Source: https://patents.google.com/patent/JP2009268889A/en
Timestamp: 2019-11-18 22:53:36
Document Index: 61451097

Matched Legal Cases: ['art 34', 'art 37', 'art 23', 'art 22', 'art 37', 'art 23', 'art 37', 'art 34', 'art 23', 'art 23', 'art 37', 'art 34', 'art 36', 'art 30', 'art 22', 'art 22', 'art 23', 'art 57', 'art 67', 'art 67', 'arts 57', 'art 36', 'art 49', 'art, 22', 'art, 36', 'art, 23']

JP2009268889A - Medical system - Google Patents
JP2009268889A
JP2009268889A JP2008330938A JP2008330938A JP2009268889A JP 2009268889 A JP2009268889 A JP 2009268889A JP 2008330938 A JP2008330938 A JP 2008330938A JP 2008330938 A JP2008330938 A JP 2008330938A JP 2009268889 A JP2009268889 A JP 2009268889A
JP2008330938A
JP5289929B2 (en
JP2009268889A5 (en
健 重田
2008-05-09 Priority to US12/118,319 priority Critical
2008-05-09 Priority to US12/118,319 priority patent/US20090281378A1/en
2008-12-25 Application filed by Olympus Medical Systems Corp, オリンパスメディカルシステムズ株式会社 filed Critical Olympus Medical Systems Corp
2009-11-19 Publication of JP2009268889A publication Critical patent/JP2009268889A/en
2012-02-02 Publication of JP2009268889A5 publication Critical patent/JP2009268889A5/ja
2013-09-11 Publication of JP5289929B2 publication Critical patent/JP5289929B2/en
<P>PROBLEM TO BE SOLVED: To provide a medical system, reliably moving an actuation part of a tip part of an operation device. <P>SOLUTION: The medical system includes operation devices 35a and 35b comprising an insertion device 16 having a base end opening part 34, a connection part 37 provided on a base end part, and a transmission part 23d extended between the actuation part 22d and 36 and the connection part 37 to transmit drive force, a drive device 54 having a connection receiving part, and a guide mechanism 77, having a guide member that is harder than the transmission part 23d, disposed between the connection part 37 connected to the connection receiving part and the base end opening part 34 to support the transmission part 23d to guide the transmission part 23d between the connection part 37 connected to the connection receiving part and the base end opening part 34. <P>COPYRIGHT: (C)2010,JPO&INPIT
The present invention inserts a surgical device into a body cavity via a channel of an insertion device inserted into a body cavity, applies a driving force to the proximal end portion of the surgical device, and applies the driving force to the distal end portion via a transmission portion. The present invention relates to a medical system that transmits an operating part to move the operating part.
Patent Document 1 discloses a medical system. In this medical system, an endoscope is inserted into a body cavity, and forceps are inserted into a body cavity from a forceps port of the endoscope through a treatment instrument channel, and surgery is performed using the forceps. In the forceps, a grasping portion for grasping a living tissue and a long and flexible flexible tube portion are continuously provided from the distal end side to the proximal end side. By manually moving the proximal end of the flexible tube extending from the forceps opening of the endoscope forward and backward, and rotating it, the grasping portion is advanced and retracted through the flexible tube inserted through the treatment instrument channel. It is possible to rotate.
US Patent Application Publication No. 2005/70757
In the medical system disclosed in Patent Document 1, when the proximal end portion of the flexible tube portion is driven by a drive device instead of manually, the flexible tube portion is interposed between the drive device and the forceps opening. It becomes a floating state, and the driving force applied to the proximal end portion of the flexible tube portion is not reliably transmitted to the grip portion at the distal end portion, and it is difficult to move the grip portion reliably.
The present invention has been made paying attention to the above-described problems, and an object of the present invention is to provide a medical system capable of reliably moving the operating portion of the distal end portion of the surgical apparatus.
In the first embodiment of the present invention, the medical system is an insertion device to be inserted into a body cavity, the channel extending between the distal end portion and the proximal end portion of the insertion device, and the channel An insertion device having a proximal opening connected to the proximal end, and a surgical device that is inserted into the channel from the proximal opening and is inserted into the channel. An operating portion provided, a connecting portion provided at a proximal end portion of the surgical device, and a driving force applied to the connecting portion that extends between the operating portion and the connecting portion to the operating portion. A driving device having a transmission unit that transmits the connection unit, a connection receiving unit to which the connection unit is connected, and a drive mechanism that drives the connection unit connected to the connection reception unit; The connecting part connected to the connection receiving part and the front Between the base end opening and the connecting portion that is disposed between the base end opening, supports the transmitting portion, and connects the transmitting portion to the connecting receiving portion; And a guide mechanism having a hard guide member.
In the second embodiment of the present invention, in the medical system, the connecting portion is detachable from the connecting receiving portion, and the guide mechanism is configured such that at least a part of the guide member receives the connecting member. A retraction support mechanism that supports the retraction position movably to a retraction position that is retreated from between the connection portion connected to a portion and the base end opening.
In the third embodiment of the present invention, the medical system may be configured such that the guide member is detachable from the guide member in a direction that intersects the guide direction of the transmission unit by the guide member. It is characterized by having.
In the fourth embodiment of the present invention, the medical system is configured such that the guide member is connected to the connection receiving portion and the proximal end opening portion with respect to the movement of the guide member to the retracted position. A retraction relief portion for escaping at least one of the transmission portion and the base end opening so that the guide member does not interfere with at least one of the transmission portion and the base end opening extending between And
In a fifth embodiment of the present invention, the medical system is characterized in that the guide mechanism includes a drop-off prevention member that covers the escape escape portion from the outside of the guide member.
In a sixth embodiment of the present invention, in the medical system, the guide mechanism includes a follow-up support mechanism that movably supports the guide member in a driving direction of the connecting portion, and the guide member in the driving direction of the connecting portion. An urging mechanism that urges the connection receiving portion to the connection receiving portion side, and the guide member has an abutting portion provided at an end portion on the connection receiving portion side, and the connection portion Has a contact receiving portion that is disposed at a base end portion of the transmission portion and that contacts the contact portion.
In a seventh embodiment of the present invention, the medical system is configured such that the guide member is connected to the connection receiving portion with respect to the movement of the guide member in the driving direction of the connection portion and the proximal end. A follow-up relief portion that escapes at least one of the transmission portion and the base end opening so that the guide member does not interfere with at least one of the transmission portion and the base end opening extending between the openings; It is characterized by that.
