CN1829466A - Medical device, medical device guide system, capsule-type medical device, and capsule-type medical device guide device - Google Patents
Medical device, medical device guide system, capsule-type medical device, and capsule-type medical device guide device Download PDFInfo
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- CN1829466A CN1829466A CNA2004800218881A CN200480021888A CN1829466A CN 1829466 A CN1829466 A CN 1829466A CN A2004800218881 A CNA2004800218881 A CN A2004800218881A CN 200480021888 A CN200480021888 A CN 200480021888A CN 1829466 A CN1829466 A CN 1829466A
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B1/00—Instruments for performing medical examinations of the interior of cavities or tubes of the body by visual or photographical inspection, e.g. endoscopes; Illuminating arrangements therefor
- A61B1/00147—Holding or positioning arrangements
- A61B1/00158—Holding or positioning arrangements using magnetic field
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B34/00—Computer-aided surgery; Manipulators or robots specially adapted for use in surgery
- A61B34/70—Manipulators specially adapted for use in surgery
- A61B34/73—Manipulators for magnetic surgery
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Abstract
A capsule (3) as a medical device to be inserted into a body cavity has its longitudinal direction as an insert axis and a magnet (8) magnetized in the direction orthogonal to the insert axis is arranged at the center position of the insert axis. By turning ON a vibration (ON/OFF) switch (8f) of an operation input device (8) for a magnetic field generation device (4) arranged outside the body, the magnetic field generation device (4) generates a vibration magnetic field in the direction parallel to the insert axis of the capsule (3) and a force couple having the function line parallel to the insert axis functions on the capsule (3), so that the capsule (3) swings around the insert axis and advances smoothly along a luminal organ.
Description
Technical field
The present invention relates to insert endoceliac medical treatment device, be suitable for making medical treatment device in rotation, to advance medical device induction system, capsule medical apparatus and the capsule-type medical device guide device of channeling conduct.
Background technology
As utilizing rotating excitation field propulsive prior art in tested having a medical check-up, Japan's patent disclosure 2001-179700 communique and patent disclosure 2002-187100 communique are arranged.In these prior aries, disclose a kind of mobile control system of transportable miniature instrument, had: the magnetic field generating unit that produces rotating excitation field; Accept this rotating excitation field and rotate the robot body who obtains thrust; The position detection part of detection machine human agent's position; With change unit, magnetic field, it is according to the detected robot body's of this position detection part position, and change is by the direction of the rotating excitation field of magnetic field generating unit generation, so that the robot body is towards the direction that arrives destination.
In above-mentioned prior art, tube chamber width that miniature instrument is advanced or diameter is less, narrow or the zigzag situation of tube chamber under, produce the phenomenon that can not guide miniature instrument etc. swimmingly sometimes.
And, otherwise at tube chamber during greater than miniature instrument big or small, the helical structure portion and the contact between the tube chamber that are located at the miniature instrument periphery reduce the guiding that can not envision sometimes.
In addition, above-mentioned prior art is to form the type of advancing in the hole by borer, can not be applicable to the situation of advancing along this tube chamber in tube chamber internal organs such as endoceliac esophagus.
The present invention In view of the foregoing proposes, its purpose is, be provided under the situation of the endoceliac medical treatment device main body of guiding insertion in the body cavity, can improve the medical treatment device that passes through function of medical treatment device, and medical treatment device, medical device induction system, capsule medical apparatus and the capsule-type medical device guide device that can be suitable for making the smooth and easy guiding of passing through of medical treatment device.
And, the objective of the invention is to, medical treatment device, medical device induction system, capsule medical apparatus and the encapsulated medical device guiding system that can be directed to the target site side by rotation along tube chamber internal organs inside at short notice are provided.
In addition, the objective of the invention is to, even provide crooked tube chamber internal organs also can smooth and easy propulsive medical treatment device, medical device induction system, capsule medical apparatus and encapsulated medical device guiding system.
Summary of the invention
Medical treatment device of the present invention is to have the medical treatment device that is directed to endoceliac insertion section, comprises the couple generation unit, and this couple generation unit produces the couple with position parallel with inserting axle.
And medical treatment device of the present invention comprises: medical treatment device, and it has and is inserted into endoceliac and has the insertion section that roughly is profile cylindraceous; Be arranged on the helicoidal structure portion on the side of this medical treatment device main body; Thrust produces mechanism, and it has makes the rotary drive unit of this helicoidal structure portion around the Cylindorical rod rotation of described medical treatment device main body, and produces thrust on the Cylindorical rod direction; And the couple generation unit, its generation has the couple of the position parallel with described Cylindorical rod.
Medical device induction system of the present invention comprises: rotating excitation field; Magnetic field generation device, the magnetic field of the vertical direction of Plane of rotation of its generation and this rotating excitation field; The medical treatment device main body, it has and is inserted into endoceliac insertion section; The thrust that is arranged on the described medical treatment device main body produces structural portion; And Magnet, it is arranged in the described medical treatment device main body, and is configured to pole orientation produces the direction approximate vertical towards the thrust with described thrust generation structural portion direction.
Medical device induction system of the present invention comprises: the magnetic field generation device that produces rotating excitation field; Has the medical treatment device main body that is inserted into endoceliac insertion section; The thrust that is arranged on the described medical treatment device main body produces structural portion; Position of centre of gravity change mechanism, it makes the position of centre of gravity that is arranged on the medical treatment device on the described medical treatment device main body move with respect to the insertion axle of medical treatment device; Magnet, it is arranged on the described medical treatment device main body, and is configured to pole orientation produces the direction approximate vertical towards the thrust with described thrust generation structural portion direction; And transfer unit, the control signal of the described position of centre of gravity change of its control mechanism passes to the medical treatment device main body.
Capsule medical apparatus of the present invention comprises: have the capsule medical apparatus main body that is inserted into endoceliac insertion section; The thrust that is arranged on the described medical treatment device main body produces structural portion; And Magnet, it is arranged on the described medical treatment device main body, and the thrust that is configured in described capsule medical apparatus main body produces near the center of direction, makes pole orientation produce the direction of direction approximate vertical towards the thrust that produces structural portion with described thrust.
Capsule medical apparatus of the present invention comprises: have the capsule medical apparatus main body that is inserted into endoceliac insertion section; The thrust that is arranged on the described medical treatment device main body produces structural portion; And Magnet, it is arranged on the described medical treatment device main body, and the thrust that is configured in described capsule medical instrument main body produces near the end of direction, makes pole orientation produce the roughly direction of straight shape of direction towards the thrust that produces structural portion with described thrust.
In addition, medical treatment device of the present invention is used for checking in tested tube chamber internal organs of having a medical check-up or the medical act of disposal etc., main body is made of the rotationally symmetric body that has direct of travel along axis of symmetry, the direct of travel front portion of main body or at least one side at rear portion are attenuated along end direction by diameter, and the reducing diameter part with end shape of sphere roughly constitutes, has electromagnetic field response portion in body interior, it is subjected to from the effect of the rotation that is examined the external electromagnetic field that applies, on the main body outer surface, have and be used for rotatablely moving of being produced by described electromagnetic field response portion is converted to the helicoidal structure of propulsive force, be arranged to make the end of described helicoidal structure to arrive near the body end.
Medical treatment device of the present invention is used for checking in tested tube chamber internal organs of having a medical check-up or the medical act of disposal etc., main body is by general cylindrical shape shape part, and the diameter at main body two ends attenuates and reducing diameter part with end shape of sphere roughly constitutes along end direction, has Magnet in body interior, it is subjected to from being examined the magnetic action of the rotating excitation field that external body applies, have on the main body outer surface and be used for rotatablely moving of being produced by described Magnet is converted to the helicoidal structure of propulsive force, described helicoidal structure is arranged on the general cylindrical shape shape part and described reducing diameter part of described main body.
Medical device induction system of the present invention is used for checking in tested tube chamber internal organs of having a medical check-up or the medical act of disposal etc., have: medical treatment device, its main body is made of the rotationally symmetric body that has direct of travel along axis of symmetry, at least one side at the front portion of the direct of travel of main body or rear portion is attenuated and has roughly that the reducing diameter part of the end shape of sphere constitutes along end direction by diameter, has electromagnetic field response portion in body interior, it is subjected to from the effect of the rotation that is examined the electromagnetic field that external body applies, on the main body outer surface, have and be used for rotatablely moving of described electromagnetic field response portion is converted to the helicoidal structure of propulsive force, be arranged to make the end of described helicoidal structure to arrive near the body end; Electromagnetic field generation unit, its generation act on the electromagnetic field of the electromagnetic field response portion that is arranged in the described medical treatment device; The electromagnetic field control unit, it controls the direction of the electromagnetic field of described electromagnetic field generation unit generation, and described electromagnetic field generation unit generates an electromagnetic field on three direction of principal axis, makes described medical treatment device at tube chamber internal organs internal rotation.
Medical device induction system of the present invention is used for checking in tested tube chamber internal organs of having a medical check-up or the medical act of disposal etc., comprise: medical treatment device, its main body is by general cylindrical shape shape part, and the diameter at main body two ends attenuates and reducing diameter part with end shape of sphere roughly constitutes along end direction, has Magnet in body interior, it is subjected to from being examined the magnetic action of the rotating excitation field that external body applies, have the helicoidal structure that is used for rotatablely moving of described Magnet is converted to propulsive force on the main body outer surface, described helicoidal structure is arranged on the general cylindrical shape shape part and described reducing diameter part of described main body; Electromagnetic field generation unit, its generation act on the electromagnetic field of the electromagnetic field response portion that is arranged in the described medical treatment device; The electromagnetic field control unit, it controls the direction of the electromagnetic field of described electromagnetic field generation unit generation, and described electromagnetic field generation unit generates an electromagnetic field on three direction of principal axis, makes described medical treatment device at tube chamber internal organs internal rotation.
Description of drawings
Fig. 1 is the special summary structure chart based on the rotating excitation field generator with encapsulated medical device guiding system of the 1st embodiment of the present invention.
Fig. 2 is the block diagram of internal structure of the each several part of the encapsulated medical device guiding system of expression with the 1st embodiment of the present invention.
Fig. 3 (A) is the side view of capsule body.
Fig. 3 (B) is the front view of capsule body.
Fig. 4 (A) is the key diagram of the structure of expression input device.
Fig. 4 (B) shows the figure of the pictorial display picture that shows the information corresponding with the operation of the input device shown in Fig. 4 (A).
Fig. 5 is the key diagram of the variable condition of the rotating excitation field of expression when applying rotating excitation field etc.
Fig. 6 (A) and Fig. 6 (B) are the synoptic diagrams of the situation of the couple that is subjected to of the capsule medical apparatus of expression when having applied oscillating magnetic field.
Fig. 7 (A) and Fig. 7 (B) are expressions when changing the frequency of rotating excitation field and oscillating magnetic field and intensity, the figure of the track that the front end of capsule medical apparatus is drawn.
Fig. 8 (A) is the figure that expression makes the mutually isochronous track of frequency of the frequency of rotating excitation field and oscillating magnetic field.
Fig. 8 (B) is expression when making the frequency of oscillating magnetic field be 2 times of frequency of rotating excitation field, the figure of the track that the front end of capsule medical apparatus is drawn.
Fig. 8 (C) is expression when making oscillating magnetic field be direct current, the figure of the track that the front end of capsule medical apparatus is drawn.
Fig. 9 (A), Fig. 9 (B) and Fig. 9 (C) are that sample, the figure of the measurement result of the fltting speed when applying rotating excitation field and oscillating magnetic field etc. are used in expression.
Figure 10 (A), Figure 10 (B), Figure 10 (C) and Figure 10 (D) are the action specification figure when advancing in the tube chamber internal organs of the tube chamber internal organs of bending and broad.
Figure 11 applies the isochronous key diagram of rotating excitation field in the coordinate system that the central shaft of capsule medical apparatus is set at x ' direction.
Figure 12 is the key diagram of calculating of the direction of capsular direction when having carried out the direction input indication of direction of change capsule medical apparatus and rotating excitation field.
Figure 13 utilizes polar coordinate system to represent the key diagram of the new direction of capsule medical apparatus.
Figure 14 is the allocation plan of the internal structure of capsule medical apparatus.
Figure 15 is the allocation plan of configurations of magnets in the variation of rear end side in Figure 14.
Figure 16 is the allocation plan of configurations of magnets in the variation of observing reveal in Figure 14.
Figure 17 is the action specification figure when configuration shown in Figure 15 is applied oscillating magnetic field.
Figure 18 (A) and Figure 18 (B) are the key diagrams of the difference of the motion respectively near the configurations of magnets center of capsule medical apparatus main body and under near the situation the end, channeling conduct the time.
Figure 19 (A) and Figure 19 (B) are the capsule medical apparatus of expression the 2nd embodiment of the present invention and the figure of pager motor part.
