TREATMENT APPARATUS

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a treatment apparatus such as forceps or a manipulator which is configured to be inserted into the body cavity of a patient to treat a morbid section.

2. Description of the Related Art

Jpn. Pat. Appln. KOKAI Publication No. 2009-142513 discloses a high-frequency treatment apparatus which is configured to grip a morbid section with a grip portion including high-frequency electrodes to treat the morbid section. This high-frequency treatment apparatus includes an insertion section configured to be inserted into a body cavity, and an operation section provided to a proximal direction side of the insertion section. The insertion section includes a distal treatment section provided with a grip portion, and a flexible tube section which is provided to the proximal direction side of the distal treatment section and which extends in longitudinal directions. When a rotating operation of the distal treatment section is performed, the rotational torque generated by the rotating operation of the operation section is transferred to the distal treatment section via a conductive line extending through the flexible tube section. This rotates the distal treatment section to directions about an axis relative to the flexible tube section. In addition, pulling or loosening the conductive line will make the grip portion perform opening/closing movement between an open state and a closed state. That is, the conductive line serves as a rotating operation transfer member which transfers rotating operation to the distal treatment section and a grip operation transfer member which transfers grip operation to the grip portion.

BRIEF SUMMARY OF THE INVENTION

According to one aspect of the invention, a treatment apparatus includes a flexible tube section which extends in longitudinal directions, and which has a longitudinal directions axis; a distal treatment section which includes a grip portion configured to perform opening/closing movement between an open state and a closed state, and which is provided to a distal direction side of the flexible tube section so as to be rotatable to the directions about an axis relative to the flexible tube section; a grip operation section which is provided to a proximal direction side of the flexible tube section, and which is configured to input grip operation of the grip portion; a grip operation linear portion which extends from the grip operation section into the flexible tube section, and which is moved along the longitudinal directions axis by the grip operation of the grip operation section; an actuated member which is provided to be connected to the grip portion, and whose actuated state is configured to change between a first actuated state in which the grip portion is actuated to the closed state and a second actuated state in which the grip portion is actuated to the open state; and a junction coupling portion which couples between the grip operation linear portion and the actuated member so as to change the actuated state of the actuated member in accordance with movement of the grip operation linear portion along the longitudinal directions axis, the junction coupling portion coupling between the grip operation linear portion and the actuated member so as to allow the grip operation linear portion and the actuated member to rotate the directions about the axis relative to each other.

Advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The advantages of the invention may be realized and obtained by means of the instrumentalities and combinations particularly pointed out hereinafter.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention, and together with the general description given above and the detailed description of the embodiments given below, serve to explain the principles of the invention.

FIG. 1 is a schematic view showing a treatment apparatus according to the first embodiment of the present invention;

FIG. 2 is a sectional view schematically showing the configuration of the operation section of the treatment apparatus according to the first embodiment;

FIG. 3 is a sectional view taken along a line III-III in FIG. 1;

FIG. 4 is a perspective view schematically showing the configuration of a distal direction side part of the treatment apparatus according to the first embodiment;

FIG. 5 is a sectional view schematically showing the configuration of the distal direction side part of the treatment apparatus according to the first embodiment;

FIG. 6 is s sectional view schematically showing the distal direction side part of the treatment apparatus according to the first embodiment using a section different from that of FIG. 5;

FIG. 7 is a perspective view schematically showing the configuration of the distal direction side part of the treatment apparatus according to the first embodiment with the outer cover being removed;

FIG. 8 is a bottom view schematically showing the configuration of the distal direction side part of the treatment apparatus according to the first embodiment with the outer cover being removed;

FIG. 9 is an enlarged sectional view of a range X1 in FIG. 5;

FIG. 10 is an enlarged sectional view of a range X2 in FIG. 6;

FIG. 11 is a sectional view schematically showing the distal direction side part of the treatment apparatus according to the first embodiment while the actuated member is in the second operation state;

FIG. 12 is a schematic view explaining a rotating movement of the distal treatment section of the treatment apparatus according to the first embodiment;

FIG. 13 is a schematic view showing a treatment apparatus according to the first modification of the first embodiment;

FIG. 14 is a perspective view schematically showing the distal direction side part of a treatment apparatus according to the second modification of the first embodiment;