In an eighth embodiment of the present invention, the medical system is characterized in that the guide mechanism includes a drop-off preventing member that covers the follow-up relief portion from the outside of the guide member.
In a ninth embodiment of the present invention, in the medical system, the guide mechanism supports the guide member movably in the driving direction of the connecting portion, and the guide member is supported by at least a part of the connecting member. A support mechanism that can be disposed at a retracted position that is retracted in the driving direction of the connecting portion from between the connecting portion that is connected to the base end opening, and the guide member in the driving direction of the connecting portion. An urging mechanism that urges toward the connection receiving portion; and a locking mechanism that can lock the guide member at the retracted position, wherein the guide member is an end on the connection receiving portion side. An abutting portion provided on the connecting portion, wherein the connecting portion is detachable from the connecting receiving portion, and is disposed at a base end portion of the transmitting portion so that the abutting portion comes into contact therewith. It has a receiving part.
In a tenth embodiment of the present invention, the medical system is configured such that the surgical device is inserted through an operating mechanism provided in the operating unit, a connecting mechanism provided in the connecting unit, and the transmitting unit. A transmission member that extends between the operation mechanism and the connection mechanism and transmits a driving force applied to the connection mechanism to the operation mechanism to operate the operation mechanism, and the drive device includes the connection mechanism. It has the drive connection mechanism which drives a mechanism, It is characterized by the above-mentioned.
In the first embodiment of the present invention, since the transmission part is supported and guided between the connection part connected to the connection receiving part and the proximal end opening part by the guide member harder than the transmission part, it is connected by the drive mechanism. The driving force applied to the part is reliably transmitted to the operating part by the transmitting part, and the operating part can be reliably moved.
In the second embodiment of the present invention, by retracting at least a part of the guide member from between the connecting portion connected to the connecting receiving portion and the proximal end opening, the connecting portion is attached to and detached from the connecting receiving portion. Space can be secured, and the attachment / detachment operation of the connecting portion with respect to the connecting receiving portion can be easily performed.
In the third embodiment of the present invention, the transmission portion can be attached to and detached from the guide member in a direction intersecting the guide direction of the guide member via the guide member attachment and detachment portion. Can be easily performed.
In the fourth embodiment of the present invention, in the movement of the guide member, the transmission portion, the base end opening, and the guide member do not interfere with each other.
In the fifth embodiment of the present invention, the drop-off prevention member prevents the transmission part from falling off the retreat escape part.
In the sixth embodiment of the present invention, the guide member is moved following the movement of the connecting portion while the contact portion of the guide member is in contact with the contact receiving portion of the connecting portion. The space where the transmission part is not supported by the guide member is not formed between the end part on the connection part side of the guide member and the connection part, and the driving force can be more reliably transmitted by the transmission part. ing.
In the seventh embodiment of the present invention, in the movement of the guide member in the driving direction of the connecting portion, the transmission portion, the proximal end opening portion, and the guide member do not interfere with each other.
In the eighth embodiment of the present invention, the dropout prevention member prevents the transmission portion from dropping off from the follow-up relief portion.
In the ninth embodiment of the present invention, the guide member is moved following the movement of the connecting portion while the contact portion of the guide member is in contact with the contact receiving portion of the connecting portion. The space where the transmission part is not supported by the guide member is not formed between the end part on the connection part side of the guide member and the connection part, and the driving force applied to the connection part is more reliably transmitted by the transmission part. It is possible to do. Further, by moving at least a part of the guide member between the connection receiving portion and the base end opening portion in the driving direction of the connection portion, the guide member is disposed and locked at the retracted position, so that the operator holds the guide member. A space for attaching and detaching the connecting portion to and from the connection receiving portion is secured without being held against the urging force of the urging mechanism, and the connecting portion can be easily attached to and detached from the connection receiving portion. Yes.
In the tenth embodiment of the present invention, since the transmission portion is supported and guided between the connection portion connected to the connection receiving portion and the base end opening portion by the guide member harder than the transmission portion, the connection drive mechanism It is possible to reliably transmit the driving force applied to the operating mechanism to the operating mechanism by the transmitting member inserted through the transmitting portion, and it is possible to operate the operating mechanism with certainty.
With reference to FIG.1 and FIG.2, schematic structure of a medical system is demonstrated.
With respect to the endoscope 16 as an insertion device, the proximal end portion of the endoscope 16 is supported by an endoscope support arm 18 disposed on the trolley 17. The endoscope 16 has a long insertion portion 19 that is inserted into a body cavity. In the insertion portion 19, a distal end rigid portion 21, an endoscope bending portion 22c that is operated to bend, and a long and flexible endoscope flexible tube portion 23c are continuously provided from the distal end side to the proximal end side. Yes. An operation unit 24 operated by an operator is connected to the proximal end portion of the insertion unit 19. The operation section 24 is provided with a bending operation knob 26 for bending the endoscope bending section 22c. A universal cable 27 extends from the operation unit 24. The universal cable 27 is connected to a video processor 28 and a light source device 29 mounted on the trolley 17. The illumination light generated by the light source device 29 is supplied to the illumination optical system of the distal end rigid portion 21 via a light guide inserted through the endoscope 16 and is irradiated onto the observation target. An observation image is captured by the imaging unit of the distal end rigid portion 21 to generate an image signal, and the image signal is output to the video processor 28 via an imaging cable inserted through the endoscope 16. The video processor 28 displays the observation image on the monitor 31. Further, the insertion portion 19 is provided with first and second channels 32. The distal end portions of the first and second channels 32 are opened by the distal end rigid portion 21 to form first and second projecting ports 33. The base ends of the first and second channels 32 are connected to first and second insertion caps 34 as base end openings protruding from the operation unit 24.
Regarding the forceps manipulator 35a and the treatment instrument manipulator 35b as a surgical device, in the forceps manipulator 35a, a gripping portion 36 that is opened and closed, a bending portion 22d that is bent and operated, a long and flexible flexible tube portion 23d and a connection A unit 37 is connected from the distal end side to the proximal end side. By driving the connecting unit 37 as a connecting portion back and forth in the longitudinal axis direction of the forceps manipulator 35a and rotationally driving about the longitudinal axis, the driving force is transmitted by the flexible tube portion 23d as the transmitting portion, and as the operating portion. The curved portion 22d and the gripping portion 36 are advanced and retracted and rotated. A pair of operation wires 47 for operating the gripping part 36 and each joint part 30 of the bending part 22d are inserted into the bending part 22d and the flexible tube part 23d and introduced into the connecting unit 37. Yes. The base end portions of each pair of operation wires 47 are continuous and have an annular shape, and are wound around pulleys 48 disposed in the connection unit 37. By rotating and driving the pulley 48 as the coupling mechanism, one and the other of the pair of operation wires 47 as the transmission members are moved forward and backward, and each of the grip portion 36 and the bending portion 22d as the operation mechanism is moved forward and backward. The joint 30 is actuated.