Figure 20 is the cutaway view of the capsule medical apparatus of expression the 3rd embodiment of the present invention.
Figure 21 (A) is the structure chart of expression o device part.
Figure 21 (B) is illustrated in the figure that one-sided end is provided with the capsule type endoscope of flexible pipe.
Figure 22 is the summary structure chart that expression has the encapsulated medical device guiding system of the 4th embodiment of the present invention.
Figure 23 is a block diagram of representing structure shown in Figure 22 in further detail.
Figure 24 is the summary structure chart of the summary structure of expression magnetic field generation device.
Figure 25 is the side view of the outward appearance of expression capsule medical apparatus.
Figure 26 is the cutaway view of the internal structure of expression capsule medical apparatus.
Figure 27 is the side view of expression tank, and wherein the capsule with sample is inserted in the silicone tube, measures fltting speed to apply rotating excitation field.
Figure 28 is illustrated in the figure that the end is provided with the 1st sample of helical form projection.
Figure 29 (A) and Figure 29 (B) are the curve charts of the measurement result of expression fltting speed.
Figure 30 (A) and Figure 30 (B) are the key diagrams that is illustrated in the effect when advancing in the crooked pipeline.
Figure 31 is the side view of the capsule medical apparatus of expression the 5th embodiment.
Figure 32 is the side view of the capsule medical apparatus of expression the 1st variation.
Figure 33 is the side view of the capsule medical apparatus of expression the 2nd variation.
Figure 34 is the side view of the capsule medical apparatus of expression the 3rd variation.
Figure 35 is the summary side view of spacing of helical form projection of the capsule medical apparatus of expression the 4th variation.
Figure 36 (A) is the key diagram of the capsule medical apparatus of expression the 6th embodiment of the present invention.
Figure 36 (B) is the figure that obtain image of expression from capsule medical apparatus shown in Figure 36 (A).
Figure 37 is that the structure division with the capsule medical apparatus of variation cuts the side view of representing.
The specific embodiment
Below, with reference to the description of drawings embodiments of the present invention.
(the 1st embodiment)
Fig. 1~Figure 18 relates to the 1st embodiment of the present invention, Fig. 1 and Fig. 2 represent the overall structure of the encapsulated medical device guiding system of the 1st embodiment, Fig. 3 represents the side view and the front view of capsule body, Fig. 4 (A) and (B) the expression input device structure and show the pictorial display picture of operating corresponding information with this, the changing condition of the rotating excitation field when Fig. 5 represents to apply rotating excitation field etc., the situation of the couple that the capsule medical apparatus when Fig. 6 has represented to apply oscillating magnetic field is subjected to, when Fig. 7 represents to change the frequency of rotating excitation field and oscillating magnetic field and intensity, the track that the front end of capsule medical apparatus is drawn, Fig. 8 (A) expression makes the frequency of rotating excitation field and the mutually isochronous track of frequency of oscillating magnetic field, when Fig. 8 (B) expression makes the frequency of oscillating magnetic field be 2 times of frequency of rotating excitation field, the track that the front end of capsule medical apparatus is drawn, when Fig. 8 (C) expression makes oscillating magnetic field be direct current, the track that the front end of capsule medical apparatus is drawn, Fig. 9 represents to use sample, the measurement result of the fltting speed when applying rotating excitation field and oscillating magnetic field etc., Figure 10 is illustrated in the action specification figure when advancing in the tube chamber internal organs of crooked tube chamber internal organs and broad, Figure 11 is illustrated in the central shaft of capsule medical apparatus is set in the coordinate system of x ' direction and applies the isochronous key diagram of rotating excitation field, the key diagram of the capsule direction when Figure 12 has represented to carry out the direction input indication of direction of change capsule medical apparatus and the calculating of rotating excitation field direction, Figure 13 represents to utilize absolute coordinate system to represent the key diagram of the new direction of capsule medical apparatus, Figure 14 represents the allocation plan of the internal structure of capsule medical apparatus, Figure 15 is illustrated among Figure 14 the allocation plan of configurations of magnets in the variation of rear end side, Figure 16 is illustrated among Figure 14 the allocation plan of configurations of magnets in the variation of observing reveal, the key diagram of the action when Figure 17 represents that configuration shown in Figure 15 applied oscillating magnetic field, Figure 18 are illustrated in respectively near the difference of configurations of magnets motion the during channeling conduct center of capsule medical apparatus main body and under near the situation the end.
As depicted in figs. 1 and 2, the encapsulated medical device guiding system 1 of the 1st embodiment of medical device induction system of the present invention has: capsule medical apparatus 3 (being designated hereinafter simply as capsule), its insertion (importing) is brought into play the effect of the capsule type endoscope that body cavity inside is taken in not shown patient's body cavity; Magnetic field generation device 4, it is configured in the promptly external of patient on every side, and described capsule 3 is applied rotating excitation field and couple generation usefulness magnetic field (or oscillating magnetic field); Magnetic field control device (or power control) 5, it makes this magnetic field generation device 4 produce rotating excitation field and the couple generation is controlled with the supply of the drive current of magnetic field (or oscillating magnetic field); Blood processor 6, it is made of personal computer etc., be configured in the external of patient, carry out radio communication with capsule 3, and carry out Flame Image Process, and the operation according to the operator comes controlling magnetic field control device 5, controls the rotating excitation field that is applied on the capsule 3 and couple and produces processing with the direction of magnetic field (or oscillating magnetic field) and size etc.; Display device 7, it is connected on this blood processor 6, the image that demonstration is taken by capsule 3 etc.; Operation inputting part 8, it is connected on the blood processor 6, by operators' such as operative doctor operation, the index signal that the indication input is corresponding with operation.
Shown in Fig. 4 (A), this operation inputting part 8 has: direction input device 8a, and it makes the input indication that is inserted into intravital capsule 3 propulsive directions; Speed input equipment 8b, it produces the index signal of the rotating excitation field of the speed corresponding with operation; The intensity adjustments device 8c of rotating excitation field, its intensity to rotating excitation field is regulated operation; The intensity adjustments device 8d in vibration (or the couple generation is used) magnetic field; The frequency regulation arrangement 8e in vibration (couple produces and uses) magnetic field; Vibration (or couple produce with) on/off switch (abbreviating vibroswitch as) 8f, it is arranged on for example top of the stick 9 that constitutes direction input device 8a, vibrates the On/Off that applies in (or couple produce use) magnetic field.In addition, (under nearly all situation) below is expressed as oscillating magnetic field to vibration (couple produce with) magnetic field.
As shown in Figure 3, capsule 3 forms general cylindrical shape shape or capsule shape, on also as the outer peripheral face of outer packaging container 11 that is inserted into intravital insertion section, helically is provided with rotation is converted to helical form projection (or spire) 12 thrust (propulsive force), produce structural portion as thrust.
This helical form projection 12 forms the section structure that the roughly hemispherical grade of arc sections is set on the outer peripheral face of packaging container 11 outside, contacts intravital internal face smoothly.
And, by should be outer the airtight inside of packaging container 11, taking in by object lens 13 be configured in the image unit that the imaging apparatus 14 on its image space constitutes.And, outside this in packaging container 11, except taking in the needed illuminating illumination component 15 (with reference to Fig. 2) of making a video recording etc., also taking in and be used to make the propulsive more smoothly magnet of capsule 3 (permanent magnet) 16.
Shown in Fig. 3 (A), Fig. 3 (B), object lens 13 are configured in the inboard of the hemispherical and transparent drive end bearing bracket 11a of for example outer packaging container 11, make that the central shaft C that can be called the insertion axle of its optical axis and cylindric capsule 3 is consistent, the middle body of drive end bearing bracket 11a becomes observation window 17 shown in Fig. 3 (B).In addition, though not shown in Fig. 3 (A), Fig. 3 (B), illumination component 15 be configured in object lens 13 around.
Therefore, under this situation, the visual field direction of object lens 13 becomes the optical axis direction of object lens 13, promptly along the direction of the central shaft C cylindraceous of capsule 3.
And, shown in Fig. 3 (A), Fig. 3 (B), be configured near the central authorities of the length direction in the capsule 3 magnet 16 be configured to the vertical direction of central shaft C on form the N utmost point and the S utmost point.Under this situation, the center of magnet 16 is configured to consistent with the position of centre of gravity of this capsule 3, applying under the situation in magnetic field from the outside, the center that acts on the magnetic force of magnet 16 becomes the position of centre of gravity of capsule 3, forms and swimmingly capsule 3 is carried out the propulsive structure of magnetic force easily.
In addition, shown in Fig. 3 (B), be configured to make magnet 16 the direction of magnetization, be that the direction of dipole is consistent with the specific configuration direction of imaging apparatus 14.
That is the last direction when, showing the image that photographs by imaging apparatus 14 is set to from the S utmost point of magnet 16 direction towards the N utmost point.
And, by utilizing 4 pairs of capsules 3 of magnetic field generation device to apply rotating excitation field, make the rotation of magnet 16 magnetic force, the capsule 3 that has made in internal fixation this magnet 16 is with magnet 16 rotations, be arranged on the helical form projection 12 contact cavity walls on the outer peripheral face of capsule 3 and rotate this moment, thereby can advance capsule 3.
And, in the present embodiment, it is characterized in that, as the summary of its basic function (effect) of Fig. 6 (A) and Fig. 6 (B) expression (by connecting the operation of vibroswitch 8f), the oscillating magnetic field that can utilize 4 pairs of capsules 3 of magnetic field generation device to apply magnetic direction on the central shaft C of capsule 3 direction, to change (couple produces and use magnetic field) Hm, thus can act on the power (being couple) that shown in the arrow among Fig. 6 (A) and Fig. 6 (B), is parallel to central shaft C and opposite sign but equal magnitude like that to the magnet 16 that is built in this capsule 3.
Under this situation, couple is connecting on two polar lines of magnet 16, on two polar each positions, and C is parallel with central shaft, the equal and opposite in direction of power, and its direction is opposite each other, and act on and make capsule 3 rotations.
In the present embodiment, be used to come magnet 16 effect couples from outside magnetic field, but also can be as the middle explanations such as the 2nd embodiment of narration in the back, inclination (shaking) mechanism of the direction rocking vibration of the insertion axle that capsule 3 is formed make its length direction or inclination etc., or change the structure (also can be to produce or the suitable power of a side of effect and formation couple) of the mimic couple generation unit of position of centre of gravity.
And, in the present embodiment, utilizing the external magnetic field to control under the situation of the capsule 3 that is built-in with magnet 16, can learn which direction is the last direction of the image of taking by capsule 3 be according to the direction of external magnetic field.
In capsule 3, except that above-mentioned object lens 13, imaging apparatus 14, illumination component 15, magnet 16, as shown in Figure 2, also taken in lower member: signal processing circuit 20, the signal of being taken by imaging apparatus 14 is carried out signal processing; Memorizer 21, the digital video signal that interim storage is generated by signal processing circuit 20; Radio-circuit 22 is utilized high-frequency signal that the video signal of reading from memorizer 21 is modulated and is converted to the signal of wireless transmission, perhaps the control signal that sends from blood processor 6 is carried out demodulation etc.; To capsule 3, the capsule control circuit of controlling as signal processing circuit 20 grades 23; Use the battery 24 of power supply to the electrical system supply work of 3 inside such as signal processing circuit 20 capsules such as grade.
And the blood processor 6 that carries out radio communication with this capsule 3 has: carry out the radio-circuit 25 of radio communication with described radio-circuit 22; Data processing circuit 26 is connected with radio-circuit 25, the view data that sends from capsule 3 is carried out the date processing of pictorial display etc. etc.; The control circuit 27 of control data treatment circuit 26 and power control 5 etc.; Memory circuit 28, storage is by the set information of described power control 5 by the status information of the rotating excitation field of rotating excitation field generator 4 generations and direction input device 8a etc.
Connecting display device 7 on the data processing circuit 26, showing by imaging apparatus 14 shootings, through radio- circuit 22,25, pass through the image of data processing circuit 26 processing etc.And, because photographic images in capsule 3 rotations, so it is the processing of certain orientation that this data processing circuit 26 carries out the adjustment in direction of the image when being presented in the display device 7, and carry out Flame Image Process, so that can show the image (being recorded in Japanese patent application 2002-105493 number) that operative doctor is seen clearly easily.
From constituting direction input device 8a, the speed input equipment 8b etc. of input device 8, to the described control circuit 27 inputs index signal corresponding with operation, control circuit 27 carries out the control action corresponding with index signal.
And described control circuit 27 is connected with memory circuit 28, is storing the information of the direction in the direction of passing through the rotating excitation field that magnetic field control device 5 produces by magnetic field generation device 4 and magnetic field in memory circuit 28 always.Then, under the situation of the operation that the direction in direction that makes rotating excitation field and magnetic field changes, the direction of rotating excitation field and the direction in magnetic field are changed continuously, and they are changed smoothly.In addition, also can be arranged on control circuit 27 inside to memory circuit 28.
