JP2001161837A - Method for physical medical care treatment utilizing laser array hologram and its apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for electronic variable hologram to be utilized for a holography physical medical care treatment apparatus, which exhibits higher performance and more practical form, while the method shown in Japanese Patent Application No.61-120166 is merely abstract one. SOLUTION: A laser array hologram is utilized for a holography laser 15 in a holography physical medical care treatment apparatus. The laser array hologram or a semiconductor laser array variable oscillation hologram is shown in Japanese Patent Application No.10-74778 (applied by the inventor of the present invention). Although the laser array hologram is a multi-purpose apparatus, the functions thereof are utilized for physical medical care treatment in the present invention.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to medical technology, and relates to an improvement and development of Japanese Patent Application No. 61-120166 (Physical medical device utilizing holographic technology. Invention by the present inventor). Things.

[0002]

2. Description of the Related Art In the prior art, that is, in Japanese Patent Application No. 61-120166 (invention by the present inventor), the method of an electronic variable hologram used in physical medical equipment is abstract. there were. In addition, since a hologram used for this was assumed to be a transparent hologram, a complicated optical system was required. Here, the above conventional technology,
That is, Japanese Patent Application No. 61-120166 is summarized as follows. Holography can realize a three-dimensional real image. Computer-generated holograms are created using computer-generated holograms. This computer holography can freely create an image of a virtual object. Therefore, by using computer holography and transmitting electromagnetic waves, it is possible to freely form a focused real image inside the human body. The primary use of holographic physical medical devices is in hyperthermia for cancer. Cancer cells are juvenile cells and die at a temperature of 43 ° C. or higher. In contrast, normal cells are old cells and are more heat resistant than young cells. A method of killing cancer cells using this temperature difference is hyperthermia for cancer.
By using holography to focus on the cancer cells, only the cancer cells can be heated well with little heating of the surrounding cells. This is a holographic physical medical device. When this is used as a scalpel, if the affected part is cut off from the living body at a locally high temperature and then crushed and sucked out with a syringe, the operation can be performed without cutting the human body surface.

[0003]

The problem to be solved by the present invention is the above-mentioned conventional Japanese Patent Application No. 61-120.
While the method of the electronic variable hologram used for the physical medical device shown in No. 166 was abstract,
A more specific and practical form is required.

[0004]

Means for solving the above-mentioned problems of the present invention, that is, means for solving a more specific form of an electronic variable hologram, is a semiconductor laser array (a large number of semiconductor laser elements are arranged in a matrix in a matrix). Using a phase-controlled one of the electronically controlled one, the hologram-like pattern of the light and dark of the laser oscillation and stop of the semiconductor laser element is identified as a hologram, and the laser oscillation of the semiconductor laser element is reproduced light ( A “laser laser variable oscillation hologram” which is one type of an electronic variable oscillation hologram identified as a reference light) is used. This semiconductor laser array variable oscillation hologram is disclosed in Japanese Patent Application No. 1998 Patent Application No. 74778 (invention by the present inventor).

[0005]

BEST MODE FOR CARRYING OUT THE INVENTION A variable oscillation hologram of a semiconductor laser array, which will be hereinafter referred to as a "laser array hologram". By utilizing this laser array hologram, a practical laser array hologram physical medical device can be created. laser·
Using the array hologram, a real real image of the focus of the holographic laser is formed on the cancer cell nodule inside the human body whose position is specified by the diagnostic apparatus, and the cancer cell nodule is heated. When heating a cancer cell mass, a holographic laser can image multiple focal points at the same time, so that cancer can be treated efficiently. When a laser array hologram is used as a scalpel, a focused real image of a holographic laser is formed on the affected part inside the human body specified by the diagnostic device, and the affected part is separated from the living body at a local high temperature. If crushed and then sucked out with a syringe, surgery can be performed without cutting through the human body surface. In addition, when the crushed diseased part is small, spontaneous outflow is also possible.