Further, the treatment instrument manipulator 35b has substantially the same configuration as the forceps manipulator 35a. That is, in the treatment instrument manipulator 35b, an electrode portion 49 to which a high-frequency current is passed, a bending portion 22d as an operation portion, a flexible tube portion 23d, and a connection unit 37 are connected from the distal end side to the proximal end side. An operation wire 47 and a pulley 48 are disposed in the treatment instrument manipulator 35b. An electrode wire for supplying a high-frequency current to the electrode portion 49 extends from the electrode portion 49, is inserted into the bending portion 22 d and the flexible tube portion 23 d, and is introduced into the connection unit 37. The proximal end portion of the electrode wire is connected to the inner end portion of the electrical connection portion 50 protruding from the coupling unit 37. The electrical connection unit 50 is connected to a high frequency output device 52 mounted on the trolley 17 via an electrical cable 51. A high frequency current is passed from the high frequency output device 52 to the electrode portion 49 via the electric cable 51, the electric connection portion 50, and the electrode wire. The high frequency output device 52 is connected to the control device 53 mounted on the trolley 17.
Regarding the first and second drive units 54 as drive devices, each drive unit 54 is supported by a drive unit support arm 55 disposed in the trolley 17. A connection unit 37 of manipulators 35a and 35b inserted through the first and second channels 32 of the endoscope 16 is detachably connected to the first and second drive units 54, respectively. The drive unit 54 drives the entire coupling unit 37 forward and backward in the longitudinal direction of the manipulators 35a and 35b, and rotationally drives the longitudinal axis about the longitudinal axis, and rotationally drives each pulley 48 of the coupling unit 37. The first and second drive units 54 are connected to a control device 53 mounted on the trolley 17.
In the control device 53, the types of the manipulators 35a and 35b connected to each drive unit 54 can be input. In the present embodiment, it is possible to input whether the manipulator connected to each drive unit 54 is the forceps manipulator 35a or the treatment instrument manipulator 35b.
An operation device 56 is connected to the control device 53. The operating device 56 is provided with first and second master arms 46. In the first and second master arms 46, first and second openable / closable portions 57 that can be freely opened and closed are movably supported by first and second arm portions 59, respectively. When it is input that the forceps manipulator 35a is connected to the first drive unit 54, the control device 53 receives the first opening / closing portion 57 according to the moving operation and the opening / closing operation. 1 drive unit 54 is controlled to move and hold the gripping portion 36 of the forceps manipulator 35a. On the other hand, when it is input that the treatment device manipulator 35b is connected to the first drive unit 54, the control device 53 performs the first operation according to the movement operation to the first opening / closing portion 57. The first drive unit 54 is controlled to move the electrode portion 49 of the treatment instrument manipulator 35b, and the high-frequency output device 52 is controlled in accordance with the opening / closing operation of the first opening / closing portion 57 so that the electrode portion 49 has a high frequency. A current is applied, and the current supply to the electrode unit 49 is stopped. Similarly, the control device 53 operates the manipulators 35 a and 35 b connected to the second drive unit 54 based on an operation on the second opening / closing part 57.
The drive unit 54 will be described in detail with reference to FIGS. 2 to 4B.
The connection unit 37 of the manipulators 35a and 35b has a flat rectangular parallelepiped shape extending in the longitudinal axis direction of the manipulators 35a and 35b. Further, the rotation shaft of the pulley 48 disposed in the connection unit 37 extends orthogonally to the connection unit 37.
In the drive unit 54, the advance / retreat housing 60 is mounted on the pedestal 58. An advancing / retreating drive unit 61 as a drive mechanism such as a ball screw is interposed between the pedestal 58 and the advancing / retreating housing 60, and the advancing / retreating housing 60 can advance and retract in the direction of the central axis O of the drive unit 54 with respect to the pedestal 58. It is. A rotating housing 62 is accommodated in the advance / retreat housing 60. A rotation drive unit 63 as a drive mechanism is interposed between the advance / retreat housing 60 and the rotation housing 62, and the rotation housing 62 is rotatable about the central axis O of the drive unit 54 with respect to the advance / retreat housing 60. is there. That is, the rotation motor 38 is fixed to the inner surface of the advance / retreat housing 60. The output shaft portion of the rotation motor 38 extends in parallel to the direction of the central axis O of the drive unit 54, and the first rotation spur gear 39 is connected to the output shaft portion. A second rotating spur gear 41 extends around the entire outer periphery of the rotating housing 62. The first and second rotating spur gears 39 and 41 are engaged with each other, and the rotational driving force of the rotating motor 38 is transmitted to the rotary housing 62 via the first and second rotating spur gears 39 and 41. Is done. An insertion / extraction hole 64 is formed at the forward end of the rotary housing 62, and a connection unit receiving portion 67 as a connection receiving portion is disposed in the rotation housing 62. The connecting unit 37 of the manipulators 35 a and 35 b can be inserted into and removed from the connecting unit receiving part 67 through the insertion hole 64 in the direction of the central axis O of the drive unit 54, and the longitudinal axis of the connecting unit 37 inserted into the connecting unit receiving part 67. Coincides with the central axis O of the drive unit 54. Further, on the outer surface of the rotary housing 62, an engagement unit 68 is disposed in the vicinity of the insertion / extraction hole 64. In the engagement unit 68, the engagement member 69 is slidably supported in the radial direction of the drive unit 54 and is urged inward in the radial direction. An operation member 70 for operating the engagement member 69 is connected to the engagement member 69. On the other hand, an engagement recess 71 is formed at the tip of the connection unit 37 of the manipulators 35a and 35b. When the connection unit 37 is inserted into the connection unit receiving portion 67, the engagement member 69 is engaged with the engagement recess 71, and the rotary housing 62 and the connection unit 37 are engaged with each other. When the connection unit 37 is removed from the connection unit receiving portion 67, the engagement member 69 is operated by the operation member 70 to release the engagement with the engagement recess 71, and the rotary housing 62 and the connection unit 37 are Release the engagement.