And the magnetic field control device 5 that is connected with described control circuit 27 has: alternating current produces and control part 31, is made of 3 the alternating currents generations and the control circuit that produce alternating current and control its frequency and phase place; Drive division 32 is made of 3 drivers of amplifying each alternating current respectively, and the output current of 3 drivers is provided for 3 electric magnet 33a, 33b, the 33c that constitutes magnetic field generation device 4 respectively.
Under this situation, electric magnet 33a, 33b, 33c are configured to produce orthogonal three axial magnetic fields.As the example of magnetic field generation device 4, can consider that 33a, 33b, 33c are respectively Helmholtz (helmholtz) coils, be that separately magnetic field produces orthogonal three Helmholtz coils of direction etc.
And, direction input device 8a by the input device 8 shown in the operation pie graph 4 (A), produce the index signal of magnetic direction, perhaps by operation speed input equipment 8b, produce the index signal of the rotating excitation field of the speed corresponding with operation, perhaps by operation vibration (on/off) switch 8f, generation is by (interchange or periodic) oscillating magnetic field of settings such as oscillating magnetic field intensity adjustments device 8d, thereby can be at the magnet 16 of capsule 3, generation makes the couple of the central shaft C of capsule 3 around the central point rotation of the central shaft C of the length direction of capsule 3 itself.Under this situation, make before central shaft C itself rotates fully, exchange or periodically apply oscillating magnetic field, so capsule 3 carries out banking motion or vibration so that the direction of oscillating magnetic field (working as couple) changes in the other direction.
In addition, in Fig. 4 (A), tilt to the anticipated orientation of wanting to advance, can produce the rotating excitation field that capsule 3 is moved to this direction by in direction input device 8a, making stick 9.
State when Fig. 5 represents for example to apply rotating excitation field by capsule 3 is applied rotating excitation field, can make magnets 16 rotations that are built in the capsule 3, capsule 3 is advanced or retreats by this rotation.
And, as shown in Figure 5, apply rotating excitation field, the utmost point of this rotating excitation field is to changing on the plane in the vertical rotating excitation field of direction (being y ' in Fig. 5) with the central shaft C of the length direction of capsule 3, make capsule 3 with in capsule 3, be fixed on the vertical direction of its length direction on magnet 16 around the rotation of its length direction, corresponding to its direction of rotation, can advance or retreat by helical form projection shown in Figure 3 12 and body cavity walls engagement.
And, in the present embodiment, can apply the oscillating magnetic field (couple produces and uses magnetic field) of the following effect of performance to capsule 3, that is, make the direction y ' of the central shaft C of the length direction of magnet 16 in Fig. 5 shake (vibration).And, when applying oscillating magnetic field, can make length direction be for example state shown in the dotted line (by its central axis direction of yz ' expression) from the change of state shown in the solid line (vibration).
Thus, capsule 3 is around the central shaft C of its length direction rotation, and the eccentric direction of this rotary middle spindle C that makes tilts.That is, can become the state of the action that torque diminishes, axle is shaken (following this action is called zigzag (zigzag) action) of spinning top under action of gravity.
Like this, make capsule 3 with the roughly the same tube chamber of the diameter of this capsule 3 in when the length direction of this tube chamber is advanced or retreat, make the rotating excitation field of capsule 3 by applying around its length direction rotation, it is moved swimmingly.
Relative therewith, in the part (with reference to Figure 10 (A)) of tube chamber bending, capsule 3 contact sweeps merely under the situation that length direction rotate, are difficult on the direction of bending mobile swimmingly sometimes.
In this case, as described above, by applying oscillating magnetic field, to act on following power: this power is along the central shaft C of the length direction of capsule 3, around the center of this central shaft C, make central shaft C rotation, thereby make capsule 3 carry out the zigzag action, the length direction when carrying out the zigzag action becomes under the state of bending direction of tube chamber, can make capsule 3 on this direction, move (, will narrate in the back) swimmingly with reference to Figure 10 (A).
In addition, in order to be controlled to desired any direction to the direction of rotating excitation field from current direct of travel, grasp the state of capsule 3 or the state of rotating excitation field by pulling stick 9 always.In the present embodiment, the state of rotating excitation field (specifically referring to the direction of rotating excitation field and the direction in magnetic field) is stored in the memory circuit 28 always.
Specifically, the index signal of the operation in the operation inputting part 8 among Fig. 2 is transfused to control circuit 27, control circuit 27 is exported the control signal that is used to produce the rotating excitation field corresponding with index signal to magnetic field control device 5, and the information of the direction in the direction of this rotating excitation field and magnetic field is stored in the memory circuit 28.
Therefore, in memory circuit 28, storing the information of the direction of rotating excitation field that produces by rotating excitation field generator 4 and the periodically variable magnetic field that forms this rotating excitation field always.
In addition, memory circuit 28 is not limited to store and the corresponding information of control signal from the direction in the direction of the rotating excitation field of control circuit 27 and magnetic field, also can be utilizing the control signal of exporting to magnetic field control device 5 from control circuit 27, produce and control part 31 and drive division 32 and the actual information of exporting to the direction in direction rotating excitation field generator 4, that be used for definite rotating excitation field and magnetic field through the alternating current of magnetic field control device 5, send to control circuit 27 from magnetic field control device 5 sides, and be stored in the memory circuit 28.
And, in the present embodiment, when beginning to apply rotating excitation field and when stopping to apply and the direction of change rotating excitation field (in other words, capsular direct of travel towards) etc. the time, be controlled to rotating excitation field is changed continuously, make capable acting on reposefully on the capsule 3, and do not have rapid masterpiece to be used on the capsule 3.
And, in the present embodiment, because the rotation of capsule 3, and the image of being taken by imaging apparatus 14 is also rotated, so when directly being presented in the display device 7 it, shown image also becomes postrotational image, and the operability that the indication towards anticipated orientation of direction input device 8b is operated reduces, so the rotation of display image is stopped.
Therefore, in the present embodiment, as Japanese Patent Application 2002-105493 number explanation, utilize data processing circuit 26 and control circuit 27 to carry out image rotating is proofreaied and correct the treatment of picture that stops for rotation.
In addition, also can be based on the directional information in magnetic field, make the image rotation, the rotation of eliminating capsule 3 shows (and, also can carry out the relevant treatment of image etc., show the rest image of predetermined direction).
And, shown in Fig. 4 (B), in the display frame 7a of display device 7, for example in circular viewing area 7b, show the rest image of taking by imaging apparatus 14, and utilize arrow 7c to represent the direction of operating of stick 9, utilize the size of arrow 7c to represent operational ton.And, utilize the Show Color of arrow 7c to represent forward/backward.
And, display frame 7a for example below show the frequency of rotating excitation field among the rotating excitation field frequency viewing area 7d in bight.
At first, the rotating excitation field of feature of the present embodiment that becomes this structure and the representativeness effect of oscillating magnetic field are described.
Fig. 6 (A) and Fig. 6 (B) expression have applied the state of oscillating magnetic field Hm.In Fig. 6 (A), by oscillating magnetic field Hm, the position that couple is represented according to arrow works like that, and this couple is rotated the magnet 16 that is fixed in capsule 3 inside in the counterclockwise direction.This force couple role is in the direction parallel with the central shaft C of capsule 3.
Like this, by oscillating magnetic field Hm, capsule 3 is subjected to being used to making the power (couple) of the direction rotation that state that this capsule 3 represents from solid line represents to double dot dash line.
And, by produce with Fig. 6 (A) be reciprocal oscillating magnetic field Hm, shown in Fig. 6 (B), the couple that effect is rotated the magnet 16 that is fixed in capsule 3 inside in the clockwise direction, the direction that the state that capsule 3 is represented from solid line is represented to double dot dash line is rotated.
And, Fig. 7 (A) expression is made as fr<fm to the relation of the frequency f m of the frequency f r of rotating excitation field Hr and oscillating magnetic field Hm, (capsule front end center) the track Tr when the front end face side of the capsule 3 under the state that has applied rotating excitation field Hr and oscillating magnetic field Hm is observed.
And Fig. 7 (B) is illustrated in the track Tr of the capsule 3 under 1/2 the state of intensity that the intensity that makes oscillating magnetic field Hm among Fig. 7 (A) is rotating excitation field Hr, and with respect to the situation of Fig. 7 (A), the angle of waving from center of rotation is 1/2 of Fig. 7 (A).
And the frequency f m that Fig. 8 (A) is illustrated in the frequency f r that makes rotating excitation field Hr among Fig. 7 (A) and oscillating magnetic field Hm equates, i.e. the track Tr of the capsule 3 under the state of fr=fm.
Under this condition, become the operating state (track Tr) that waves to a side (in Fig. 8 (A), being the left side) off-centre.
Therefore, wanting to press under the condition of enlarged effective to a thruster.
And Fig. 8 (B) is illustrated in the frequency f r that makes rotating excitation field Hr among Fig. 7 (A) and produces with 1/2 of the frequency f m of magnetic field H m, even the track Tr of the capsule 3 under the state of fr=fm/2 for vibration.
In addition, more than narrated the situation that makes oscillating magnetic field Hm cyclical movement, but also can provide oscillating magnetic field Hm as the magnetic field (fm=0, Hm ≠ 0) of not change, under this situation, the track Tr of capsule 3 is shown in Fig. 8 (C), with the final period rotation identical with the frequency f r of rotating excitation field Hr.
And, in the present embodiment, shown in Fig. 9 (A), in container 31, be full of water 32, in silicone tube 33, insert capsule 3 at its bottom side, the state of setting capsule 3 is inserted in the endoceliac pipeline carries out mimic state.
And, this container 31 is configured in the rotating excitation field generator 4 shown in Figure 1, utilize this rotating excitation field generator 4 to apply to make to the right side of the length direction (in Fig. 9 (A), being left and right directions) of silicone tube 33 and advance (advancing) and the rotating excitation field of advance to the left (retreating), and the frequency that changes oscillating magnetic field applies oscillating magnetic field, measures the time that has spent when capsule 3 has moved 2cm and calculates its translational speed.
Under this situation, the frequency of rotating excitation field is 1Hz, and its magnetic field intensity is 100Oe, and the intensity of oscillating magnetic field is 50Oe, and water level is 20cm, and the angulation of the helical form projection 12 of capsule 3 is 45 ° and forms two projections, adopts above condition to simulate.And, in the present embodiment, under the state that makes silicone tube 43 bottom right inclination a little (promptly the left side is high), simulate.That is, the right side is advance (decline), and the left side is for retreating (rising).
Its measurement result under situation about retreating shown in Fig. 9 (B), under progressive situation shown in Fig. 9 (C).According to the result of Fig. 9 (B) and Fig. 9 (C), under the situation of the frequency that makes oscillating magnetic field greater than the frequency of rotating excitation field, particularly retreat on the direction of rising under the situation about moving very effective.
And, under the condition of present embodiment,, think that about 2~10Hz compares active data to fltting speed as the frequency of oscillating magnetic field.And, think that frequency with respect to rotating excitation field is that about 2~10 times frequency of vibration is to fltting speed active data relatively.
Below, the mass action of present embodiment is described.
When utilizing capsule 3 to check that body cavity is inner, the patient swallows this capsule 3.When being inserted into endoceliac capsule 3, utilize illumination component 15 illuminations, the image of being taken by imaging apparatus 14 is passed through radio-circuit 22 be wirelessly sent to external blood processor 6 by esophagus etc.
Operative doctor can infer that according to the image that is presented in the display device 7 capsule 3 is currently located at endoceliac Position Approximate.For example, be in the state of taking esophagus and be under the situation of for example darker side such as small intestinal as the position of checking object being judged as, make capsule 3 advance relatively good more apace in the position halfway, (normal direction towards) becomes along the downside of patient's height under this situation, to carry out initial setting so that the direction of the rotating excitation field that is produced by magnetic field generation device 4.In addition, suppose under this situation to be located at the visual field direction that the helical form projection 12 on the capsule 3 makes a video recording with imaging apparatus 14 be the front side, form for example right-hand thread shape.
In order to produce rotating excitation field, for example under the situation of initial manipulation direction input device 8a etc., owing in memory circuit 28, there not be to store the corresponding information of state with before this rotating excitation field, so control circuit 27 starting initialization circuits 29, the setting picture that shows initial setting on display device 7 grades makes operative doctor can select to be set in the direction of the rotating excitation field that produces under the initial setting.And operative doctor becomes along the indication operation of the downside of patient's height the direction of initial generation rotating excitation field, thereby the initial generation information of rotating excitation field is stored in the memory circuit 28.
And, also can utilize initialization circuit 29 to preestablish the size (amplitude) of rotating excitation field, set for and do not produce the above rotating excitation field of this value.The set information of setting by this initialization circuit 29 is stored in the memory circuit 28.
