JPH08215324A - Treatment device equipped with small x-ray tube - Google Patents

Abstract

PURPOSE: To insert the insertion tube of a small X-ray tube to a prescribed part with high rectilinearity and certainty by fixing the small X-ray tube on the prescribed part of the human body with a supporting member, inserting a sheath to the human body by reinforcing by the insertion of a solid bar and inserting the insertion tube to the sheath after extracting the solid bar. CONSTITUTION: Reinforcement is performed by inserting the solid bar to the inside of the sheath 13. The sheath 13 set in such a state is inserted to a living body 5 so as to drive in the terminal part of the solid bar. The tip part of the sheath 13 is suspended by bringing it into contact with a defective part 19, or inserting it to the inside, thence, the solid bar is extracted from the sheath 13, and only the sheath 13 is left in the living body 5. Thence, the small X-ray tube 11 is fixed on the head of the living body 5 with the supporting member 12. Thence, the insertion tube 20 extending from the small X-ray tube 11 in the longitudinal direction of the sheath 13 is fixed by inserting it so as to make the longitudinal direction coincide.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a compact X-ray for performing treatment by locating a small X-ray source inside or in the vicinity of a tumor in a living body to be treated, and irradiating only the lesion with X-rays. With regard to a treatment device provided with a ray tube, in particular, a small X-ray tube can be reliably fixed to a predetermined part of the human body, and an insertion tube that guides the X-ray generation source to a diseased part in a living body can be inserted straightly.
Further, the present invention relates to a treatment apparatus equipped with a small X-ray tube capable of varying the dose distribution of X-rays applied to the affected area.

[0002]

2. Description of the Related Art A conventional compact X-ray tube 8 used for this type of treatment is an electron gun 2 for generating an electron beam 1 as shown in FIG.
An accelerator 3 for accelerating the electron beam 1 generated from the electron gun 2, a target 4 serving as an X-ray generation source by irradiating the electron beam 1 accelerated by the accelerator 3, and the target 4 And a small-diameter insertion tube 7 to be inserted into the living body 5 in order to position the target 4 in the affected portion 6 to be treated in the living body 5 or in the vicinity thereof. Reference numeral 10 indicates a power cable for supplying electric power to the small X-ray tube 8.

In order to treat the affected area 6 in the living body 5 using such a small X-ray tube 8, first, the small X-ray tube 8 is positioned with the insertion tube 7 facing the head of the living body 5, for example. , The entire small X-ray tube 8 is moved in the direction of arrow A, and the insertion tube 7
The insertion tube 7 is inserted into the living body 5 so that the target 4 fixed to the tip of the subject is located inside or near the affected area 6 to be treated, for example, a tumor. After the insertion tube 7 is inserted into the living body 5 and reaches the affected area 6, electric power is supplied to the small X-ray tube 8 via the power cable 10.

Then, an electron beam 1 is generated from the electron gun 2 by the supply of this electric power, and the electron beam 1 is accelerated as it passes through a hole formed at the center of the accelerator 3. The acceleration of the electron beam 1 is performed by creating a potential difference between the electron gun 2 and the accelerator 3. At this time, since it is impossible to apply a high voltage to the target 4 inserted into the living body 5, a high voltage is applied to the human body.
Then, the potential of the accelerator 3 may be set to zero potential, and the potential of the electron gun 2 may be set to a negative potential. In this way, the electron beam 1 accelerated by the potential difference between the electron gun 2 and the accelerator 3 is
The target 4 is irradiated through the hollow portion inside the insertion tube 7. By irradiating the target 4 with the electron beam 1, X-rays are generated from the target 4, and the affected area 6 is irradiated with X-rays to perform treatment. In this case, the X-ray dose applied to the affected area 6 attenuates as the distance from the target 4 increases. Since this dose attenuation rate varies depending on the energy of X-rays, by appropriately selecting the energy of the X-rays to be irradiated, the normal cells outside the affected area 6 can be seen from the target 4 inserted into the living body 5. Exposure can be prevented. As such a small X-ray tube, there is one described in Japanese Patent Publication No. 6-500661.