A pulley drive unit 72 as a drive connection mechanism for driving the pulley 48 of the connection unit 37 inserted in the connection unit receiving portion 67 is disposed in the rotary housing 62. That is, a motor base 73 is disposed on the retreat side in the rotary housing 62, and the motor base 73 can advance and retreat in parallel to the direction of the central axis O of the drive unit 54 within a predetermined range with respect to the rotary housing 62. It is. An operation motor 74 is disposed on the forward side of the motor base 73. The output shaft portion of the actuating motor 74 extends rearward in parallel with the central axis O of the drive unit 54, and a first bevel gear 76a is connected to the end portion of the output shaft portion. A rotating shaft portion 78 projects from the motor base 73 on the backward side. The rotating shaft 78 extends so as to be orthogonal to the connecting unit 37 inserted into the connecting unit receiving portion 67, and is rotatable about its own central axis. A second bevel gear 76 b that meshes with the first bevel gear 76 a is connected to an intermediate portion of the rotation shaft portion 78, and an operation spur gear 79 is connected to the end portion of the rotation shaft portion 78. The spur gear 79 for operation is meshed with the pulley 48 of the connection unit 37 inserted in the connection unit receiving portion 67. The pulley drive unit 72 is always urged forward by a tension spring 75. That is, the pulley drive unit 72 is biased in the direction opposite to the insertion direction of the connection unit 37, and the pulley 48 and the pulley drive unit 72 of the connection unit 37 are simply inserted into the connection unit receiving portion 67. The operating spur gear 79 can be reliably meshed. The rotational driving force of the actuating motor 74 is transmitted to the pulley 48 via the first bevel gear 76a, the second bevel gear 76b, and the actuating spur gear 79.
The guide mechanism 77 will be described in detail with reference to FIGS. 5A to 7.
The drive unit 54 is disposed so that the central axis O of the drive unit 54 is parallel to the longitudinal axis of the endoscope 16. With respect to the longitudinal axis of the endoscope 16, the first drive unit 54 is parallel to the first insertion base 34 and the second drive unit 54 is parallel to the second insertion base 34. Are arranged. Between the first and second insertion caps 34 and the first and second drive units 54, first and second guide mechanisms 77 are arranged in parallel with each other, respectively.
In the guide mechanism 77, a support arm portion 80 as a retraction support mechanism is pivotally attached to the side surface of the operation unit 24 of the endoscope 16. The distal end portion of the support arm portion 80 is rotatable about a rotation axis P parallel to the longitudinal axis of the endoscope 16. A support hole 81 extends in the end portion of the support arm 80 in parallel with the longitudinal axis direction of the endoscope 16. A circular tubular guide pipe 82 as a guide member is inserted into the support hole 81, and the guide pipe 82 is fixed to the support arm portion 80 and arranged in parallel to the longitudinal axis direction of the endoscope 16. . The guide pipe 82 is made of a material harder than the material of the flexible tube forming the flexible tube portion 23d of the manipulators 35a and 35b. That is, the flexible pipes of the manipulators 35a and 35b are made of, for example, a fluororesin, whereas the guide pipe 82 is made of, for example, metal, preferably stainless steel, brass, or resin, preferably polyether ether. -It is formed from a ketone resin, polycarbonate, polypropylene, or a mixture thereof. The guide pipe 82 is rotatable between a guide position (see FIG. 5A) and a retracted position (see FIG. 5B) by the support arm 80. At the guide position, the central axis of the guide pipe 82 coincides with the central axis O of the drive unit 54. In the retracted position, the guide pipe 82 is disposed symmetrically with respect to the guide position about the rotation axis of the support arm 80. The guide pipe 82 is provided with an attachment / detachment groove 84 as a notch attachment / detachment portion extending over the entire length in the longitudinal axis direction of the guide pipe 82. The support arm 80 also has a notch groove at a position facing the attachment / detachment groove 84 of the guide pipe 82. The width of the detachable groove 84 is slightly smaller than the outer diameter of the flexible tube portion 23d of the manipulators 35a and 35b. A flexible guide tube 85 made of polytetrafluoroethylene or the like is attached between the distal end portion of the guide pipe 82 and the protruding end portion of the insertion cap 34.
Next, the usage method of the medical system of this embodiment is demonstrated.
When using the medical system, the insertion portion 19 of the endoscope 16 is inserted into the body cavity. In the guide mechanism 77, the guide pipe 82 is disposed at the retracted position, and one end of the guide tube 85 is connected to the insertion base 34 of the endoscope 16. The connection unit 37 of the manipulators 35 a and 35 b is inserted into the connection unit receiving portion 67 of the drive unit 54, and the rotary housing 62 and the connection unit 37 are engaged to connect the manipulators 35 a and 35 b to the drive unit 54. The distal ends of the manipulators 35 a and 35 b are inserted into the corresponding insertion caps 34 through the guide tubes 85, inserted into the channels 32, and protruded from the protruding ports 33 of the distal end rigid portion 21 of the endoscope 16. Subsequently, the guide pipe 82 is moved from the retracted position to the guide position, and the flexible pipe portions 23 d of the manipulators 35 a and 35 b are mounted in the guide pipe 82 via the attachment / detachment groove 84 of the guide pipe 82, and the guide tube 85. Is connected to the tip of the guide pipe 82. In addition, the controller 53 is appropriately input as to whether the manipulator connected to the first and second drive units 54 is the forceps manipulator 35a or the treatment instrument manipulator 35b.
Subsequently, while observing the observation image of the endoscope 16 displayed on the monitor 31, the first and second opening / closing parts 57 of the first and second master arms 46 of the operation device 56 are operated, The grasping portion 36 of the forceps manipulator 35a is moved, opened and closed, and while grasping and supporting the living tissue, a high-frequency current is applied to the electrode portion 49 of the treatment instrument manipulator 35b to move the electrode portion 49 to the living tissue. An incision treatment is performed on the living tissue. At this time, the connecting unit 37 of the manipulators 35a, 35b is driven forward / backward and rotated by the drive unit 54, and the forward / backward driving force and the rotational driving force applied to the connecting unit 37 are bent by the flexible tube portion 23d and the gripping portion 22d. 36 or the electrode portion 49, and the bending portion 22d and the gripping portion 36 or the electrode portion 49 are moved back and forth and rotated. Further, the pulley 48 is rotationally driven by the pulley drive unit 72 of the drive unit 54, and one and the other operation wires 47 of the pair of operation wires 47 are advanced and retracted, so that each joint portion 30 of the grip portion 36 and the bending portion 22d. Is activated. Here, since the flexible tube portion 23d is supported and guided by the rigid guide pipe 82 between the connection unit 37 connected to the connection unit receiving portion 67 and the guide tube 85, the flexible tube portion 23d. Thus, the forward / backward driving force and the rotational driving force can be reliably transmitted. Further, the driving force can be reliably transmitted by the pair of operation wires 47 inserted through the flexible tube portion 23d.