And, stick 9 by pulling the input device 8 shown in Fig. 4 (A) and the operation of action bars 8b, control circuit 27 is read and is stored in the information in the memory circuit 28 and controls, and becomes the direction of rotating excitation field along the downside of patient's height to produce rotating excitation field, to make.That is,, produce described rotating excitation field by rotating excitation field generator 4 by magnetic field control device 5 according to the information of reading from memory circuit 28.
Like this, by from the external rotating excitation field that applies, effect magnetic moment of torsion on the built-in magnet 16 in being inserted into endoceliac capsule 3, make capsule 3 rotations, at this moment, under the state that makes the endoceliac inwall of helical form projection 12 contacts on the outer peripheral face that is arranged at capsule 3, make screw thread rotation, thereby can advance fast.
And, in memory circuit 28, storing state (direction of rotating excitation field and the direction in the magnetic field) information of rotating excitation field always, also storing in the status information that stops to apply the rotating excitation field under the state of rotating excitation field.
And, when applying the operation of rotating excitation field once more,, produce rotating excitation field identical when stopping the rotation magnetic field according to the information that is stored in the memory circuit 28 next time.
Like this, capsule 3 is advanced along endoceliac pipeline, but for example shown in Figure 10 (A), in narrower and small tube chamber 41, under the situation that has narrower and small and crooked bending section 42, merely rely on rotating excitation field, can not effectively advance along bending section 42 sometimes.
In this case, shown in Fig. 7 (A) etc., apply oscillating magnetic field, on capsule 3, act on couple again, can make capsule 3 carry out the zigzag action of Rolling around the axle of its length direction thus with rotating excitation field.
Wave effect by this, shown in the dotted line among Figure 10 (A), can push the tube chamber part that enlarges bending section 42, and towards the state of the bending direction of bending section 42 time, advance to this direction.
And Figure 10 (B) is illustrated in the effect when effectively advancing in the wide tube chamber of the external diameter of capsule 3 41.
Shown in Figure 10 (B), in the time will in the tube chamber 41 wideer, advancing capsule 3 than the external diameter of capsule 3, iff applying rotating excitation field to capsule 3 merely, then shown in Figure 10 (C) or Figure 10 (D), the outer peripheral face of capsule 3 (being located at the helical form projection 12 on this outer peripheral face) is less with the mate (occlusion portion) of tube chamber 41 inner faces, so idle running easily, gait of march is slack-off easily.
In addition, the state when looking A observation of Figure 10 (D) expression from Figure 10 (C), under the situation of merely rotation, its posture change is little, because idle running reduces the performance of advancing.
In this case, shown in Fig. 7 (A) etc., by applying oscillating magnetic field with rotating excitation field, shown in Figure 10 (B), make capsule 3 carry out oscillating motion, it is big that the actual effect external diameter of the capsule 3 under the rocking action state becomes, and its direct of travel is also periodically changed, even under the situation of the tube chamber 41 of broad, also can enlarge the mate with its inwall, can advance effectively.
And, shown in Figure 10 (B), by carrying out rocking action (zigzag action), can advance capsule 3 effectively on the internal diameter tube chamber 41 partially stabilized ground bigger than the external diameter of capsule 3, and by the zigzag action, can enlarge image pickup scope in fact, take tube chamber 41 inwalls in a wider context.
In addition, as mentioned above in the present embodiment, shown in Fig. 4 (B), utilize arrow 7c to represent direction of operating of stick 9 etc., the indication that can in captured image, capsule 3 be advanced on which direction.And corresponding to this direction indication, magnetic field generation device 4 produces the rotating excitation field that capsule 3 is advanced on this direction.
Control circuit 27 calculates the processing of the generation direction of rotating excitation field at this moment, by magnetic field control circuit 5, and the rotating excitation field that rotating excitation field generator 4 produces corresponding to direction indication.
Below, the generation action of the rotating excitation field that describes this moment in detail.
Utilize Hr (t), Hm expressions such as (t) the rotating excitation field intensity that depends on the time t of input shown below, oscillating magnetic field intensity etc. herein.
Rotating excitation field intensity: Hr (t) → utilize 8c to set
Oscillating magnetic field intensity: Hm (t) → utilize 8d to set
The frequency of rotating excitation field: fr (t) → utilize 8b to set
The frequency of oscillating magnetic field: fm (t) → utilize 8e to set
Sampling period: Ts → system's switching field intensity or read in the interval of the input quantity of stick etc.
Current rotatable phase: β (t)
Current couple phase place: α (t)
The parameter that is used for the variable quantity of definite direction: C
Vy ' is (t): the input quantity of the y ' direction of the stick 8a during time t
Vz ' is (t): the input quantity of the z ' direction of the stick 8a during time t
Figure 11 represents the central axis direction of capsule 3 is set at the coordinate system (x ', y ', z ') of x '.In this coordinate system (x ', y ', z ') because the central axis direction of capsule 3 is set at x ', so that capsule 3 is advanced along this central shaft x ' direction, and the magnetic field under the state that applies oscillating magnetic field on central shaft x ' direction is expressed as follows.
Hx′(t+Ts)=Hm(t)cos(α(t)+2πTsfm(t))
Hy′(t+Ts)=Hr(t)cos(β(t)+2πTsfr(t))
Hz′(t+Ts)=Hr(t)sin(β(t)+2πTsfr(t))
Hy ', Hz ' are rotating excitation fields, and Hx ' is equivalent to oscillating magnetic field.
Herein, the current phase place in the trigonometric function is expressed as follows, and adopts below.
α(t+Ts)=α(t)+2πTsfm(t)
β(t+Ts)=β(t)+2πTsfr(t)
Figure 12 is the key diagram of new direction calculating of capsule 3 of having imported direction when indication of capsule 3.
Under state shown in Figure 12, suppose as shown by arrows, indicated the capsule direction indication (becoming the angle direction of angle γ with y ' axle) that changes its direct of travel at (central axis direction is x's ') capsule 3.
Under this situation, make coordinate system become the direction of rotating excitation field around direction with the postrotational new x ' axle of the vertical rotary middle spindle p of capsule direction indication.
This rotation is calculated and can be realized by the following stated.
(1) with x ' axle be the center-rotation (arrow among Figure 12 (1)) of γ
(2) with z ' axle be the rotation (arrow among Figure 12 (2)) of the δ at center
(3) with x ' axle be the rotation (arrow among Figure 12 (3)) of the γ at center
Wherein, the input quantity Vy ' that δ represents stick 9 (t), Vz ' (t),
V(t)=((Vy′(t)
2+(Vz′(t)
2)
1/2
δ(t)=C×V(t)
γ=sin
-1(Vz′(t)/V(t))
Thus, around the transformation matrix that rotary middle spindle p carries out δ (t) rotation, use and operation (1), (2), (3) corresponding spin matrix R
γ X ', R
δ (t) Z ', R
-γ X ', become
R
δ(t) p=R
γ x′R
δ(t) z′R
-γ x′。
Wherein, utilize the spin matrix of formula 1 expression around each rotation.
Thus, by using these spin matrixs, the magnetic field that newly applies becomes the magnetic field that utilizes following formula 2 represented.
Wherein, Hx ' is (t+Ts) |
V (t)=0, Hy ' (t+Ts) |
V (t)=0, Hz ' (t+Ts) |
V (t)=0Be respectively x ', the y ' at V (t)=0 o'clock t+Ts place, the magnetic field of z ' direction.
On the other hand, the magnetic field that is produced by three Helmholtz coils becomes (Hx (t) Hy (t) Hz (t)) when moment t.
And, when using the direction of ψ (t), θ (t) expression capsule 3, become as shown in Figure 13.When the magnetic field side also when x ', y ', z ' are transformed to this x, y, z coordinate system, when moment t+Ts, become formula 3.
Wherein, the R in the formula 3
(t) z, R
0 (t) yExpression with around the angle ψ of the z of Figure 13 axle (t), around the corresponding spin matrix of rotary manipulation of the angle θ of y axle (t).
Calculate by repeating these, can calculate the magnetic field that produces from the outside.
Generally, the magnetic field of coil generation can be expressed as:
H=I·N
H: magnetic field, N: coefficient, I: electric current
So the control electric current I, promptly I=H/N gets final product.
When the coefficient N of three Helmholtz coils was made as Nx, Ny, Nz respectively, electric current I x (t), the Iy (t), the Iz (t) that flow through coil can utilize formula 4 expressions.
About capsular directional information,
(1) under situation,, uses θ (t), ψ (t) according to the testing result of position detection unit with locality detecting unit.Locality unit (pick off) as this moment can use the AURORA of NDI corporate system etc.
(2) when not having position probing, input θ (0), ψ (0) (initial value) carry out.
When asking the direction X (t) of capsule 3 after this, Y (t), Z (t), the direction that wushu 5 is defined as capsule 3 gets final product.
And capsule shown in Figure 3 (medical treatment device 3) disposes magnet 16 at the central part that becomes this medical treatment device main body.Figure 14 represents the internal configuration diagram of capsule 3.
Disposing object lens 13, illumination component 15, the imaging apparatus 14 that is installed on (on the object lens frame 51) in the observation window end.In addition, dispose signal processing circuit 20 (being built-in with memorizer 21 herein), radio-circuit 22, dispose magnet 16 in its back.Dispose battery 24 and on-off circuit 71 at opposition side across the observation reveal of magnet 16.Utilization is connected up to each unit as the flexible substrate 56 of routing cell, the capsule medical apparatus 3 of the action that the formation realization illustrates previously.By such configuration, can be configured in magnet 16 on the core of capsule medical apparatus 3 main bodys.And in this configuration, the position of magnet 16 is near the position of centre of gravity of capsule medical apparatus 3.
Thus, rotary driving force by applying capsule medical apparatus 3 main bodys that magnetic field produces from the outside etc. produces near the center of gravity of capsule medical apparatus 3 main bodys.
Therefore, can carry out stable control to capsule medical apparatus 3.
But under following situation, sometimes, configuration magnet 16 more can not improve controlled near the center of capsule medical apparatus.
Figure 15 is the configuration that changes magnet 16, battery 24, on-off circuit 71 with respect to Figure 14, magnet 16 is configured in the opposition side of observing reveal the end variation capsule 3 '.
In this structure, more favourable when the inner guiding of tube chamber of broads such as large intestine.
Under the situation of carrying out the action shown in Figure 18 (B), when as Fig. 3 or shown in Figure 14, when magnet 16 being configured near the center of capsule 3, when applying oscillating magnetic field, the main body of capsule 3 is pressed vibration shown in Fig. 6 (A), Fig. 6 (B).
Relative therewith, by under the situation of configuration magnet 16 shown in Figure 15, when applying oscillating magnetic field, vibrate by shown in Figure 17, make the amplitude of observation window side end of capsule body become big.Owing to can move like this, so even in bigger tube chamber, also can guarantee (increase) lumen wall and capsule 3 ' mate.
Therefore, can guide capsule 3 even have in bigger tube chamber also ' effect.
And, in Figure 16, make magnet 16 form hollow structure, and inserted logical being fixed on the object lens frame 51.By forming this structure, can be configured in capsule 3 to magnet 16 " the end of observation reveal near.
Compare the capsule 3 that guiding (changing the action of direction) Figure 16 is described with capsule 3 among Fig. 3, Figure 14 " time the difference of motion.
Shown in Figure 18 (A), in the capsule 3 of Fig. 3 or Figure 14, (position of magnet 16) is the action that the center changes direction near the center with this capsule 3.Under the rapid crooked situation of the route of tube chamber, there is the situation that is difficult to guarantee radius of turn, guided bone reduction sometimes under this situation along tube chamber.
Relative therewith, at the capsule 3 of Figure 16 " in carry out following action.
That is shown in Figure 18 (B), be that the center changes direction near the observation window of capsule 3 " with capsule 3 ",, so guarantee radius of turn easily.
Therefore, have and can improve capsule 3 " the effect of guided bone.
Present embodiment according to above explanation, even tube chamber that capsule 3 grades will be passed through greater than the situation of the external diameter of capsule 3 grades under or narrow, or under the crooked situation, can both make smooth and easy passing through such as capsule 3, can be directed to the target site side to capsule 3 grades at short notice.
And, compare with example in the past, can make fast moving in tube chamber such as capsule 3 grades, so can be directed to the target site side to capsule 3 grades at short notice.
(the 2nd embodiment)
Below, with reference to Figure 19 the 2nd embodiment of the present invention is described.Figure 19 represents the capsule 3B of the 2nd embodiment of the present invention.The internal structure of Figure 19 (A) expression capsule 3B, Figure 19 (B) represents from the observed pager motor of rear end side (pager motor) 57 parts.
In the 1st embodiment, interior magnet 16 in capsule 3, by apply the oscillating magnetic field with the vertical direction of rotating excitation field with rotating excitation field from the outside, the effect couple is so that capsule 3 makes the central shaft C of capsule 3 tilt passively, but in the present embodiment, to capsule 3B effect tilting force or vibration force so that it makes the central shaft C of capsule 3B tilt on one's own initiative.