[0005]

However, in such a conventional small X-ray tube, damage to the living body 5 when inserting the target 4 which is an X-ray generation source into the living body 5 is made as small as possible. For this reason, the insertion tube 7 having the target 4 fixed to the distal end thereof needs to have an outer diameter of, for example, 3 mm or less. On the other hand, since the electron beam 1 generated by the electron gun 2 and accelerated by the accelerator 3 is passed through the inside of the insertion tube 7, the inner diameter of the insertion tube 7 needs to be, for example, 2 mm or more. Therefore, under these conditions, the wall thickness of the insertion tube 7 was 0.5 mm or less. However, the wall thickness is 0.5 mm
The insertion tube 7, which is a hollow tube described below, has low mechanical strength and may be bent when it is inserted into the living body 5. Since the electron beam 1 makes a linear motion in the insertion tube 7, when the insertion tube 7 is bent, the electron beam 1 collides with the wall of the insertion tube 7 and the electron beam 1 does not reach the target 4. Therefore, X-rays are not generated from the target 4 and the affected area 6 cannot be treated.

Further, in the small X-ray tube 8 having the structure shown in FIG. 8, since the X-ray generated from the target 4 is directly emitted to the outside, the dose distribution of the X-ray cannot be changed and is supplied. Only X-rays with a predetermined dose distribution depending on the required power and size can be emitted. However, the shape of the tumor or the like in the affected area 6 to be treated is not constant, and there are large tumors and small tumors. Large tumors are irradiated with a large dose of X-rays, and small tumors are irradiated. It is desirable to change such as irradiating a low dose of X-ray. However, in the conventional small X-ray tube 8 that can only emit X-rays having a certain dose distribution, there are tumors that cannot be completely treated, and it may not be possible to sufficiently cope with various affected areas. In the conventional small X-ray tube, the means for securely fixing the small X-ray tube to a predetermined part of the human body has not been sufficiently disclosed.

Therefore, the present invention addresses such problems and can reliably fix a small X-ray tube to a predetermined part of the human body.
Further, the present invention provides a treatment apparatus equipped with a small X-ray tube that can insert an insertion tube that guides the X-ray generation source to a diseased part in a living body with good straightness and can change the dose distribution of X-rays that irradiate the diseased part. The purpose is to do.

[0008]

In order to achieve the above-mentioned object, a treatment apparatus equipped with a small X-ray tube according to the present invention includes an electron gun for generating an electron beam and an electron beam generated by the electron gun. An accelerating body that accelerates, and a target that becomes an X-ray generation source by irradiating an electron beam accelerated by this accelerating body,
A small X-ray tube having a small diameter insertion tube that is fixed to the distal end of the target and is inserted into the living body in order to position the target inside or near the affected area to be treated in the living body A metal member which is provided with a support member for fixing the small X-ray tube to a predetermined part of the human body, and which is inserted into the living body in advance to guide the insertion of the insertion tube of the small X-ray tube into the living body. A sheath is added, and the sheath has an outer diameter substantially equal to the outer diameter of the insertion tube. When the sheath is inserted into a living body, the sheath is inserted into the sheath for reinforcement, and after the sheath is inserted, the sheath is removed from the sheath. It is made by adding a solid rod.

The support member moves relative to the fixed frame, which serves as a base member for fixing the small X-ray tube to a predetermined part of the human body, and the fixed frame for moving the small X-ray tube to an arbitrary position. It may have a movable frame made possible.

Further, the support member may support the small X-ray tube so as to be movable in the front-rear direction with the insertion tube inserted into the inside of the sheath.

The outer surface of the sheath may be entirely coated with a biocompatible material.