When removing the manipulators 35a and 35b, the support arm 80 is rotated to move the guide pipe 82 to the retracted position. The other end portion of the guide tube 85 is removed from the distal end portion of the guide pipe 82 while the flexible tube portion 23d of the manipulators 35a and 35b is removed from the guide pipe 82 via the attaching / detaching groove 84 of the guide pipe 82. Then, the distal ends of the manipulators 35a and 35b are removed from the endoscope 16 and the guide tube 85. Subsequently, the connection between the connection unit 37 and the rotary housing 62 is released, the connection unit 37 is removed from the connection unit receiving portion 67, and the manipulators 35 a and 35 b are separated from the drive unit 54.
Therefore, the medical system of this embodiment has the following effects.
In the medical system of the present embodiment, the flexible tube portion 23d is supported by the guide pipe 82 that is harder than the flexible tube portion 23d between the connection unit 37 connected to the connection unit receiving portion 67 and the insertion base 34. I am guiding. Therefore, the forward / backward driving force and rotational driving force applied to the connecting unit 37 by the drive unit 54 can be reliably transmitted to the bending portion 22d and the gripping portion 36 or the electrode portion 49 by the flexible tube portion 23d. 22d and the gripping part 36 or the electrode part 49 can be reliably moved forward and backward. Further, the driving force applied to the pulley 48 can be reliably transmitted to the bending portion 22d and the gripping portion 36 by the operation wire 47 inserted through the flexible tube portion 23d. Can be operated.
Further, since the entire guide mechanism 77 can be retracted from between the connection unit 37 connected to the connection unit receiving portion 67 and the insertion base 34, a space for attaching and detaching the connection unit 37 to and from the connection unit receiving portion 67 is provided. It is possible to secure the connection unit 37 with respect to the connection unit receiving portion 67 easily. Further, the flexible tube portion 23d can be attached to and detached from the guide pipe 82 in the radial direction of the guide pipe 82 via the attachment / detachment groove 84 of the guide pipe 82, and the flexible tube portion 23d is attached to and detached from the guide pipe 82. Can be easily performed.
8A to 9 show a second embodiment of the present invention.
In the guide mechanism 77 of the present embodiment, a support arm 80 as a follow-up support mechanism and a retreat support mechanism is fixed to the operation unit 24 of the endoscope 16. An insertion base 86 is embedded in the support arm portion 80. An inner end portion of the insertion base 86 protrudes into the support hole 81 of the support arm portion 80, and an outer end portion of the insertion base 86 protrudes from the support arm portion 80 and is disposed so as to face the insertion base 34 of the endoscope 16. Has been. A guide tube 85 is mounted between the insertion base 86 and the insertion base 34. A proximal end opening is formed by the insertion base 34, the guide tube 85, and the insertion base 86. A guide pipe 82 is inserted into the support hole 81 of the support arm portion 80 so as to be movable forward and backward in the longitudinal axis direction of the endoscope 16. In the guide pipe 82, a notch groove-like follow-up relief portion and a relief groove 87 as a retreat escape portion are extended over the entire length in the axial direction of the guide pipe 82 on the endoscope 16 side. The inner end portion of the insertion base 86 is inserted into the escape groove 87 of the guide pipe 82 so that the guide pipe 82 and the insertion base 86 do not interfere with each other when the guide pipe 82 advances and retreats.
A cylindrical distal end stopper 90a and a proximal end stopper 90b as a contact portion are externally fixed to the distal end portion and the proximal end portion of the guide pipe 82, respectively. A coil spring 89 as a biasing mechanism and a drop-off preventing member is compressed and disposed between the support arm portion 80 and the base end stopper 90b of the guide pipe 82. The coil spring 89 is extrapolated to the guide pipe 82. ing. The guide pipe 82 is biased toward the proximal end side with respect to the support arm portion 80 by a coil spring 89. When the distal end stopper 90a of the guide pipe 82 is brought into contact with the support arm portion 80, the movement of the guide pipe 82 toward the proximal end side is restricted. On the other hand, at the distal end portion of the coupling unit 37 of the manipulators 35a and 35b, a stopper receiving portion 91 as a cylindrical contact receiving portion is fitted and fixed to the flexible tube portion 23d coaxially. The proximal end stopper 90 b of the guide pipe 82 is brought into contact with the stopper receiving portion 91 of the connection unit 37.
The guide mechanism 77 is provided with a locking unit 97 that locks the guide pipe 82 at the most advanced retracted position. That is, a locking hole 92 is formed in the guide pipe 82 in a radial direction at a predetermined position in the axial direction. A housing groove 93 extends along the support hole 81 on the outer surface of the support arm 80, and an insertion hole 94 is formed between the bottom of the housing groove 93 and the support hole 81. A locking member 95 is disposed in the insertion hole 94, and the locking member 95 is urged inward in the radial direction of the insertion hole 94 by a leaf spring 96. When the guide pipe 82 is not in the retracted position, the locking member 95 is in contact with the outer peripheral surface of the guide pipe 82, and when the guide pipe 82 is disposed in the retracted position, the support arm 80 is inserted. The locking hole 92 of the guide pipe 82 is aligned with the hole 94, and the locking member 95 is locked to the locking hole 92 of the guide pipe 82.
When using the medical system, as shown in FIG. 8C, in the guide mechanism 77, the guide pipe 82 is moved to the distal end side against the urging force of the coil spring 89 to the retracted position, and the guide pipe 82. The locking member 95 of the support arm portion 80 is locked in the locking hole 92, and the guide pipe 82 is locked to the support arm portion 80. Subsequently, the manipulators 35a and 35b are connected to the drive unit 54, the distal ends of the manipulators 35a and 35b are inserted into the base end portion of the guide pipe 82, inserted into the guide pipe 82, the insertion cap 86, and the guide tube 85, It is inserted into the insertion cap 34 of the endoscope 16, is inserted through the channel 32, and protrudes from the protrusion 33 of the distal end rigid portion 21. Subsequently, the guide pipe 82 is moved to the proximal end side, the locking member 95 is pushed out from the locking hole 92, and the locking between the guide pipe 82 and the support arm portion 80 is released. As a result, as shown in FIG. 8A, the guide pipe 82 is moved to the proximal end side by the urging force of the coil spring 89, and the proximal end stopper 90b of the guide pipe 82 is received by the stopper of the connecting unit 37 of the manipulators 35a and 35b. It abuts on the portion 91.