Having disposed the cylindric object lens frame 51 that object lens 13 are installed with these observation window 17 opposed inside, on the image space of object lens 13, dispose the imaging apparatus substrate 52 that imaging apparatus 14 has been installed, around object lens frame 51, disposed illumination component 15.
The substrate 54 of communicating by letter that is adjacent to dispose the control substrate 53 that carries out signal processing and control with imaging apparatus substrate 52 and has the function of radio-circuit 22 etc. is connecting antenna 55 on communication substrate 54.And illumination component 15, imaging apparatus substrate 52 etc. is electrically connected by flexible substrate 56.
And, on the central shaft C of the length direction of this capsule 3B, configuration magnet 16 on the heart position therein, make with the vertical direction of this central shaft C be its length direction, and utilize not shown bonding agent etc. to fix.
And, be adjacent to taking in battery 24 with this magnet 16, and be connected with flexible substrate 56 by not shown switch.In addition, near the incorporating section the rearward end of the capsule 3B adjacent, taking in and be used to make this capsule 3B from the direction off-centre of central shaft C or the pager motor 57 of rocking vibration with this battery 24, and by flexible substrate 56 with control substrate 53 etc. and be connected.
This pager motor 57 for example is made of with the hammer portion 59 that is arranged on this supersonic motor 58 supersonic motor 58.
Shown in Figure 19 (B), the hammer portion 59 that is roughly circular cone or fan shape is installed on the rotating shaft 58a of supersonic motor 58, hammer portion 59 rotates along with the rotation of the rotor-side of supersonic motor 58, form the position of centre of gravity change mechanism that position of centre of gravity changes according to the position of this hammer portion 59, capsule 3B carries out oscillating motion (vibration) along with the rotation of hammer portion 59 thus.
And, capsule 3B with in the 1st embodiment, illustrate identical, have the communication unit that communicates with external blood processor 6.
In the 1st embodiment, when the operation of the vibroswitch 8f that has carried out making operation input equipment 8, control circuit 27 controlling magnetic field generators 4 in the blood processor 6 and produce oscillating magnetic field, but in the present embodiment, control circuit 27 sends to capsule 3B side to its index signal by radio-circuit 25.
And when capsule 3B had received this index signal and understood this order, capsule control circuit 23 (with reference to Fig. 2, being control substrate 53 in Figure 19) made pager motor 57 actions.And when disconnecting the operation of vibroswitch 8f, capsule 3B stops the action of pager motor 57.In addition, about rotating excitation field, carry out the effect identical with the 1st embodiment.
The action of the present embodiment that constitutes like this is described.
Operation when in the present embodiment, making capsule 3B rotation is identical with the 1st embodiment.And, in the time of for example need in the tube chamber internal organs of bending, advancing more swimmingly, press the vibroswitch 8f that is arranged on as shown in Figure 2 on the input device 8.Like this, the information of vibration unlatching passes to radio-circuit 25 by control circuit 27.
The information that vibration is opened is delivered to capsule 3B by radio communication.The capsule control circuit 23 of capsule 3B receives this signal, starts the rotation of pager motor 57.
Thus, capsule 3B produces central shaft C inclination that makes capsule 3B or the power (simulation couple) of shaking, the action that can make capsule 3B vibrate or wave on one's own initiative by mimic couple (that is, with a side's who forms couple the suitable power of power).Apply rotating excitation field and obtain the method for propulsive force identical with the 1st embodiment.
In addition, if set the signal of rotating speed of indication pager motor 57, then can change the frequency of vibration by radio communication.
According to present embodiment, even do not apply oscillating magnetic field from the outside, the also action that can make capsule 3B vibrate or wave by shirtsleeve operation.
And, even capsule 3B is not being applied under the state of rotating excitation field, also can utilize the helical form projection 43B that is arranged on the capsule 3B, by the vermicular movement of intravital tube chamber internal organs and capsule 3B is being rotated advance, even therefore under the situation of the minisystem structure of not using the magnetic field generation device 4 that produces rotating excitation field, also can make capsule 3B vibration according to present embodiment, can make capsule 3B pass through crooked position etc. swimmingly.
(the 3rd embodiment)
Below, with reference to Figure 20~Figure 21 (B) the 3rd embodiment of the present invention is described.Figure 20 represents the capsule 3C of the 3rd embodiment of the present invention, Figure 21 (A) expression o device part, and Figure 21 (B) is illustrated in the capsule type endoscope that one-sided end is provided with flexible pipe.
As shown in figure 20, taken in o device 64 near the rearward end of the capsule 3C adjacent incorporating section with battery 24, its agitator 63 by magnetic shield framework 62 and driving o 61 constitutes, magnetic shield framework 62 be built-in with can make this capsule 3C with the vertical direction of the direction of central shaft C on magnetized o 61 etc., and cover this o 61 and make and be not subjected to influences from the magnetic field of outside.
And, with illustrated in fig. 19 identical, when the vibration On/Off signal that produces when the operation of the vibroswitch 8f of the input device 8 by the outside is sent to capsule 3C, the capsule control circuit 23 of control substrate 53 receives this signal, to send to agitator 63 after the demodulation of On/Off signal, make agitator 63 vibrations.This agitator 63 produces the electric current that is used to drive o 61 of the frequency range from direct current to tens of approximately Hz.
In addition, the drive condition of the frequency of oscillation of agitator 63 can set in advance, and also can constitute all right input frequency signal except the On/Off signal, can control from the outside.
When the output signal of above-mentioned agitator 63 as driving signal during to o 61 energisings, o 61 magnetization (generation magnetic field).
And, the direction of magnetization according to o 61, can make the hammer portion 66 that for example constitutes that parts 65 keep movably that is directed to by magnet, the elastic force of the spring 67 that opposing applies to the end (in Figure 20 and Figure 21 (A) for top) of guiding parts 65, guiding parts 65 axially on move back and forth.Follow moving back and forth of this hammer portion 66, capsule 3C guiding parts 65 axially on vibration.
Figure 21 (A) amplifies the structure more specifically of expressing o device 64 parts.O 61 and be connected fixing respectively by biasing member 68a, 68b with the guiding parts 65 of these o 61 configured in parallel.
In addition, be provided with block 69, utilize these block 69 restriction hammer portions 66 to move again downwards from assigned position in biasing member 68b side.
And in the present embodiment, biasing member 68a is formed by nonmagnetic material, and biasing member 68b is formed by magnetic.In addition, o 61 is controlled by the capsule control circuit in the capsule 3C.
And the action control of o 61 can be undertaken by the input device 9 of external blood processor 6.
Identical with the situation of Figure 19, pass to capsule 3C from the signal based on operation input of input device 8 by radio-circuit 25, and pass to capsule control circuit 23.According to this signal, capsule control circuit 23 control os 61.
When utilizing interchange to drive signal to o 61 energisings, its direction of magnetization changes, thereby the hammer portion 66 that is formed by magnet is moved back and forth on above-below direction.
Therefore, the centre-of gravity shift of capsule 3C, effect makes the power of capsule 3C around the axle rotation (or banking motion) of length direction.
Thus, under the situations such as propelling difficulty of capsule 3C, can improve trafficability characteristic.
In addition, also can replace utilizing the output of agitator 63 to drive o 61 with exchanging, and the on/off of switching on repeatedly.Under this situation, can form by magnet, also can form by magnetic as hammer portion 66.That is, carry out when connecting, moving, being moved upward by the elastic force of spring 67 when disconnecting the action of (resetting) repeatedly downwards.
That is, drive identically, can produce the power that capsule 3 is periodically waved with the output that utilizes agitator 63.The effect of this moment and the situation of pager motor 57 are roughly the same.
And, form the structure of utilizing o 61 that hammer portion 66 is moved in the present embodiment, for example, also can form and ultrasonic linear motor is configured to vertical, the drive division of ultrasonic linear motor is applied attached heavy structure with the insertion direction of principal axis of capsule medical apparatus.
And, in embodiment, narrate whole are capsule endoscopes, but in arbitrary embodiment, all be not limited to capsule endoscope, for example shown in Figure 21 (B), the one-sided end that is formed on capsule endoscope is provided with rotational slide portion, and the structure of the guider of catheter-like is set, also can obtain same effect.In addition, the inside that also can be formed on endoscope is provided with the structure that the arbitrary vibration unit shown in above-mentioned makes the endoscope distal end vibration.
(the 4th embodiment)
Figure 22~Figure 30 relates to the 4th embodiment of the present invention, Figure 22 is the overall structure figure of summary structure that expression has the capsule medical instrument guidance system of the 4th embodiment of the present invention, Figure 23 is a block diagram of representing the structure of Figure 22 in further detail, Figure 24 is the summary construction diagram of the summary structure of expression magnetic field generation device, Figure 25 is the side view of the outward appearance of expression capsule medical apparatus, Figure 26 is the cutaway view of the internal structure of expression Figure 25 shown device, Figure 27 is the side view of expression tank, wherein the capsule with sample is inserted in the silicone tube, measure fltting speed to apply rotating excitation field, Figure 28 is that the expression end is provided with the figure of the measurement of helical form projection with sample, Figure 29 is the figure of the measurement result of expression fltting speed, and Figure 30 is the key diagram that is illustrated in the effect when advancing in the crooked pipeline.
As Figure 22, Figure 23 and shown in Figure 24, encapsulated medical device guiding system (the following capsule guiding system that slightly is called) 101 has: the capsule medical apparatus of capsule shape (being designated hereinafter simply as capsule) 103, be inserted in (shown in Figure 1) patient 102 the body cavity, be used to check body cavity inside; Capsule control device (being designated hereinafter simply as control device) 104 is made of personal computer etc., is configured in this patient's 102 outside, carries out the electric wave transmitting-receiving with capsule 103, controls the action of this capsule 103, or receives the information that sends from capsule 103; Magnetic field generation device (schematically illustrated in Figure 22) 105 is controlled the direction of the rotating excitation field that imposes on capsule 103 etc., is wanting guide capsule 103 on the propulsive direction; Ac power supply apparatus 106, supply are used to make this magnetic field generation device 5 to produce the alternating current power supply in the magnetic field (being electromagnetic field more in a broad aspect) of rotation.
As shown in figure 23, magnetic field generation device 105 is for example formed by 3 electric magnet 105a, 105b, 105c, and the alternating current power supply by control is supplied with from ac power supply apparatus 106 can produce rotating excitation field on three direction of principal axis.In addition, in Figure 24, utilize (the hollow cube shape) three Helmholtz coils that on three direction of principal axis, form that magnetic field generation device 105 schematically is shown.
As shown in figure 23, configuration produces the magnetic field generation device 105 of rotating excitation field around patient 102, from control device 104 sides ac power supply apparatus 106 is controlled, for being configured in capsule 103 inside in the body cavity pipeline that is inserted into patient 102, magnetic field being produced response and (as magnetic responsiveness portion) magnet 108 of active force, apply rotating excitation field making on the capsule 3 propulsive directions, thus can be swimmingly and advance (guiding) capsule 103 effectively.
Control the direction of the rotating excitation field that this magnetic field generation device 105 produces by being operationally connected to input device 9 on the control device 4.
As shown in figure 22, control device 104 has: personal computer main body 111 has the function of control capsule 103 and magnetic field generation device 105 (alternating current power supply 107); Keyboard 112 is connected on this personal computer main body 111, carries out the input of order, data etc.; Monitor 113 is connected on the personal computer main body 111, as the display unit of display image etc.; External antenna 114 is connected on the personal computer main body 111, sends the control signal and the signal that receives from capsule 103 that are used to control capsule 103; Input device 109 is connected on the personal computer main body 111, and direction of rotating excitation field etc. is carried out input operation.
Described control device 104 as shown in figure 23, be built-in with CPU 115, CPU 115 is according to from the input of keyboard 112 and input device 109 or be stored in hard disk 116 (with reference to Figure 23) in the personal computer main body 111 control sequence in waiting, and generation is used to control the control signal of capsule 103 and magnetic field generation device 105.
The control signal that is used for controlling magnetic field generator 105 passes to ac power supply apparatus 106 from personal computer main body 111 by connection cord.Then, produce rotating excitation field according to this control signal.Capsule 103 constitutes, and by this rotating excitation field, by the rotating excitation field that produced by magnetic field generation device 105 magnet 108 of inside is carried out magnetic action, makes capsule 103 rotations, utilizes thrust described later to produce structural portion thus and obtains to be used for propulsive power.
On the other hand, the control signal of control capsule 103 utilizes the carrier wave of preset frequency to modulate through the oscillating circuit in the personal computer main body 111, sends from external antenna 114 as electric wave.
And capsule 103 utilizes antenna 127 described later to receive electric wave, demodulates control signal and exports to each forming circuit etc.