[0012]

In the treatment apparatus having the small X-ray tube configured as described above, the small X-ray tube is fixed to a predetermined part of the human body by the support member and has an outer diameter substantially equal to the outer diameter of the insertion tube. The solid rod is inserted into the inside of the sheath to reinforce it when inserting the metal sheath for guiding the insertion of the insertion tube into the living body, and is removed from the sheath after the sheath is inserted. By inserting the insertion tube into the sheath in this state, the insertion tube is inserted into the living body by using the sheath as a guide, and further the small X-ray tube is inserted into the sheath by the support member. It operates so as to movably support in the front-rear direction in the state of being kept. As a result, the small X-ray tube can be reliably fixed to a predetermined part of the human body, and the target, which is the source of the X-ray generation, can be fixed to the distal end portion and the insertion tube for guiding to the affected part in the living body can be inserted straightly. The dose distribution of the X-rays applied to the affected area can be made variable.

[0013]

Embodiments of the present invention will now be described in detail with reference to the accompanying drawings. FIG. 1 is a schematic configuration diagram showing an embodiment of a treatment apparatus including a small X-ray tube according to the present invention. The treatment device provided with this small X-ray tube is
For example, an X-ray generation source is located inside or near the tumor and X-rays are irradiated only to the affected area for treatment.
As shown in FIG. 3, the small X-ray tube 11 and the supporting member 12 are provided, and a sheath 13 and a solid rod (not shown) are further added.

The small X-ray tube 11 is for inserting the X-ray source into the living body 5 and irradiating the affected area with X-rays.
As shown in FIG. 2, an electron beam 1 is provided inside the box body 14.
5, an electron gun 16 for generating an electron beam 5, an accelerator 17 for accelerating an electron beam 15 generated by the electron gun 16, and an accelerator 1
The target 18 which is an X-ray generation source by irradiating the electron beam 15 accelerated by 7 and the target 18 is fixed to the tip part and the target 18 is placed inside or near the affected part 19 to be treated in the living body 5. It has a small diameter insertion tube 20 to be inserted into the living body 5 for positioning. In FIG. 2, reference numeral 10 indicates a power cable for supplying power to the small X-ray tube 11.

The electron gun 16 is, for example, 1 μA to 1 mA.
The electron beam 15 is generated by, for example, a hot cathode electron gun or a photocathode electron gun is used to adjust the temperature of the cathode of the hot cathode electron gun or to adjust the amount of light applied to the cathode of the photocathode electron gun. By adjusting, the generated current is controlled. The power for driving the heater for heating the hot cathode type electron gun or the light source of the light for irradiating the photocathode type electron gun and the power for keeping these electron guns at a constant potential are supplied through the power cable 10. It is supplied from a power supply device (not shown) via the power supply device.

The accelerating body 17 accelerates the electron beam 15 generated from the electron gun 16 with a potential difference in the range of, for example, 10 to 90 KV, and has a hole for allowing the electron beam 15 to pass therethrough at the center thereof. ing. The acceleration of the electron beam 15 is performed by creating a potential difference between the electron gun 16 and the accelerator 17. At this time, the target 18 to be inserted into the living body 5
Since it is impossible to apply a high voltage to the human body because it is impossible to apply a high voltage to the human body, if the potentials of the target 18 and the accelerator 17 are set to zero potential and the potential of the electron gun 16 is set to a negative potential, Good. For example, the target 18 and the accelerator 17 are set to 0V potential, and the electron gun 16 is set to -10 to -90K.
The potential of V is kept. The electrons in the electron gun 16 excited by heat or light are accelerated by the potential difference between the electron gun 16 and the accelerating body 17, and pass through a hole formed in the center of the accelerating body 17 to be described later. The target 18 is irradiated.

The target 18 serves as an X-ray generation source that generates X-rays by being irradiated with the electron beam 15 accelerated by the accelerating body 17, and the irradiated electrons are absorbed by the target 18. The kinetic energy of electrons is emitted as braking X-rays. And the insertion tube 2
0 is for fixing the target 18 to the distal end and inserting the target 18 into the living body 5 in order to position the target 18 in or near the affected area 19 to be treated in the living body 5,
For example, the outer diameter is 3 mm or less and the inner diameter is a small diameter tube of 2 mm or more. Its length is set to an appropriate dimension in accordance with the depth of the affected part 19.