Similarly to the first embodiment, the manipulators 35a and 35b are operated by operating the operating device 56. Here, as shown in FIG. 8B, when the connecting unit 37 is advanced, the stopper stopper 91 of the connecting unit 37 causes the proximal end stopper 90 b of the guide pipe 82 to resist the biasing force of the coil spring 89. The guide pipe 82 is moved to the tip side. On the other hand, when the connecting unit 37 is retracted, the guide pipe 82 is moved in a state where the proximal end stopper 90 b of the guide pipe 82 is in contact with the stopper receiving portion 91 of the connecting unit 37 by the biasing force of the coil spring 89. It is moved to the proximal side. In this way, the guide pipe 82 is advanced and retracted following the advance and retreat of the connecting unit 37. Thus, during the driving of the connecting unit 37, the base end stopper 90b of the guide pipe 82 is always in contact with the stopper receiving portion 91 of the connecting unit 37, and the end of the guide pipe 82 on the connecting unit 37 side and the connecting unit 37 A space in which the flexible pipe portion 23d is not supported by the guide pipe 82 is not formed between them.
When removing the manipulators 35a and 35b, the guide pipe 82 is disposed at the retracted position, and the distal ends of the manipulators 35a and 35b are removed from the endoscope 16, the guide tube 85, and the guide mechanism 77, as in the case of mounting. To do.
In the medical system of the present embodiment, the guide pipe 82 is advanced and retracted following the advance and retreat of the connection unit 37 in a state where the proximal end stopper 90 b of the guide pipe 82 is in contact with the stopper receiving portion 91 of the connection unit 37. Therefore, a space in which the flexible pipe portion 23d is not supported by the guide pipe 82 is not formed between the end portion of the guide pipe 82 on the connection unit 37 side and the connection unit 37, and the flexible pipe The driving force can be more reliably transmitted by the portion 23d and the operation wire 47. Further, by operating at least a part of the guide pipe 82 between the connection unit receiving portion 67 and the support arm portion 80 in the advancing / retreating direction of the connection unit 37 and disposing and locking the guide pipe 82 at the retracted position. A person can secure a space for attaching and detaching the connecting unit 37 to and from the connecting unit receiving portion 67 without holding the guide pipe 82 against the urging force of the coil spring 89, and the connection to the connecting unit receiving portion 67 can be secured. The unit 37 can be easily attached and detached.
Further, the width of the escape groove 87 of the guide pipe 82 is slightly larger than the outer diameter of the insertion base 86 so that the guide pipe 82 and the insertion base 86 do not interfere with each other, and is larger than the outer diameter of the flexible tube portion 23d. However, since the coil spring 89 is extrapolated to the guide pipe 82, the coil spring 89 prevents the flexible tube portion 23 d from dropping from the escape groove 87 of the guide pipe 82.
The guide mechanism 77 of the present embodiment is such that, in the guide mechanism 77 of the second embodiment, the support arm portion 80 can be rotated as in the first embodiment. In the medical system of the present embodiment, the entire guide mechanism 77 can be retracted from between the connecting unit 37 connected to the connecting unit receiving portion 67 and the insertion cap 34, so that the medical system of the second embodiment is used. In comparison, a sufficient space for attaching and detaching the connecting unit 37 to and from the connecting unit receiving portion 67 can be secured.
In the embodiment described above, an endoscope is used as the insertion device, but an overtube or the like may be used. Moreover, although the pipe-shaped member is used as the guide member, a curved plate-shaped member, a square bar-shaped member in which a guide groove for guiding the flexible tube portion of the manipulator is extended, or the like may be used.
FIG. 10 shows a first reference embodiment of the present invention.
With reference to FIGS. 1 and 10, the manipulators 35a and 35b and the drive unit 54 of the present embodiment are provided with an identification mechanism for identifying the type of the manipulators 35a and 35b. In this reference embodiment, a mechanical identification mechanism is used as the identification mechanism. That is, a convex portion 98 is formed in the connecting unit 37 of the forceps manipulator 35a, and a concave portion 99 is formed in the connecting unit 37 of the treatment instrument manipulator 35b. The drive unit 54 is provided with a determination mechanism that determines whether the convex portion 98 or the concave portion 99 is formed in the connecting unit 37. The drive unit 54 outputs a determination signal indicating the determination result to the control device 53. Based on the determination signal, the control device 53 determines whether the manipulator connected to the drive unit 54 is the forceps manipulator 35a or the treatment instrument manipulator 35b, and stores it. The control device 53 controls the first and second drive units 54 in accordance with operations on the first and second master arms 46 based on the stored types of manipulators.
In the medical system of the present embodiment, the operator does not need to input whether the manipulator connected to each drive unit 54 is the forceps manipulator 35a or the treatment instrument manipulator 35b, and the input operation is omitted. It is possible to prevent the malfunction of the medical system by erroneously inputting the type of the manipulators 35a and 35b.
In the present embodiment, a mechanical identification mechanism is used as the identification mechanism. However, a software identification mechanism using an IC tag or the like, or an electrical identification mechanism using electrical resistance may be used.
11 to 13 show a first reference embodiment of the present invention.
With reference to FIG. 1 and FIGS. 11 to 13, the operation device 56 of the present embodiment has a support column 100 installed on the floor or the like. The top of the support column 100 is connected to the center of the guide rail 101. The guide rail 101 extends in the horizontal direction. Slide portions 104 of the first and second master bases 103 are attached to both end portions of the guide rail 101 so as to be slidable in the longitudinal axis direction of the guide rail 101. The slide section 104 has a concave cross section, and the slide section 104 is placed on the guide rail 101. A handle 105 is disposed on one side wall of the slide portion 104, and the handle 105 is screwed and the guide rail 101 is sandwiched between the handle 105 and the other side wall of the slide portion 104, thereby sliding relative to the guide rail 101. The portion 104 can be fixed.
The base end arms 102 of the first and second master arms 46 are supported by the base portions 106 of the first and second master bases 103, respectively. The proximal arm 102 is arranged in the vertical direction and is rotatable with respect to the master base 103 around the central axis of the proximal arm 102.