And, information (data) signal of the video signal that control device 104 utilizes external antenna 114 to receive to send from the wireless antenna 127 of capsule 103 etc., and be presented on the monitor 113.
As shown in figure 23, in capsule 103, except that the objective lens optical system 121 that forms optical image, be configured in imaging apparatus 122 on its image space, be configured in illumination component 123 around the objective lens optical system 121, the magnet 108, also taking in: signal processing circuit 124, the signal of being taken by imaging apparatus 122 is carried out signal processing; Memorizer 125, the digital video signal that interim storage is generated by signal processing circuit 124; Radio-circuit 126 utilizes high-frequency signal to modulate the video signal of reading from memorizer 125, thereby is converted to the signal of wireless transmission, perhaps the control signal that sends from control device 104 is carried out demodulation; Antenna 127 carries out the transmitting-receiving of electric wave with external antenna 114; Capsule control circuit 128, control capsule 103 is as signal processing circuit 124 etc.; Battery 129, the power supply of using to the electrical system supply work of 103 inside such as signal processing circuit 124 capsules such as grade.
And, constitute the personal computer main body 111 of carrying out the control device 104 of radio communication and have with this capsule 103: radio-circuit 131, be connected on the external antenna 114, carry out radio communication with (capsule 103 sides) radio-circuit 126; Data processing circuit 132 is connected on the radio-circuit 131, the view data that sends from capsule 103 is carried out the date processing of pictorial display etc. etc.; As the CPU 115 of control unit, control data treatment circuit 132 and ac power supply apparatus 106 etc.; The hard disk 116 of storage program and data etc., on CPU 115, connecting the direction of setting rotating excitation field operation input device 109 and carry out order and the keyboard 112 of data inputs.
On data processing circuit 132, connecting monitor 113, showing by imaging apparatus 122 and take, carried out the image of processing etc. through radio-circuit 126,131, by data processing circuit 132.And, because photographic images in capsule 103 rotations, so this data processing circuit 132 carries out the processing that the correction for direction of the image when showing is certain direction on monitor 113, and carries out Flame Image Process, so that can show the image that operative doctor is observed easily.
Figure 25 represents the profile of capsule 103, and Figure 26 represents its internal structure.
As these Figure 25, shown in Figure 26, capsule 103 for example is covered with airtightly by the main body exterior member 140 of hemispherical transparent drive end bearing bracket 139 with the drum that hermetic is connected with this drive end bearing bracket 139, forms inner airtight capsule body 141 roughly cylindraceous.In addition, the rear end of this main body exterior member 140 forms roughly hemispherical.As shown in figure 26, this capsule body 141 forms the symmetric profile of the rotating revolution of central shaft C that makes to the length direction of direct of travel.
And, turn round on the outer surface of symmetric capsule body 141 at this, the propelling generation helicoidal structure body that is converted to propulsive force rotatablely moving is set.This helicoidal structure body is provided with helical form jut 143, and its cylindric outer peripheral face (basal plane) 141a helically from capsule body 141 is outstanding, and the contact cavity wall, is converted to propulsive force rotatablely moving.And, between adjacent helical form jut 143, form and can be communicated with fluidic helicla flutes such as endoceliac gas and body fluid in front and back.
Take in built-in things such as disposing above-mentioned object lens 121, illumination component 123 in these capsule body 141 inside.
Specifically, object lens 121 are under the state of being installed on the cylindric camera lens frame 144, be configured in the central part of drive end bearing bracket 139 inboards in the capsule body 141, on the image space of these object lens 121, dispose the imaging apparatus substrate 145 that imaging apparatus 122 has been installed, around camera lens frame 144, dispose a plurality of illumination components 123.
Be adjacent to the substrate 147 of communicating by letter that laminated configuration is carried out the control substrate 146 of signal processing and control and had the function of radio-circuit 126 etc. with imaging apparatus substrate 145, on communication substrate 147, connecting antenna 127.And illumination component 123, imaging apparatus substrate 145 etc. are electrically connected by flexible substrate 148.
And on the central shaft C of the length direction of this capsule 103, configuration magnet 108 makes its length direction become the vertical direction with this central shaft C on the approximate centre position of its length, and utilizes not shown bonding agent etc. to fix.
And, be adjacent to taking in battery 129 with this magnet 108, and be connected with flexible substrate 148 by on-off circuit 149.
Described magnet 108 is configured on the center on the central shaft C of capsule body 141, have the direction of magnetization on the direction that with respect to central shaft C is the right angle, thereby for this capsule 103, the rotating excitation field that is produced by magnetic field generation device 5 acts on magnet 108, by the revolving force that this magnet 108 is subjected to, make capsule 103 rotations.
In addition, the magnet of Shi Yonging (Magnet) the 108th herein, the permanent magnet of neodium magnet, SmCo Magnet, ferrite magnet, siderochrome cobalt magnet, platinum Magnet, aluminum nickel cobalt (AlNiCo) Magnet etc.
Rare earth element magnet magnetic force such as neodium magnet, SmCo Magnet are strong, have to make to be built in the advantage that the Magnet in the capsule diminishes.On the other hand, ferrite magnet has advantages of cheap price.In addition, platinum Magnet corrosion resistance is good.
And, in the present embodiment, as shown in figure 25, be formed at the helical form jut 143 on the outer surface of capsule body 141, its front extends to the side that undergauge is a semi-spherical shape through the cylinder outer peripheral face, its end 143a is formed on the part midway that undergauge is a semi-spherical shape, specifically is formed on the position in the angle of visibility that does not enter object lens 121.And it is hemispheric boundary vicinity that the rear end 143b of this helical form jut 143 extends to undergauge.In addition, in the example of Figure 25, helical form jut 143 also is provided with helical form jut 143 on the centre position of a helical form jut 143, and forms dual (two) jut.
Like this, in the present embodiment, helical form jut 143 is set on the outer surface of capsule 103, and one end thereof 143a is formed up near the position, end that arrives reducing diameter part.Promptly, be characterised in that on the cylinder outer peripheral face part of capsule body 141 and also form this helical form jut 143, and end 143a forms and extends to the radius for example dome shape part of undergauge of comparing cylinder, arrives the boundary position in the angle that do not come into view.
Like this, by helical form jut 143 being arranged to arrive near the end of capsule body 141, as described below, can improve propulsion functions.
Figure 27 represents to adopt near the structure this end of helical form jut 143 being arranged to reach capsule body 141 to measure the tank that fltting speed is used.Under the state of (contour structures) sample (being made as the 1st sample) in the silicone tube that is inserted into simulation tube chamber internal organs with capsule 103 of present embodiment, be inserted in this tank, from above add under entry applies hydraulic pressure to pipe the state (for example water level is 20cm), apply rotating excitation field from the outside, for example make sample move 2cm, measure its fltting speed.
And, for only being formed at, helical form projection in the 1st sample relatively uses sample (being made as the 2nd sample) on the barrel surface part, also measured fltting speed with the same terms.Figure 28 represents the profile of the 1st sample.In addition, the 2nd sample is in the 1st sample shown in Figure 28, only is provided with the helical form projection on cylindrical portions may.
The measurement result that Figure 29 (A), Figure 29 (B) expression uses these samples to obtain.Marking and drawing its meansigma methods after measurement result shown in Figure 29 (A), Figure 29 (B) is carried out 10 times obtains.And, be to carry out under the condition of 0.5Hz, 1Hz, 5Hz in the frequency of rotating excitation field.
And, suppose that fltting speed and frequency are proportional, utilize method of least square to depict and be similar to collinear line.
Figure 29 (A) represents identical experimental result with the scale that Figure 29 (B) changes frequency, speed.The data of representing with circle are data that the sample (in Figure 29 abbreviate do not have front end for simplification) that utilizes front end that the helical form projection is not set obtains in addition, and the data of representing with triangle are data that the sample that utilizes front end also to be provided with the helical form projection obtains.And, the frequency till in Figure 29 (A), representing 5Hz, the situation of speed, Figure 29 (B) amplifies the measurement result of representing till the 1Hz.
According to these measurement data, we can say that near the situation that the helical form projection is not set situation that the helical form projection is set to the end always and the end compares, fltting speed is big, is approximately 1.4 times of the latter.This helical form projection that can be described as the end helps to produce propulsive force.
Other characteristic effects of the capsule 103 of present embodiment are described with reference to Figure 30 (A), Figure 30 (B) in addition.
Shown in Figure 30 (A), Figure 30 (B), for example suppose in the tube chamber internal organs 155 of bending, in the time of need on its crooked direction, advancing, shown in Figure 30 (B), if only on cylindrical portions may, be provided with the capsule 103 of helical form jut ', even then rotation, helical form jut also are difficult for the jog engagement with the gauffer of the internal face of tube chamber internal organs etc., be difficult to advance swimmingly.
In this state, in the present embodiment, shown in Figure 30 (A), because helical form jut 143 is formed near the end behind the undergauge always, so when rotated, by be formed into always near its end helical form jut 143 and with the jog engagement of the internal face of tube chamber internal organs, can advance capsule 103 more swimmingly.
Like this, in the present embodiment, it is characterized in that, the helicoidal structure body also is set near the end of undergauge, helical form projection 143 specifically is set, by this capsule 3 is rotated driving, propulsive force can be improved, the target site side can be arrived at short notice, and under the situation of the pipeline of bending, also can be by near the helical form projection 43 that is formed at the end, advance more swimmingly along the pipeline of bending.
The action of the capsule guiding system 101 that is provided with helical form jut 143 then, is described below.
As shown in figure 22, observe the body cavity pipeline of patient 102 for example duodenum 151 sides or small intestinal side etc. when inner at needs, the operator allows patient 102 152 swallow capsule 103 from the oral cavity.
In addition, at this moment, the operator is being about to allow before patient 102 swallows, and connects the on-off circuit 149 of capsule 103 in advance, and the electric power of battery 129 is delivered to illumination component 123 etc.Meanwhile, the operator starts (connection) magnetic field generation device 105, utilizes the rotating excitation field that is produced by this magnetic field generation device 105, carries out magnetic control and makes capsule 103 arrive the target site side easily in the body cavity pipeline.
As mentioned above,, do the time spent in 108 pairs of rotating excitation fields generations that produce by magnetic field generation device 105 of magnet for capsule 103, by the effect that this magnet 108 is subjected to, capsule body 141 rotations.And when capsule body 141 contact cavity walls, the frictional force between the mucosa of this body cavity walls and the helical form jut 143 is converted into big propulsive force, thereby capsule 103 advance and retreat move.And capsule 103 is along with the rotation of rotating excitation field, change direct of travel in capsule body 141 rotations (towards), make that the Plane of rotation of magnet 108 is consistent with the Plane of rotation of rotating excitation field.
At this moment, for capsule 103, can in tube chamber, pipeline, head for target position side advance capsule body 141 swimmingly.
And when needs were observed stomach 154 inside, the operator carried out the key input corresponding with observing initiation command from for example keyboard 112 of control device 104.Thereby, the control signal that forms by the input of this key through the external antenna 114 of control device 104, utilize electric wave to launch, send to capsule 103 sides.
This electric wave is received by the external antenna 114 of control device 104, and demodulation in the radio-circuit in personal computer main body 111 131, carry out the A/D conversion again, be converted to the video signal of numeral by data processing circuit 132, store in the memorizer or hard disk 116 of data processing circuit 132, and read with predetermined speed, the optical imagery of on monitor 113 imaging apparatus 122 being taken carries out colour and shows.
The operator can observe patient 102 stomach 154 inside etc. by observing this image.Observing the operating units such as stick that use input device 109 when this observes image, can easily control the mode that applies of outside magnetic force, so that can observe the Zone Full in the stomach 154.
In addition, after the observation of stomach 154 inside finishes, can control the direction of the rotating excitation field that produces by magnetic field generation device 105, thus to capsule 103 carry out magnetic guiding make its from stomach 154 to duodenum 151 side shiftings.And, in duodenum 151, also can capsule 103 be advanced along the direction of its tube chamber, thereby advance capsule 103 swimmingly by the direction of control rotating excitation field.
And, when in pipeline crooked as small intestinal, advancing, as explanation among Figure 30 (A), because helical form projection 143 is formed near the dome shape end of capsule body 141 always, so can make capsule 103 smooth and easy advancing in the pipeline of bending.
Like this,, can advance capsule 103 swimmingly, check the required time, and can alleviate operative doctor and patient's burden and fatigue etc. so can shorten according to present embodiment.
And the capsule 103 of present embodiment does not carry out useless moving, and introduction by magnetic field efficient correspondingly improves, and has the effect of the magnet 108 that can make in the capsule body 141 and external electric magnet 105a~105c miniaturization.
(the 5th embodiment)
Below, with reference to Figure 31 the 5th embodiment of the present invention is described.Figure 31 represents the capsule 103B of the 5th embodiment of the present invention.In the capsule 103 in the 4th embodiment, make the rear end 143b of helical form jut 143 be in the anterior position of the rear end that arrives capsule body 103, but the rear end 143b that this capsule 103B then makes helical form jut 143 extend and is formed near the end of capsule body 141 to rear side more.