The supporting member 12 is the small X-ray tube 1 described above.
1 for fixing to a predetermined part of the human body, for example, the head. As shown in FIG. 3, for example, a ring-shaped fixing frame 12a formed so as to surround the periphery of the head, and a small X-ray tube 11 And an arch-shaped movable frame 12b for moving the carriage to an arbitrary position. The fixed frame 12a is
The base member is fixed to a predetermined part of the human body, and is composed of a ring member having a diameter larger than the circumference of the head of the human body (5) shown in FIG. A fixing screw (not shown) provided on the human body is used to fix the skull of the human body. The movable frame 12b is for moving the small X-ray tube 11 to an arbitrary position, and is a human body (5) shown in FIG.
3 is composed of an arch member which draws an arc of a half circle higher than the top of the head of FIG. 3, and both ends of the arch member slidably engage with each other on the fixed frame 12a.
As shown in FIG. 5, the entire movable frame 12b is rotatable about the central axis 21 of the fixed frame 12a as indicated by arrows C and D. As shown in FIG. 4 (a), the engagement structure has the above-mentioned structure with respect to the fixed frame 12 a having a tongue piece 22 having an inwardly protruding cross-sectional shape and protruding inwardly at the upper side. The flat plate-like end plates 23 provided at both ends of the movable frame 12b are engaged and slid, and a set screw 24 provided at a part of the end plate 23 is engaged.
Thus, the rotation in the directions of arrows C and D shown in FIG. 3 is fixed.

As shown in FIG. 1, a mounting rail 25 for mounting the small X-ray tube 11 to the movable frame 12b is provided at one location of the movable frame 12b. The mounting rail 25 serves to mount the small X-ray tube 11 on the support member 12, move the small X-ray tube 11 in the front-rear direction, and change the position along the arc of the movable frame 12b. As shown in FIG. 3, it is a bar material having an axis toward the center O of the fixed frame 12a, and 1 / on one side surface of the movable frame 12b.
It is slidably engaged by utilizing a concave groove 26 formed in an arc shape of four circles. As shown in FIG. 4 (b), the engaging structure has a short arc shape protruding from the mounting rail 25 to one side with respect to the groove 26 having the neck portion at the opening of one side surface. The engaging member 27 formed on the above is engaged and slid, and the movement in the directions of arrows G and H is fixed by a set screw 28 provided on a part of the engaging member 27 as shown in FIG. It has become. As a result, the mounting rail 25 can be moved or fixed in the directions of arrows G and H along the arc of the movable frame 12b around the center O of the fixed frame 12a in FIG. As shown in FIG. 1, the small X-ray tube 11 is attached to the mounting rail 25 provided on the movable frame 12b as described above, so that the small X-ray tube 11 can be attached to an arbitrary portion of, for example, the head of the human body (5). Can be moved into position and fixed.

Further, the small X-ray tube 11 is supported by a support member 12 so as to be movable in the front-rear direction. That is, as shown in FIG. 1, the mounting rail 25 is provided with a motor 30, and the rack 3 is provided on one side of the small X-ray tube 11.
1 is provided, and a pinion 32 provided on the rotation shaft of the motor 30 is engaged with the rack 31. Thereby, the rotation of the motor 30 is controlled to move or fix the small X-ray tube 11 in the front-rear direction along the mounting rail 25 through the pinion 32 and the rack 31 as shown by arrows A and B. You can Therefore,
The insertion tube 20 extending from the small X-ray tube 11 moves in the anteroposterior direction with respect to the living body 5 as indicated by arrows A and B,
Can be fixed.