[0006]

【Example】

Embodiment 1: Laser array hologram cancer hyperthermia treatment method and apparatus. A laser array hologram, that is, an array of semiconductor laser elements 12 arranged in a matrix and controlled by a control circuit 13, and an interference fringe pattern formed by transmitting and stopping the phase-controlled laser 11 emitted from each element 12 is identified to the hologram 1. Holographic physio-medical device, characterized in that the device obtained is used as a holographic laser generator, and the device is used. This holography
Lasers are used for hyperthermia of cancer. Here, the principle of holography is summarized and described. In FIG. 1A, when the object light that is the light from the object point B and the oblique reference light from the reference light source A interfere with each other, the peaks of the waveforms of the object light and the reference light overlap each other. The maximum appears. Therefore, when the local maximum is recorded on the film, the film becomes transparent. This is the transparent portion 3 of the interference fringe of the hologram 1, and information (maximum) of the phase of the object light is recorded on the transparent portion 3. Of course, it is also information (maximum) of the phase of the reference light. Next, when this hologram (dry plate) 1 is irradiated with reference light (reproduction light), a spherical wave 4 is generated from each point 3 of the transparent portion, and the combined wave forms the next wave front. At this time, since the phase of the spherical wave 4 emitted from each point 3 includes both the phase from the object point B and the phase from the reference light source A,
The combined wave becomes a wave from both points and becomes two waves 5 and 6. Therefore, not only the wave 6 from the reference light source A but also the wave 5 from the object point B is generated. As a result, a virtual image B ′ of the object point B is reproduced. However, the reproduced image of the object point B includes a virtual image B ′ and a real image. In a normal hologram of a stereoscopic photograph, a virtual image B 'is reproduced at the position where the original object point B was, and a real image is reproduced at a position which is angularly shifted by twice the incident angle of the reference light. Next, in computer holography, if a hologram of an arbitrary virtual object is calculated by a computer and its interference fringe pattern is created, a three-dimensional real image of the virtual object can be realized by irradiating the hologram with reproduction light. . That is, the equivalent of the hologram of the virtual object shown above can be realized by the interference fringe pattern of the blinking of each laser element 12 in which a large number of laser elements 12 of the semiconductor laser array are arranged in a matrix. In this case, assuming that the laser oscillation of each laser element 12 is “point” and the laser stop is “extinction”, the point corresponds to the transparent part 3 of the conventional ordinary hologram,
The destruction corresponds to an opaque portion, and the interference fringe pattern formed by the combination serves as a hologram function and also serves as a reproduction light generating device. In this case, the laser element 12
Oscillates in a radially expanding spherical wave 11 (in practice, it is radial and combines at a more advanced position), so that the combined wave of the laser from each laser element 12 forms the next wavefront The result is holography as a whole. Using the laser array hologram described above, a real image of the focus of the holographic laser from a wide angle S is formed on the cancer cell nodule 19 inside the human body whose position has been specified by the diagnostic device, thereby forming the cancer cell nodule 19. Heat. Cancer cells are immature cells and are weak to heat and die at about 43 ° C. In contrast, normal cells that are old cells are 43
It does not die at degree C. It is cancer hyperthermia that uses this temperature difference to treat cancer. Since the irradiation is performed from the wide angle S, the degree of heating rapidly decreases at a position distant from the focal point, so that the device has few side effects in principle. Further, when heating the cancer cell nodule 19, a plurality of focal points can be imaged simultaneously with the holographic laser, so that cancer can be treated efficiently.

Embodiment 2: A scalpel method using a laser array hologram and an apparatus therefor. A laser array hologram, that is, an array of semiconductor laser elements 12 arranged in a matrix and controlled by a control circuit 13, and an interference fringe pattern formed by transmitting and stopping the phase-controlled laser 11 emitted from each element 12 is identified to the hologram 1. Holographic physio-medical device, characterized in that the device obtained is used as a holographic laser generator, and the device is used. The resulting holographic laser is used for the scalpel. Laser array
When a hologram is used as a scalpel, a focused real image of a holographic laser is formed on the diseased part 20 inside the human body whose position has been specified by the diagnostic device, and the diseased part 20 is separated from the living body at a locally high temperature and then crushed. Suction with a syringe allows surgery without cutting through the human body surface. When the crushed diseased part 20 is small, natural outflow is also possible.