Other structures are identical with capsule 103 in the 4th embodiment.
As the effect and the effect of present embodiment, under situation about moving rearward, also can move efficiently, and under the situation that the rear side to bending moves, also can move swimmingly.
Figure 32 represents the capsule 103C of the 1st variation.Profile with respect to capsule 103B shown in Figure 31 is roughly semi-spherical shape, thereby the external diameter of this capsule 103C forms the leaf roll shape from front end to the rear end smooth change.
Because the external diameter of this capsule 103C from front end to the rear end smooth change, so have the property inserted good effect and effect.
Figure 33 represents the capsule 103D of the 2nd variation.In capsule 3D shown in Figure 33, the profile of its capsule body 141 is: the two ends undergauge that forms the cylindrical portion of central part is the tapering 161 of taper (cone shape).And front and rear end side form picture plane as cutting off.
Because drive end bearing bracket side and rearward end side undergauge are taper, so the property inserted is good.And, owing to the shape that forms as looking like to cut off, so can realize miniaturization.
Figure 34 represents the capsule 103E of the 3rd variation.Capsule 103E shown in Figure 34 is among the capsule 103D in Figure 33, be not that leading section and rearward end are formed is plane, but slyness becomes roughly dome shape.
That is, in this capsule 103E, the profile of capsule body 141 is: the cylindrical portion two ends undergauge that forms central part is the tapering 161 of taper (cone shape).And the end of front and rear end side is roughly dome shape.
It is taper that this variation makes drive end bearing bracket side and rearward end side undergauge, so the property inserted is good.
Figure 35 represents the capsule 103F of the 4th variation.In capsule 103F shown in Figure 35, for the helical form projection 143 on the outer surface that is formed at capsule body 141, for example form the spacing b of projection 143 and be formed at the external diameter front little and the spacing a and the c of the projection 143 of rear end side on partly are equidistant from distance, promptly set a=b=c for than it at the helically on the external diameter the best part of central part.
Like this, fix by the spacing that makes the helical form projection 143 on the outer surface that is formed at capsule 103F, thereby under the situation about being pushed in capsule 103F rotation and with the concavo-convex engagement of the internal face of tube chamber internal organs, because can think the concavo-convex almost fixed of internal face of tube chamber internal organs, so can advance capsule 103 effectively.
And, because spacing fixes, thus make man-hour feed fixing adding with respect to rotating to be of lathe, thus can make handling ease, and can be with the low cost manufacturing.And the feed in one week of partial rotation that the feed in one week of partial rotation that diameter is less and diameter are bigger is identical, so capsule 103F integral body can produce thrust effectively.
In addition, can also form the 5th variation of the following stated.
Aforesaid each capsule 103B etc. is the cordless type that does not have line or pipe at the rear portion, but also can form what the rearward end (opposition side of drive end bearing bracket 39) of this capsule 103B etc. was installed the pliability pipe that can rotate freely rope type capsule medical apparatus is arranged.
Under this situation, the propelling by making the helicoidal structure body and the push-and-pull of pipe combine, and have the effect that can make capsule medical apparatus more effectively advance or retreat.
(the 6th embodiment)
Below, with reference to Figure 36 (A), Figure 36 (B) the 6th embodiment of the present invention is described.The capsule 103G of Figure 36 (A) expression present embodiment, Figure 36 (B) expression is obtained example images by what this capsule 103G obtained.
Capsule 103G shown in Figure 36 (A) forms for example in the capsule 103B of Figure 31, in helical form projection 143, be provided with the hollow structure of hollow bulb 162 along its length direction, form the opening 162a of opening at the end of its front 143a, and make this end 143a extend to the position that becomes the angle of visibility inboard always, can be shown in Figure 36 (B) like that (according to obtaining image) observe this end 143a.
And, in this capsule 103G, inside at capsule body 141 is provided with hollow bulb, and form the incorporating section 164 to store medicament 163, between the pipe 165 of the hollow bulb 162 that connects this incorporating section 164 and helical form projection 143, setting is sent driving (emitting driving) or is sucked the micropump 166 that drives, the medicament 163 that is stored in the incorporating section 164 is emitted through the hollow bulb 162 of the helical form projections 143 opening 162a from front end, thereby can handle the treatment that affected part etc. carries out delivering medicament.
And above-mentioned micropump 166 can counter-rotating, sucks substance in vivo such as body fluid thus from opening 162a and is accommodated in the incorporating section 164.For example, at first emit the medicament 163 that is stored at the incorporating section 164 to affected part etc. from opening 162a, make micropump 165 counter-rotatings then, thereby substance in vivos such as body fluid are accommodated in the incorporating section 164, after capsule 103G discharged in the body, can take out the substance in vivo of incorporating section 164 from capsule 103G, carry out detailed inspection.
According to present embodiment, can be used to emit medicament 163 to helical form projection 143 as the helicoidal structure body, so can be used to the helicoidal structure body to advance and the emitting of medicament 163, can realize small-sized, have the function of carrying out endoceliac shooting and the medicament that is used for the treatment of emitted the capsule 103G of function.
And, also can realize also having the capsule 103G that collects the function of material in endoceliac body fluid and other body cavitys.
And, extend to the position that becomes the angle of visibility inboard by the end 143a that makes helical form projection 143 always, can further improve propulsive force, and emitting medicament 163 from the opening 162a that is located at end 143a, perhaps suck under the situation of substance in vivo, can confirm this action according to obtaining image.
In addition, also can only be used for emitting of medicament 163 to the capsule 103G of Figure 36, or only be used for the suction collection of substance in vivo.
Also can various pick offs such as pressure transducer, pH pick off, temperature sensor, blood sensor be set at the hollow bulb opening 162a of described helical form projection 143, and along the wiring of hollow bulb 162 sensors configured.About pick off, can different types of pick off be set to each of a plurality of helical form projections 143, the pick off of identical type also can be set.Under this situation, can when emitting medicament 163 or collecting body fluid, utilize image to confirm position, the position of measuring, so convenient more by pick off.
Figure 37 represents the capsule 103H of variation.This capsule 103H is the incorporating section 164 that capsule 103 inside are not set in the capsule 103G of Figure 36 (A), makes the micropump 166 of being located at capsule 103H inside by managing 165 hollow bulbs 162 that are connected to two helical form projections 143 of dual setting.
And when making micropump 166 to the rotation of clockwise direction for example, micropump 166 carries out the action that sucks from the downward side of upside in Figure 37, can suck body fluid etc. in the hollow bulb 62 of the helical form projection 143 shown in Figure 37 midship section and storage.
And, by making micropump 166 counter-rotatings, can be also storing in the hollow bulb 162 of another helical form projections 143 of suction such as body fluid.
That is, in this variation, can be in the hollow bulb 162 of the helical form projection 143 of dual setting, for example suck the substance in vivo of collecting body fluid etc. respectively, need the material checked at different parts.This variation has the effect roughly the same with the capsule 103H of Figure 36.
In addition, replace the magnet 108 that is built in capsule 103 grades, also can utilize ferromagnetism body or magnetic formation such as ferrum as electromagnetic field response portion.And, also can not apply magnetic field, and apply electric field, built-in electrical body or electrolyte in capsule 103 grades.
In addition, above-mentioned each embodiment etc. is carried out the part combination and the embodiment that constitutes etc. also belong to the present invention.
In the present invention, certainly under the situation that does not break away from the spirit and scope of the present invention, in wide region, constitute different embodiments according to the present invention.The present invention is not subjected to the restriction of its specific implementations except the qualification that is subjected to incidental claim.
Utilizability on the industry
As mentioned above, according to medical treatment device of the present invention, medical device induction system, capsule-type doctor Therapeutic apparatus and capsule-type medical device guide device, guiding is inserted into endoceliac medical treatment in body cavity During apparatus main body, can improve endoceliac by performance, and by making the medical treatment device rotation, Can be directed to the target site side along tube chamber internal organs inside at short notice, be used for endoceliac Observe and very useful during various metacheirisises etc.
The cross reference of association request
The application is to be the application on the basis of claim of priority with patent application 2003-288273 number of submitting in Japan in patent application 2003-291771 number of submitting in Japan on August 11st, 2003 and on August 6th, 2003.Above-mentioned content is cited in the application's description, claims, accompanying drawing.
Claims (64)
1. one kind has the medical treatment device that is inserted into endoceliac insertion section, it is characterized in that, comprises the couple generation unit, and this couple generation unit produces the couple with position parallel with inserting axle.
2. medical treatment device according to claim 1 is characterized in that, by the couple cyclically-varying of described couple generation unit generation.
3. medical treatment device according to claim 1 is characterized in that, has the couple generation unit, and the feature of this couple generation unit is that described position is that central shaft rotates with described insertion axle.
4. medical treatment device according to claim 1 is characterized in that, has the thrust generating unit, and it produces propulsive force on described insertion direction of principal axis.
5. one kind has the medical treatment device that is inserted into endoceliac insertion section, it is characterized in that, comprising:
Medical treatment device, it has and is inserted into endoceliac and has the roughly insertion section of cylindrical in shape;
Be arranged on the helicoidal structure portion on the side of described medical treatment device main body;
Thrust produces mechanism, and it has makes the rotary drive unit of described helicoidal structure portion around the Cylindorical rod rotation of medical treatment device main body, and produces thrust on the Cylindorical rod direction; And
Couple generation unit, its generation have the couple of the position parallel with described Cylindorical rod.
6. medical treatment device according to claim 5 is characterized in that, by the couple cyclically-varying of described couple generation unit generation.
7. medical treatment device according to claim 5 is characterized in that, in the internal configurations of described medical treatment device Magnet is arranged, and it is vertical that the thrust that the pole orientation of this Magnet is configured to described thrust produces mechanism produces direction.
One kind in body cavity the guiding medical treatment device medical device induction system, comprising:
Rotating excitation field;
Magnetic field generation device, the magnetic field of the vertical direction of Plane of rotation of its generation and rotating excitation field;
The medical treatment device main body, it has and is inserted into endoceliac insertion section;
The thrust that is arranged on the described medical treatment device main body produces structural portion; And
Magnet, it is arranged in the described medical treatment device main body, and is configured to pole orientation produces the direction approximate vertical towards the thrust with described thrust generation structural portion direction.
9. medical device induction system according to claim 8 is characterized in that, described thrust produces the helical structure portion on the periphery that structural portion is arranged on described medical treatment device main body.
10. medical device induction system according to claim 8 is characterized in that, with the magnetic field of the vertical direction of Plane of rotation of described rotating excitation field be AC magnetic field.
11. medical device induction system according to claim 8 is characterized in that, has the magnetic field control unit of the described magnetic field generation device of control.
12. medical device induction system according to claim 11 is characterized in that, described magnetic field control unit has the function of switching with the magnetic field of the vertical direction of Plane of rotation of described rotating excitation field that has or not.
13. medical device induction system according to claim 11 is characterized in that, described magnetic field control unit has the function that changes with the intensity in the magnetic field of the vertical direction of Plane of rotation of described rotating excitation field.
14. medical device induction system according to claim 11 is characterized in that, described magnetic field control unit has the function that changes with the frequency in the magnetic field of the vertical direction of Plane of rotation of described rotating excitation field.
15. medical device induction system according to claim 10 is characterized in that, with the magnetic field of the vertical direction of Plane of rotation of described rotating excitation field be AC magnetic field, the frequency of described AC magnetic field more than or equal to 2Hz smaller or equal to 10Hz.
16. medical device induction system according to claim 10 is characterized in that, with respect to the speed of described rotating excitation field, with the frequency height of the AC magnetic field of the vertical direction of Plane of rotation of rotating excitation field.
17. medical device induction system according to claim 10 is characterized in that, with respect to the speed of described rotating excitation field, with the frequency of the AC magnetic field of the vertical direction of Plane of rotation of rotating excitation field be its 2 times~10 times frequency.
18. medical device induction system according to claim 8 is characterized in that, and is with respect to the magnetic field intensity of described rotating excitation field, little with the magnetic field intensity in the magnetic field of the vertical direction of Plane of rotation of rotating excitation field.
19. one kind has the medical treatment device that is inserted into endoceliac insertion section, it is characterized in that, has the vibration generation unit that the direction of inserting axle is periodically changed.
20. medical treatment device according to claim 19, wherein, described vibration generation unit is a position of centre of gravity change mechanism.
21. medical treatment device according to claim 1 is characterized in that, the unit that the produces couple position of centre of gravity change mechanism that to be the position of centre of gravity that makes medical treatment device move with respect to the insertion axle of medical treatment device.
22. medical treatment device according to claim 20 is characterized in that, it is pager motor that described position of centre of gravity changes mechanism.