A sheath 13 and a solid rod 29 (see FIG. 6) are added to the small X-ray tube 11. As shown in FIG. 2, the sheath 13 is inserted into the living body 5 in advance in order to guide the insertion of the insertion tube 20 of the small X-ray tube 11 into the living body 5, and is shown in the sectional view of FIG. Thus, the metal cylinder 13a made of, for example, stainless steel having an inner diameter slightly larger than the outer diameter of the insertion tube 20 and the outer surface of the metal cylinder 13a made of, for example, polyurethane or silicone resin. And a biocompatible material 13b. The metal cylinder 13a is for maintaining the mechanical strength of the sheath 13 as a whole, and it is not preferable to insert the metal cylinder 13a directly into the living body 5 as the biocompatible material 13b, so that the living body 5 is protected from the metal cylinder 13a. It is for doing. The shape of the tip of the biocompatible material 13b is preferably spherical so as not to damage the living body 5 when it is inserted into the living body 5. When a metal having a high magnetic permeability (for example, permalloy or mu metal) having a thickness of 1 mm or more is used as the metal cylinder 13a, it is possible to shield the earth magnetic field leaking into the hollow of the insertion tube 20. . By thus shielding the geomagnetic field in the hollow of the insertion tube 20, the bending of the electron beam 15 (see FIG. 2) in the insertion tube 20 due to the influence of the geomagnetic field can be suppressed, and the insertion tube 20 of the electron beam 15 can be suppressed. Can be prevented from colliding with the pipe wall. In addition, the sheath 13 shown in FIG.
Although the coaxial two-layer structure of 3a and the biocompatible material 13b is used, the present invention is not limited to this, and may be a single layer of the metal cylinder 13a alone, or may be further laminated with another layer to have a structure of three or more coaxial layers.

Further, the solid rod 29, as shown in FIG.
When the sheath 13 is inserted into the living body 5, the sheath 13 is inserted into the inside of the sheath 13 to reinforce the sheath 13, and the sheath 13 is removed from the sheath 13 after being inserted into the living body 5. It is composed of a metal cylinder rod or other member having an equal outer diameter and high mechanical strength. The length of the solid rod 29 is longer than that of the sheath 13 as shown in FIG. 6, so that the solid rod 29 can be easily pulled out from the sheath 13 after being inserted into the living body 5. Then, when the solid rod 29 is pulled out, only the sheath 13 is inserted and fixed in the living body 5.

Next, the use of the medical treatment apparatus provided with the small X-ray tube thus constructed will be described. First, it is necessary to insert the insertion tube 20 of the small X-ray tube 11 shown in FIG. 1 into, for example, the head of the human body (5). Prior to this, the sheath 13 for guiding the insertion of the insertion tube 20 is provided inside the living body 5. To insert. Therefore, as shown in FIG.
To reinforce the sheath 13 in this state.
The end portion of the sheath 13 is inserted into the living body 5, and the distal end portion of the sheath 13 comes into contact with the affected portion 19 or enters the inside thereof and is stopped. Then, the solid rod 29 is put into the sheath 13
Only the sheath 13 is left inside the living body 5. As a result, the sheath 13 is fixed while being inserted into the living body 5.

Next, in this state, the small X-ray tube 11 is fixed to the head of the human body (5) by the support member 12 as shown in FIG. At this time, the supporting member 12 is fixed using the skull by fixing screws (not shown) provided at three to four places around the fixing frame 12a shown in FIG. Next, as shown in FIG. 6, in order that the longitudinal direction of the insertion tube 20 extending from the small X-ray tube 11 coincides with the longitudinal direction of the sheath 13 fixed to the living body 5, in FIG. It rotates in the D direction and its movable frame 12b
Above, the mounting rail 25 is moved in the directions of arrows G and H. Then, when the longitudinal direction of the sheath 13 and the longitudinal direction of the insertion tube 20 coincide with each other, the set screw 24 shown in FIG. 4A is tightened to fix the movable frame 12b, and the other set screw shown in FIG. Tighten 28 to fix the mounting rail 25 to the movable frame 12b. Thereby, as shown in FIG. 1, the small X-ray tube 11 is set by aligning the axis of the insertion tube 20 with the sheath 13 inserted into the living body 5.