The master base 103 incorporates an encoder 107 for detecting the amount of rotation of the proximal end arm 102 relative to the master base 103. A first detection spur gear 108 a connected to the base end arm 102 and a second detection spur gear 108 b connected to the rotary shaft portion 78 of the encoder 107 mesh with each other. The gear ratio of the second detection spur gear 108b to the first detection spur gear 108a is greater than 1 in order to improve the resolution of rotation amount detection. In order to set the rotation range of the rotary shaft portion 78 of the encoder 107 to 360 ° or less, it is necessary to limit the rotation range of the proximal arm 102 to a rotation range obtained by multiplying 360 ° by the reciprocal of the gear ratio. That is, the rotation stopper 109 is connected to the base end arm 102. The rotation stopper 109 is formed of an annular portion that is coaxially fitted to the proximal end arm 102 and a protruding portion 110 that protrudes radially outward from the annular portion. On the other hand, the master arm 46 is provided with a rotation stopper receiving portion 111. An annular portion of the base end arm 102 and the rotation stopper 109 is coaxially arranged in the cylindrical wall of the rotation stopper receiving portion 111, and a rotation stopper is provided in the cutout portion 117 extending in the circumferential direction on the cylindrical wall. 109 protrusions 110 are inserted. When the protrusions 110 come into contact with both end walls of the notch 117, the rotation of the proximal arm 102 relative to the master base 103 is restricted. By appropriately setting the central angle of the notch 117, the rotation range of the proximal arm 102 can be limited to the rotation range described above.
From the viewpoint of the operability of the operating device 56, the rotation range of the base end arm 102 relative to the master base 103 is set so that the center of the rotation range always faces the operator according to the arrangement of the master base 103 with respect to the guide rail 101. It is preferable to change as appropriate. That is, a rack 112 is extended from the guide rail 101 in the axial direction of the guide rail 101. In the rack 112, a large number of teeth are arranged in parallel in the axial direction of the guide rail 101 on the top side in the longitudinal axis direction of the proximal end arm 102. A pinion 113 is meshed with the rack 112. The pinion 113 is supported by the base portion 106 so as to be rotatable about a rotation axis orthogonal to the longitudinal axis direction of the guide rail 101 and the central axis direction of the proximal arm 102. A worm gear 114 is connected to the pinion 113 coaxially with the pinion 113. A worm wheel 116 is engaged with the worm gear 114. The worm wheel 116 is supported by the base portion 106 coaxially with the base end arm 102 so as to be rotatable about the central axis of the base end arm 102, and the base end arm 102 is formed in the central opening of the worm wheel 116. It is inserted. A stopper receiving portion 91 is coaxially connected to the worm wheel 116 on the top side in the longitudinal axis direction of the proximal arm 102. When the master base 103 is moved with respect to the guide rail 101, the pinion 113 meshed with the rack 112 of the guide rail 101 rotates, and the rotation is transmitted to the pinion 113, the worm gear 114, and the worm wheel 116, and the worm The rotation stopper receiving portion 111 connected to the wheel 116 is rotated, and the center of the rotation range of the proximal end arm 102 is changed. With such a mechanism, the rotation range of the base end arm 102 of the master arm 46 can be optimally set according to the arrangement of the master base 103 with respect to the guide rail 101. Further, the rotation is easily transmitted from the worm gear 114 to the worm wheel 116, but the rotation is not easily transmitted from the worm wheel 116 to the worm gear 114. Therefore, by operating the master arm 46, the base end arm 102 is rotated with respect to the master base 103, and the protrusion 110 of the rotation stopper 109 of the base end arm 102 is the end of the notch 117 of the rotation stopper receiving portion 111. Even if it contacts the wall, the rotation is not transmitted from the worm wheel 116 connected to the rotation stopper receiving portion 111 to the worm gear 114, and the rotation stopper receiving portion 111 does not rotate. The rotation is not transmitted to the pinion 113.
In the medical system according to the present embodiment, in the operation device 56, the resolution of detecting the rotation amount of the proximal arm 102 with respect to the master base 103 is improved, and the proximal arm 102 is changed according to the arrangement of the master base 103 with respect to the guide rail 101. The rotation range can be set optimally, and the operability of the operating device 56 can be improved.
Schematic which shows the medical system of 1st Embodiment of this invention. The perspective view which shows the forceps manipulator of 1st Embodiment of this invention. The perspective view which shows the drive unit of 1st Embodiment of this invention. It is a longitudinal cross-sectional view which shows the drive unit of 1st Embodiment of this invention. It is a cross-sectional view which cut | disconnects and shows the drive unit of 1st Embodiment of this invention along the IVB-IVB line | wire of FIG. 4A. The side view which shows the medical system of 1st Embodiment of this invention in an operating state. The side view which shows the medical system of 1st Embodiment of this invention in the attachment or detachment state. The longitudinal cross-sectional view which shows the manipulator and guide mechanism of 1st Embodiment of this invention. The cross-sectional view which shows the manipulator and guide mechanism of 1st Embodiment of this invention. The side view which shows the medical system of 2nd Embodiment of this invention in a reverse operation state. The side view which shows the medical system of 2nd Embodiment of this invention in a forward operation state. The side view which shows the medical system of 2nd Embodiment of this invention in an attachment or detachment state. The longitudinal cross-sectional view which shows the manipulator and guide mechanism of 2nd Embodiment of this invention. The perspective view which shows the manipulator of the 1st reference form of this invention. The external view which shows the rotation control mechanism of the 2nd reference form of this invention. The cross-sectional view which shows the rotation control mechanism of the 2nd reference form of this invention. The cross-sectional view which cuts and shows the rotation control mechanism of the 2nd reference form of this invention along the XIII-XIII line | wire of FIG.