23. medical treatment device according to claim 20 is characterized in that, described position of centre of gravity changes mechanism and is made of straight line driving mechanism and hammer portion.
24. the medical device induction system of a guiding medical treatment device in body cavity is characterized in that, comprising:
Produce the magnetic field generation device of rotating excitation field;
Has the medical treatment device main body that is inserted into endoceliac insertion section;
The thrust that is arranged on the described medical treatment device main body produces structural portion;
Position of centre of gravity change mechanism, it makes the position of centre of gravity that is arranged on the medical treatment device on the described medical treatment device main body move with respect to the insertion axle of medical treatment device;
Magnet, it is arranged on the described medical treatment device main body, and is configured to pole orientation produces the direction approximate vertical towards the thrust with described thrust generation structural portion direction; And
Transfer unit, the control signal of the described position of centre of gravity change of its control mechanism passes to the medical treatment device main body.
25. medical device induction system according to claim 24 is characterized in that, it is pager motor that described position of centre of gravity changes mechanism.
26. medical device induction system according to claim 24 is characterized in that, described position of centre of gravity changes mechanism and is made of straight line driving mechanism and hammer portion.
27. medical device induction system according to claim 24 is characterized in that, control unit and the medical treatment device split ground of controlling at least one side in described rotating excitation field generator, the described position of centre of gravity change mechanism are provided with.
28. medical device induction system according to claim 27 is characterized in that, described control unit has the function that has or not of switching described position of centre of gravity change mechanism action.
29. medical device induction system according to claim 27 is characterized in that, described control unit has the function of the operating frequency of the described position of centre of gravity change of change mechanism.
30. medical device induction system according to claim 24 is characterized in that, the operating frequency of described position of centre of gravity change mechanism more than or equal to 2Hz smaller or equal to 10Hz.
31. medical device induction system according to claim 24 is characterized in that, the operating frequency of described position of centre of gravity change mechanism is higher than the frequency of the rotating excitation field that described rotating excitation field generator produces.
32. medical device induction system according to claim 31 is characterized in that, the frequency of the rotating excitation field that produces with respect to described rotating excitation field generator, the operating frequency of described position of centre of gravity change mechanism are its 2 times~10 times frequencies.
33. one kind is inserted into endoceliac capsule medical apparatus, it is characterized in that, comprising:
Has the capsule medical apparatus main body that is inserted into endoceliac insertion section;
The thrust that is arranged on the described medical treatment device main body produces structural portion; And
Magnet, it is arranged on the described medical treatment device main body, and the thrust that is configured in described capsule medical instrument main body produces near the center of direction, makes pole orientation produce the direction of direction approximate vertical towards the thrust that produces structural portion with described thrust.
34. one kind is inserted into endoceliac capsule medical apparatus, it is characterized in that, comprising:
Has the capsule medical apparatus main body that is inserted into endoceliac insertion section;
The thrust that is arranged on the described medical treatment device main body produces structural portion; And
Magnet, it is arranged on the described medical treatment device main body, and the thrust that is configured in described capsule medical instrument main body produces near the end of direction, makes pole orientation produce the direction of direction approximate vertical towards the thrust that produces structural portion with described thrust.
35. capsule medical apparatus according to claim 34, it is characterized in that, described medical treatment device main body has the camera system of obtaining endoceliac image, the thrust that described camera system is arranged on described capsule medical apparatus main body produces near the end of an end of direction, and described magnet configuration is near described camera system.
36. capsule medical apparatus according to claim 34, it is characterized in that, described medical treatment device main body has the camera system of obtaining endoceliac image, the thrust that described camera system is arranged on described capsule medical apparatus main body produces near the end of an end of direction, and described magnet configuration is near the end of the opposition side of described camera system.
37. an encapsulated medical device guiding system is characterized in that having: the magnetic field generation device that produces rotating excitation field; The magnetic field generation unit, the magnetic field of the vertical direction of Plane of rotation of its generation and rotating excitation field, described encapsulated medical device guiding system is to the described capsule medical apparatus channeling conduct of claim 33~claim 36.
38. in tested tube chamber internal organs of having a medical check-up, check or the medical treatment device of medical act such as disposal for one kind, it is characterized in that, main body is made of the rotationally symmetric body that has direct of travel along axis of symmetry, the direct of travel front portion of main body or at least one side at rear portion are attenuated along end direction by diameter, and the reducing diameter part with end shape of sphere roughly constitutes, has electromagnetic field response portion in body interior, it is subjected to from the effect of the rotation that is examined the external electromagnetic field that applies, on the main body outer surface, have and be used for rotatablely moving of being produced by described electromagnetic field response portion is converted to the helicoidal structure of propulsive force, be arranged to make the end of described helicoidal structure to arrive near the body end.
39. in tested tube chamber internal organs of having a medical check-up, check or the medical treatment device of medical act such as disposal for one kind, it is characterized in that, main body is by general cylindrical shape shape part, and the diameter at main body two ends attenuates and reducing diameter part with end shape of sphere roughly constitutes along end direction, has Magnet in body interior, it is subjected to from being examined the magnetic action of the rotating excitation field that external body applies, have on the main body outer surface and be used for rotatablely moving of being produced by described Magnet is converted to the helicoidal structure of propulsive force, described helicoidal structure is arranged on both of the general cylindrical shape shape part of described main body and described reducing diameter part.
40., it is characterized in that the spacing of described helicoidal structure is equal according to the described medical treatment device of claim 38, and irrelevant with the shape of main body.
41. according to the described medical treatment device of claim 38, it is characterized in that, have: at least one imaging apparatus in the inside of described medical treatment device; Be used for the lens system of the optical convergence that is taken into from the outside to the described imaging apparatus; With light transmission department spare, it is arranged at least one end of described main body as described reducing diameter part, is used for light is taken into described lens system, and described helicoidal structure is arranged on the outer described light transmission department spare of the image pickup scope of described imaging apparatus.
42., it is characterized in that described electromagnetic field response portion is magnetic or Magnet according to the described medical treatment device of claim 38.
43., it is characterized in that described electromagnetic field response portion is an electrolyte according to the described medical treatment device of claim 38.
44., it is characterized in that the spacing of described helicoidal structure is equal according to the described medical treatment device of claim 39, and irrelevant with the shape of main body.
45. according to the described medical treatment device of claim 39, it is characterized in that, have: at least one imaging apparatus in the inside of described medical treatment device; Be used for the lens system of the optical convergence that is taken into from the outside to the described imaging apparatus; With light transmission department spare, it is arranged at least one end of described main body as described reducing diameter part, is used for light is taken into described lens system, and described helicoidal structure is arranged on the outer described light transmission department spare of the image pickup scope of described imaging apparatus.
46., it is characterized in that in the described general cylindrical shape shape part of described medical treatment device and the coupling part of described reducing diameter part, described helicoidal structure connects smoothly according to the described medical treatment device of claim 39.
47., it is characterized in that the described helicoidal structure of described medical treatment device is made of a plurality of spirals according to the described medical treatment device of claim 38.
48., it is characterized in that the described helicoidal structure of described medical treatment device is made of a plurality of spirals according to the described medical treatment device of claim 39.
49., it is characterized in that in described medical treatment device, described reducing diameter part is a cone-shaped according to the described medical treatment device of claim 38.
50., it is characterized in that in described medical treatment device, described reducing diameter part is a cone-shaped according to the described medical treatment device of claim 39.
51., it is characterized in that described helicoidal structure has hollow space according to the described medical treatment device of claim 38.
52., it is characterized in that described helicoidal structure has hollow space according to the described medical treatment device of claim 39.
53. according to the described medical treatment device of claim 51, it is characterized in that, have: the storage unit of storing medicament at least in the inside of described medical treatment device; Be stored at the medicament in the described storage unit; Emit the unit that emits of described medicament, by emitting the medicament that the unit emits and emit by described from described helicoidal structure end as the described helicoidal structure inside of hollow structure.
54. according to the described medical treatment device of claim 52, it is characterized in that, have: the storage unit of storing medicament at least in the inside of described medical treatment device; Be stored at the medicament in the described storage unit; Emit the unit that emits of described medicament, by emitting the medicament that the unit emits and emit by described from described helicoidal structure end as the described helicoidal structure inside of hollow structure.
55. according to the described medical treatment device of claim 51, it is characterized in that, have: the suction unit that sucks substance in vivo at least in the inside of described medical treatment device; With the storage unit of storage inhaled material, as the end of the described helicoidal structure of hollow structure suction inlet as substance in vivo.
56. according to the described medical treatment device of claim 52, it is characterized in that, have: the suction unit that sucks substance in vivo at least in the inside of described medical treatment device; With the storage unit of storage inhaled material, as the end of the described helicoidal structure of hollow structure suction inlet as substance in vivo.
57. according to the described medical treatment device of claim 38, it is characterized in that, have: at least one imaging apparatus in the inside of described medical treatment device; Be used for the lens system of the optical convergence that is taken into from the outside to the described imaging apparatus; With light transmission department spare, it is arranged at least one end of described main body as described reducing diameter part, is used for light is taken into described lens system, and described helicoidal structure also is set on the described light transmission department spare in the image pickup scope of described imaging apparatus.
58. according to the described medical treatment device of claim 39, it is characterized in that, have: at least one imaging apparatus in the inside of described medical treatment device; Be used for the lens system of the optical convergence that is taken into from the outside to the described imaging apparatus; With light transmission department spare, it is arranged at least one end of described main body as described reducing diameter part, is used for light is taken into described lens system, and described helicoidal structure also is set on the described light transmission department spare in the image pickup scope of described imaging apparatus.
59. a medical device induction system is characterized in that having: the described medical treatment device of claim 38; Electromagnetic field generation unit, its generation act on the electromagnetic field of the electromagnetic field response portion that is located in the described medical treatment device; The electromagnetic field control unit, it controls the direction of the electromagnetic field of described electromagnetic field generation unit generation,
Described electromagnetic field generation unit generates an electromagnetic field on three direction of principal axis, makes described medical treatment device at tube chamber internal organs internal rotation.
60. a medical device induction system is characterized in that having: the described medical treatment device of claim 39; Electromagnetic field generation unit, its generation act on the electromagnetic field of the electromagnetic field response portion that is arranged in the described medical treatment device; The electromagnetic field control unit, it controls the direction of the electromagnetic field of described electromagnetic field generation unit generation,
Described electromagnetic field generation unit generates an electromagnetic field on three direction of principal axis, makes described medical treatment device at tube chamber internal organs internal rotation.
61., it is characterized in that described medical treatment device is a capsule medical apparatus of swallowing type according to the described medical treatment device of claim 38.
62., it is characterized in that described medical treatment device is a capsule medical apparatus of swallowing type according to the described medical treatment device of claim 39.
63., it is characterized in that described medical treatment device is the medical treatment device that flexible pipe has been installed according to the described medical treatment device of claim 38 on capsule medical apparatus.
64., it is characterized in that described medical treatment device is the medical treatment device that flexible pipe has been installed according to the described medical treatment device of claim 39 on capsule medical apparatus.
Applications Claiming Priority (5)
Application Number | Priority Date | Filing Date | Title |
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JP2882732003 | 2003-08-06 | ||
JP2003288273A JP4137740B2 (en) | 2003-08-06 | 2003-08-06 | Capsule type medical device and capsule type medical device guidance system |
JP2003291771A JP4153845B2 (en) | 2003-08-11 | 2003-08-11 | Medical device guidance system |
JP291771/2003 | 2003-08-11 | ||
PCT/JP2004/011628 WO2005013811A1 (en) | 2003-08-06 | 2004-08-06 | Medical device, medical device guide system, capsule-type medical device, and capsule-type medical device guide device |
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CN2008100965381A Division CN101292857B (en) | 2003-08-06 | 2004-08-06 | Medical apparatus, medical apparatus guide system, capsule type medical apparatus, and guide apparatus thereof |
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CN1829466A true CN1829466A (en) | 2006-09-06 |
CN1829466B CN1829466B (en) | 2011-01-05 |
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CN2004800218881A Expired - Fee Related CN1829466B (en) | 2003-08-06 | 2004-08-06 | Medical device, medical device guide system, capsule-type medical device, and capsule-type medical device guide device |
CN2008100965381A Expired - Fee Related CN101292857B (en) | 2003-08-06 | 2004-08-06 | Medical apparatus, medical apparatus guide system, capsule type medical apparatus, and guide apparatus thereof |
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CN2008100965381A Expired - Fee Related CN101292857B (en) | 2003-08-06 | 2004-08-06 | Medical apparatus, medical apparatus guide system, capsule type medical apparatus, and guide apparatus thereof |
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Also Published As
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CN1829466B (en) | 2011-01-05 |
CN101292857B (en) | 2013-03-06 |
JP4137740B2 (en) | 2008-08-20 |
JP2005052502A (en) | 2005-03-03 |
CN101292857A (en) | 2008-10-29 |
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