Next, in FIG. 1, the motor 30 is rotationally driven to move the small X-ray tube 11 forward along the mounting rail 25 in the direction of arrow A through the pinion 32 and the rack 31.
The insertion tube 20 is inserted into the sheath 13. At this time,
As shown in FIG. 2, the insertion tube 20 is inserted into the living body 5 using the sheath 13 as a guide, and when the insertion tube 20 reaches the tip of the sheath 13, the motor 30 is stopped and the insertion tube 20 is stopped.
As a result, the target 18 provided at the distal end of the insertion tube 20 is located inside or in the vicinity of the affected area 19. In this case, even if the mechanical strength of the insertion tube 20 is not sufficient, since the sheath 13 previously inserted into the living body 5 toward the affected part 19 is inserted as a guide, the insertion tube 20 is
It is inserted toward the affected part 19 in a straight state without bending.

In this state, the power cable 10 shown in FIG.
Power is supplied to the small X-ray tube 11 via. Then, the supply of this electric power causes the electron gun 16 to generate an electron beam 15, and the electron beam 15 is accelerated by the accelerator 17.
The accelerated electron beam 15 then irradiates the target 18 through the hollow portion inside the insertion tube 20, and X-rays are generated from the target 18. Then, the generated X-rays are applied to the affected area 19 for treatment. At this time, as shown in FIG. 2, the state of distribution of X-rays emitted from the target 18 in a state where the insertion tube 20 is inserted inside the sheath 13 will be described with reference to FIG. 7.

The sheath 13 shown in FIGS. 7 (a) and 7 (b) has the same structure as the sheath 13 shown in FIG. 5, but in FIG. 7, the biocompatible material 13b shields X-rays. The illustration is omitted because there is no. And the metal cylinder 13a
Has a thickness sufficient to shield the X-rays 33 emitted from the target 18 at the tip of the insertion tube 20 inserted into the sheath 13. In such a state, the X-ray 3 emitted by irradiating the target 18 with the electron beam 15 is emitted.
3 spreads radially from the target 18, but the range is limited to the metal cylinder 13a of the sheath 13. That is,
As shown in FIGS. 7A and 7B, the target 18
A part of the X-ray 33 radially radiated from the metal cylinder 13a
Therefore, it will not spread after that.

In FIGS. 7A and 7B, the amount of insertion of the insertion tube 20 into the sheath 13 is adjusted to change the distance from the tip of the sheath 13 to the target 18. In this way, by changing the distances d ₁ and d ₂ from the tip of the sheath 13 to the target 18, the target 18
It is possible to change the radiation range of the X-ray 33 emitted from the. Further, since the density of the X-rays 33 emitted from the target 18 decreases as the distance from the target 18 increases, the affected area 19 is irradiated with X by changing the distances d ₁ and d _2. The linear dose can be varied. That is, as shown in FIG.
If the distance d ₁ from the tip of the sheath 13 to the target 18 is shortened, a large dose of X-rays 33 will be emitted in a wide radiation range, and as shown in FIG. If the distance d ₂ up to 18 is increased, the low-dose X-ray 33 is emitted in a narrow radiation range.

From this, a large dose of X-rays 33 is irradiated to a large radiation range for a large diseased part 19 as shown in FIG. By irradiating a narrow radiation range with the low-dose X-ray 33 as shown in (b), it is possible to improve the therapeutic effect on each affected area 19. Then, the operation for this purpose is to control the rotation of the motor 30 in FIG.
The distance from the tip of the sheath 13 to the target 18 may be appropriately set by moving in the front-rear direction as indicated by B.