[0009]

According to the method described above, a practical laser array hologram physical medical device can be manufactured. When this device is used for hyperthermia of cancer, a cancer cell nodule 1 inside the human body whose position is specified by the diagnostic device is used.
9, a large number of holographic laser focal real images are formed at the same time, and the cancer cell nodules 19 are heated to efficiently treat cancer. When used as a scalpel, surgery can be performed without opening the surface of the human body. Since the holographic laser 15 in these devices emits light from a wide angle S, the device has in principle fewer side effects.

[Brief description of the drawings]

FIG. 1 is a sectional view showing the principle of holography.

FIG. 2 is a sectional view showing the principle of diffraction by a slit.

FIG. 3 is a cross-sectional view showing a portion of a variable oscillation hologram of a semiconductor laser array.

FIG. 4 is a cross-sectional view of a laser array hologram physical medical device.

[Explanation of symbols]

1 ...... Dry plate. 2 The maximum of the standing wave (hyperbola). 3 ...... The transparent part of the dry plate. 4. Wavefront of spherical wave. 5 Reproduction waves. 6 ……… Illumination wave (reference wave). 7 ……… Screen. 8 ...... Slit. 9 …… Ray. 10 The traveling direction of the wavefront. 11 ...... Wavefront. 12 ……… Semiconductor laser element. 13 Control circuit layer. 14 ...... Power line layer. 15 holographic laser. 16 ...... Real holographic image. 17 ... Structure. 18 ...... Cross section of the human body. 19 ...... Cancer cell nodule. 20 ...... The affected area. 21 ... Bet. A Reference light source A. B ……… Object point B. B '... A virtual image of the object point B. S: The azimuth angle of holographic laser irradiation.

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[Procedure amendment]

[Submission date] February 28, 2000 (200.2.2
8)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Brief description of drawings

[Correction method] Change

[Correction contents]

[Brief description of the drawings]

FIG. 1 is a sectional view showing the principle of holography.

FIG. 2 is a sectional view showing the principle of diffraction by a slit.

FIG. 3 is a cross-sectional view showing a portion of a variable oscillation hologram of a semiconductor laser array.

FIG. 4 is a cross-sectional view showing a holographic real image by a semiconductor laser array variable oscillation hologram.

FIG. 5 is a cross-sectional view of a laser array hologram physical medical device.

[Explanation of Signs] 1 ...... Dry plate. 2 The maximum of the standing wave (hyperbola). 3 ...... The transparent part of the dry plate. 4. Wavefront of spherical wave. 5 Reproduction waves. 6 ……… Illumination wave (reference wave). 7 ……… Screen. 8 ...... Slit. 9 …… Ray. 10 The traveling direction of the wavefront. 11 ...... Wavefront. 12 ……… Semiconductor laser element. 13 Control circuit layer. 14 ...... Power line layer. 15… Holographic laser. 16 ...... Real holographic image. 17 ... Structure. 18 ...... Cross section of the human body. 19 ...... Cancer cell nodule. 20 ...... The affected area. 21 ... Bet. A Reference light source A. B ……… Object point B. B '... A virtual image of the object point B. S: The azimuth angle of holographic laser irradiation.

Claims (6)

[Claims] 1. A laser array hologram, that is, an array of semiconductor laser elements arranged in a matrix and controlled by a control circuit, and an interference fringe pattern formed by transmitting and stopping a laser whose phase is controlled and emitted from each element is identified in the hologram. A method for holographic physical medicine, wherein the apparatus is used as a holographic laser generator. 2. The method according to claim 1, wherein the holographic laser is used for hyperthermia of cancer. 3. The holographic physical medical method according to claim 1, wherein a holographic laser is used as a scalpel. 4. A laser array hologram, that is, an array of semiconductor laser elements arranged in a matrix and controlled by a control circuit, and an interference fringe pattern formed by transmitting and stopping a laser whose phase is controlled and emitted from each element is identified in the hologram. A holographic physical medical device characterized in that the device obtained is used as a holographic laser generator. 5. The physical medical device according to claim 4, wherein the holographic laser is used for hyperthermia of cancer. 6. The holographic physical medical device according to claim 1, wherein a holographic laser is used as a scalpel.