, multiple cancer cell tissues 10 can be heated and killed at the same time with one device, as shown in FIG. 8. Here, it is a medically confirmed fact that young cells that have just divided have a low resistance to heating by laser light, whereas old cells have a high resistance, and cancer cells that have just divided have a low resistance to heating by laser light. Because they are young cells, they are more likely to die when heated by laser light than old normal cells.Therefore, the above method can selectively target cancer cells within the human body without causing side effects to normal cells. It is useful as a method to kill them.

Next, in the case of the method using multiple rice husks, it is possible to not only heat the rice husks as in the above method, but also compress them, so that cancer cell tissue can be killed more effectively. FIG. 9 illustrates this. The same figure (a) is
Cancer cell group I! By imaging the multiple rice husk 12 inside the rice husk 10 and then successively reducing it, the cancer cell tissue inside the multiple rice husk 12 is compressed and destroyed as shown in 21(b). , and can be killed by heating.In other words, from the state in which cancer cell set 1!tlo and surrounding normal cells are in direct contact as shown in figure (a), to the state shown in figure (b), After separating the cancer cells and reducing their volume, the cancer cells can be heated more effectively to kill them more effectively. In some cases, as shown in Fig. 10, it is possible to image a plurality of multiple rice husks 12 inside and compress and heat them simultaneously or sequentially.Therefore, the above-mentioned multiple rice husks can be used. This method is useful for selectively killing cancer cells.

Next, the relationship between the holography imaging device and the cancer cell tissue site measuring device will be described.

No. 1112I shows a situation in which a laser and a holographic real image are focused on the cancer cell tissue 10 inside the human body and heated. At this time, GJal cell group v & 1 inside the human body
It is necessary to measure the area of 0. This site measurement method includes a method using a conventionally known measurement method and a method using a holography measuring device. By connecting this cancer cell tissue site measuring device and the holography-imaging devices of the two methods described above through a computer and interlocking them, holography-imaging can be performed at an appropriate position at all times.

Therefore, when the linked devices are used, even if the patient moves a little, holographic imaging can be performed following the change in position of the patient. Therefore, since cancer treatment can be automated, continuous treatment for a long period of time becomes possible.

The holographic medical device described above works not only for cancer treatment on sheep, but also as other thermal treatment devices. Moreover, in particular, the method using multiple rice husks is capable of compressing and destroying the affected area in addition to simply heat therapy, so it can be applied to many treatments such as stone crushing.

[Brief explanation of the drawing]

FIG. 1 is a cross-sectional view of the single point. FIG. 2 is a cross-sectional view of a single-layer structure that causes an implosion effect on material particles, FIG. 3 is a cross-sectional view of a multilayered rice shell, and FIG. 4 is a crosssectional view showing a portion of a traveling multilayered light film. FIG. 5 is a cross-sectional view showing a portion of the selectively progressing multiplexed light film; 612I is a cross-sectional view showing a state in which the focal point P of the laser beam is imaged using holography on cancer cell tissue inside the human body; Figure 7 is a cross-sectional view showing a method of heating the entire cancer cell tissue, (a) shows a method using scanning of the focal point P, and (b) shows a holography-real image and a cancer cell tissue. Fig. 8 is a cross-sectional view showing a state in which images are simultaneously focused on multiple cancer cell tissues inside the human body, and Fig. 9 is a cross-sectional view showing a state in which multiple cancer cells are overlapped three-dimensionally. Heating the cell tissue Vi, +1! [J (A) is a cross-sectional view showing a state in which multiple rice shells are imaged to surround the entire cancer cell tissue, and (B) is a cross-sectional view showing a state in which multiple rice shells are imaged to surround the entire cancer cell tissue. 10 is a cross-sectional view showing a state in which the cancer cell tissue inside is compressed and heated by successively shrinking the
The figure images multiple rice shells inside a cancer cell tissue.
Figure 11 is a cross-sectional view showing a state in which cancer cell tissue is compressed and destroyed and heated to be killed. The sectional view shown. 1...focal point, 2...light film, 3...
...Material particle group, 4...Direction of explosion, 5
...The direction of implosion. 6... Reproduction light, 7... Diffracted light, 8.
...Hologram, 9...Cross section of human body,
10... Cancer cell tissue, 11... Real holographic image, 12... Multiple rice shells (abbreviation for division progressive multiple light shells), 13...・Direction of compression, 14... units, d... minute thickness, D... diameter, r... radius of light film. Ql, Q2...Respectively, internal pressure, θ...
...Angle, P...Focus, Ki (i=
0~n+1)...i-th rice shell. Fig. 1 Ko 2 Fig. Stem 3 Notebook 4 Fig. 5 Leap and tun name 6 Curse 7th ward (a) (b) 8th flash

Claims (1)

[Claims] 1. A device that uses holography technology to selectively apply heat or pressure to cell tissues inside or outside a living body to treat diseases. 2. The treatment device according to claim 1, which utilizes electromagnetic holography. 3. The device 4 according to claim 2, which uses electromagnetic waves that can penetrate the living body; and the device according to claim 1, which uses acoustic holography technology. 5. The apparatus according to claim 2 or 3, which uses a normal holographic real image. 6. The device according to claim 2 or 3, which utilizes a divisional progression multiple light shell. 7. The apparatus according to claim 4, which utilizes a normal acoustic holographic real image. 8. The device according to claim 4, characterized in that it utilizes a split progression multiple sound shell. 9. The device according to claim 1, 2, 3, 5, or 6, characterized in that it performs hyperthermia therapy for cancer. 10. Claims 1, 2, 3, 4, 5, 6, 7, or 8, characterized in that compression destruction of cancer cell tissue is performed. Apparatus described in section. 11. The device according to claim 1, 4, 6, 7, or 8, which performs in-vivo stone crushing.