[0030]

Since the present invention is constructed as described above,
A small X-ray tube is fixed to a predetermined part of the human body with a support member, and a solid rod having an outer diameter substantially equal to the outer diameter of the insertion tube is made of metal for guiding the insertion of the insertion tube into a living body. When inserting the sheath into the living body, the sheath is reinforced by being inserted into the sheath, and after the sheath is inserted, the sheath is removed from the sheath, and in this state, the insertion tube is inserted into the sheath to guide the sheath. As a result, the insertion tube can be inserted into the living body, and the small X-ray tube can be supported by the support member so as to be movable in the front-rear direction with the insertion tube being inserted into the sheath. This allows a small X
The X-ray tube can be securely fixed to a predetermined part of the human body, and an X-ray generation source target can be fixed to the distal end portion and an insertion tube that guides to the affected part in the living body can be inserted with good straightness and further irradiated to the affected part. The dose distribution of X-rays can be made variable. Therefore, it is possible to prevent the electron beam from colliding with the tube wall of the insertion tube and not to reach the target, and X-rays are always generated from the target to treat the affected area. Furthermore, since the dose distribution of the X-rays that are applied to the affected area can be changed, it is possible to apply the dose of X-rays corresponding to the large and small affected areas, and the therapeutic effect on each affected area can be improved.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing an embodiment of a therapeutic apparatus including a small X-ray tube according to the present invention.

FIG. 2 is a cross-sectional explanatory view showing a state in which the insertion tube of the small X-ray tube according to the present invention is inserted inside a living body.

FIG. 3 is a perspective view showing a structure of a support member.

FIG. 4 is an explanatory view showing a detailed structure of a fixed frame and a movable frame of the support member, (a) of FIG.
Similarly, FIG. 3B is a sectional view taken along the line O-F in FIG.

FIG. 5 is a cross-sectional view showing the structure of the sheath of the insertion tube.

FIG. 6 is a cross-sectional explanatory view showing a state in which a solid rod is inserted into the inside of the sheath and the sheath is inserted into a living body.

FIG. 7 is an explanatory diagram showing a state of distribution of X-rays emitted from a target with a small X-ray tube insertion tube inserted inside the sheath.

FIG. 8 is a schematic configuration diagram showing a conventional small X-ray tube for treatment.

[Explanation of symbols]

 5 ... Living body 11 ... Small X-ray tube 12 ... Support member 12a ... Fixed frame 12b ... Movable frame 13 ... Sheath 13a ... Metal cylinder 13b ... Biocompatible material 15 ... Electron beam 16 ... Electron gun 17 ... Accelerator 18 ... Target 19 ... Affected part 20 ... Insertion tube 25 ... Mounting rail 29 ... Solid rod 30 ... Motor 31 ... Rack 32 ... Pinion 33 ... X-ray

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Hirokazu Ihara 1-1-14 Kanda, Uchida, Chiyoda-ku, Tokyo Inside Hitachi Medical Co., Ltd.

Claims (4)

[Claims] 1. An electron gun for generating an electron beam, an accelerating body for accelerating the electron beam generated by the electron gun, and an X-ray generating source by irradiating the electron beam accelerated by the accelerating body. A small X-ray tube comprising a target and a small-diameter insertion tube which is inserted into the living body in order to fix the target to the distal end and locate the target in or near the affected area to be treated in the living body. The small X-ray tube is provided with a support member for fixing the small X-ray tube to a predetermined part of the human body, and is inserted into the living body in advance to guide the insertion of the small X-ray tube into the living body. A metal sheath is added, and the sheath has an outer diameter substantially equal to that of the insertion tube. When the sheath is inserted into a living body, the sheath is inserted into the sheath to reinforce the sheath and after the sheath is inserted, the sheath is inserted. Small size characterized by adding a solid rod to remove from A treatment device equipped with an X-ray tube. 2. The supporting member moves with respect to the fixed frame, which serves as a base member for fixing the small X-ray tube to a predetermined portion of a human body, and the fixed frame for moving the small X-ray tube to an arbitrary position. A treatment device with a small X-ray tube according to claim 1, characterized in that it comprises a movable frame which is enabled. 3. The support member supports the small X-ray tube so as to be movable in the front-rear direction with the insertion tube inserted into the inside of the sheath.
Alternatively, a treatment device including the small X-ray tube according to the above item 2. 4. The treatment apparatus having a small X-ray tube according to claim 1, wherein the outer surface of the sheath is entirely coated with a biocompatible material.