DESCRIPTION OF SYMBOLS 16 ... Insertion device (endoscope), 22d, 36; 22d ... Actuation part, 22d ... Bending part, 36 ... Gripping part, 23d ... Transmission part (flexible tube part), 30; 36 ... Actuation mechanism, 30 ... Joint 34, 34, 85, 86 ... Base end opening, 34 ... Insertion cap, 85 ... Guide tube, 86 ... Insertion cap, 35a; 35b ... Surgical device, 35a ... Forceps manipulator , 35b ... treatment instrument manipulator, 37 ... connecting portion (connecting unit), 47 ... transmission member (operation wire), 48 ... connecting mechanism (pulley), 54 ... driving device (driving unit), 61; 63 ... driving mechanism, 61 ... Advance / retreat drive unit, 63 ... Rotation drive unit, 67 ... Connection receiving part (connection unit receiving part), 72 ... Drive connection mechanism (pulley drive unit), 77 ... Guide mechanism, 82 ... Guide member (guide pad) ), 80... Evacuation support mechanism (support arm portion), follow-up support mechanism (support arm portion), support mechanism (support arm portion), 84... Detachable portion (detachment groove), 87. Follow-up relief (escape groove), 89 ... Fall-off prevention member (coil spring), urging mechanism (coil spring), 90b ... Contact part (base end stopper), 91 ... Contact receiver (stopper receiver), 97 ... Locking mechanism (locking unit).
An insertion device to be inserted into a body cavity, comprising: a channel extending between a distal end portion and a proximal end portion of the insertion device; and a proximal end opening connected to the proximal end portion of the channel. An insertion device having
A surgical device that is inserted into the channel from the proximal end opening and is inserted into the channel, and is provided at an operating portion provided at a distal end portion of the surgical device, and at a proximal end portion of the surgical device. A surgical device having a connection part, and a transmission part that extends between the operation part and the connection part and transmits a driving force applied to the connection part to the operation part;
A drive device having a connection receiving part to which the connection part is connected, and a drive mechanism for driving the connection part connected to the connection receiving part;
The connecting portion and the proximal end opening, which are disposed between the connecting portion connected to the connecting receiving portion and the proximal end opening, support the transmitting portion, and connect the transmitting portion to the connecting receiving portion. A guide mechanism having a guide member harder than the transmission unit,
The connecting portion is detachable from the connecting receiving portion,
The guide mechanism movably supports the guide member in a retracted position where at least a part of the guide member is retracted from between the connecting portion where the connecting receiving portion is connected to the base end opening. Having a retraction support mechanism,
The medical system according to claim 1.
The guide member has an attachment / detachment portion that allows the transmission portion to be attached to and detached from the guide member in a direction intersecting a guide direction of the transmission portion by the guide member.
The medical system according to claim 2.
The guide member is configured to extend between the connection portion connected to the connection receiving portion and the base end opening with respect to the movement of the guide member to the retracted position, and the base end opening. A retreat escape portion for escaping at least one of the transmission portion and the base end opening so that the guide member does not interfere with at least one of the portions,
The guide mechanism has a drop-off preventing member that covers the escape escape portion from the outside of the guide member.
The guide mechanism includes a follow-up support mechanism that supports the guide member so as to be movable in the driving direction of the connecting portion, and biases the guide member toward the connecting receiving portion in the driving direction of the connecting portion. A biasing mechanism, and the guide member has a contact portion provided at an end portion on the connection receiving portion side,
The connecting portion includes a contact receiving portion that is disposed at a proximal end portion of the transmission portion and is in contact with the contact portion.
The guide member extends between the connection portion connected to the connection receiving portion and the proximal end opening with respect to the movement of the guide member in the driving direction of the connection portion, and A follow-up relief portion that escapes at least one of the transmission portion and the base end opening so that the guide member does not interfere with at least one of the base end openings;
The medical system according to claim 6.
The guide mechanism includes a drop-off prevention member that covers the follow-up relief portion from the outside of the guide member.
The medical system according to claim 7.
The guide mechanism supports the guide member so as to be movable in the driving direction of the connecting portion, and the guide member and at least a part of the guide member are connected to the connecting receiving portion and the base end opening portion. A support mechanism that can be disposed at a retracted position that is retracted in the driving direction of the connecting portion from between and a biasing force that biases the guide member toward the connecting receiving portion in the driving direction of the connecting portion A mechanism and a locking mechanism capable of locking the guide member at the retracted position, and the guide member has a contact portion provided at an end portion on the connection receiving portion side,
The connection portion is detachable from the connection receiving portion, and has a contact receiving portion that is disposed at a base end portion of the transmission portion and is in contact with the contact portion.
The surgical apparatus includes: an operating mechanism provided in the operating unit; a connecting mechanism provided in the connecting unit; and the connecting mechanism that is inserted through the transmission unit and extends between the operating mechanism and the connecting mechanism. A transmission member that transmits the driving force applied to the operating mechanism to operate the operating mechanism;
The drive device includes a drive connection mechanism that drives the connection mechanism.
JP2008330938A 2008-05-09 2008-12-25 Medical system Active JP5289929B2 (en)
US12/118,319 2008-05-09
US12/118,319 US20090281378A1 (en) 2008-05-09 2008-05-09 Medical system
JP2009268889A true JP2009268889A (en) 2009-11-19
JP2009268889A5 JP2009268889A5 (en) 2012-02-02
JP5289929B2 JP5289929B2 (en) 2013-09-11
ID=40668116
JP2008330938A Active JP5289929B2 (en) 2008-05-09 2008-12-25 Medical system
US (1) US20090281378A1 (en)
EP (1) EP2116175B1 (en)
JP (1) JP5289929B2 (en)
CN (1) CN101574271B (en)
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JPS50108287U (en) * 1974-02-12 1975-09-04
JPS50138882U (en) * 1974-04-30 1975-11-15
WO2007096951A1 (en) * 2006-02-21 2007-08-30 Olympus Medical Systems Corp. Endoscope system and medical instrument
WO2007138674A1 (en) * 2006-05-30 2007-12-06 Olympus Medical Systems Corp. Endoscope treatment system
JP2008000580A (en) * 2006-06-23 2008-01-10 Olympus Medical Systems Corp Endoscope system, treatment instrument cartridge, and storage case
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JP4282554B2 (en) * 2004-06-02 2009-06-24 オリンパス株式会社 Endoscope treatment instrument system
2008-05-09 US US12/118,319 patent/US20090281378A1/en not_active Abandoned
2008-12-25 JP JP2008330938A patent/JP5289929B2/en active Active
2009-01-23 EP EP09000971.3A patent/EP2116175B1/en active Active
2009-02-10 CN CN2009100063512A patent/CN101574271B/en active IP Right Grant
EP2116175B1 (en) 2013-10-23
EP2116175A1 (en) 2009-11-11
US20090281378A1 (en) 2009-11-12
JP5289929B2 (en) 2013-09-11
CN101574271A (en) 2009-11-11
CN101574271B (en) 2013-07-31
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JP5059001B2 (en) 2012-10-24 Surgical equipment
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JP4464816B2 (en) 2010-05-19 Surgical device