FIG. 15 is a sectional view schematically showing the configuration between the grip operation wire and the grip portion of a treatment apparatus according to the third modification of the first embodiment;

FIG. 16 is a sectional view schematically showing the configuration between the grip operation wire and the grip portion of a treatment apparatus according to the fourth modification of the first embodiment;

FIG. 17 is a sectional view schematically showing the configuration between the grip operation wire and the grip portion of a treatment apparatus according to the fifth modification of the first embodiment;

FIG. 18 is a sectional view schematically showing the configuration of the distal direction side part of a treatment apparatus according to the sixth modification of the first embodiment;

FIG. 19 is a sectional view schematically showing the configuration of the distal direction side part of a treatment apparatus according to the second embodiment of the present invention;

FIG. 20 is a sectional view schematically showing the configuration of the distal direction side part of a treatment apparatus according to the third embodiment of the present invention;

FIG. 21 is a sectional view taken along a line 21-21 in FIG. 20; and

FIG. 22 is a sectional view schematically showing an example of the interior of the flexible tube section of the treatment apparatus according to the third embodiment while the shape of the flexible tube section has changed.

DETAILED DESCRIPTION OF THE INVENTION
First Embodiment

The first embodiment of the present invention will be described with reference to FIGS. 1 to 12.

FIG. 1 is a view showing the configuration of a treatment apparatus 1 according to this embodiment. As shown in FIG. 1, the treatment apparatus 1 includes an insertion section 2 configured to be inserted into a body cavity, and an operation section 3 provided to a proximal direction side to the insertion section 2. The insertion section 2 includes a distal treatment section 4 which is configured to perform treatment, and a flexible tube section 5 which is provided to the proximal direction side of the distal treatment section 4 and extends in longitudinal directions. The distal treatment section 4 is provided with a grip portion 6 which is configured to grip a tissue or the like. The grip portion 6 is configured to perform opening/closing movement between an open state (indicated by the dotted lines in FIG. 1) and a closed state (indicated by the solid lines in FIG. 1). The flexible tube section 5 has a longitudinal directions axis C.

FIG. 2 is a view showing the configuration of the operation section 3. As shown in FIG. 2, the operation section 3 includes an operation section main body 10, a grip operation handle 11 serving as a grip operation section which is configured to perform the grip operation of gripping a tissue or the like with the grip portion 6, and a rotating operation handle 12 serving as a rotating operation section which is configured to perform the rotating operation of rotating the distal treatment section 4 to directions about an axis relative to the flexible tube section 5.

The grip operation handle 11 is mounted on the operation section main body 10 so as to be movable in the longitudinal directions relative to the operation section main body 10. A proximal end of a grip operation wire 16 serving as a grip operation transfer member, which transfers grip operation to the grip portion 6, is fixed to the grip operation handle 11. The grip operation wire 16 extends in the longitudinal directions through the interior of the flexible tube section 5. Inside the flexible tube section 5, the grip operation wire 16 extends through a coil pipe (third coil pipe) 17 used in grip operation. The grip operation wire 16 is pulled or loosened by moving the grip operation handle 11 in the longitudinal directions relative to the operation section main body 10.

The rotating operation handle 12 is mounted on the operation section main body 10 so as to be rotatable to the directions about (around) the axis relative to the operation section main body 10. A bevel gear 20 is coupled to the rotating operation handle 12. The bevel gear 20 includes a first gear 20A coupled to the rotating operation handle 12, and a second gear 20B meshed with the first gear 20A. Proximal ends of first and second rotating operation wires 21A and 21B serving as rotating operation transfer members, which transfer rotating operation to the distal treatment section 4, are connected to the second gear 20B. The first and second rotating operation wires 21A and 21B are guided into the flexible tube section 5 by guide pulleys 22, and extend in almost longitudinal directions inside the flexible tube section 5. Inside the flexible tube section 5, the first rotating operation wire 21A extends through a coil pipe (first coil pipe) 23A used in rotating operation, and the second rotating operation wire 21B extends through a coil pipe (second coil pipe) 23B used in rotating operation. When the rotating operation handle 12 is rotated to the directions about the axis, the first gear 20A of the bevel gear 20 rotates together with the rotating operation handle 12 to the directions about the axis. As the first gear 20A rotates, the second gear 20B rotates about an axis perpendicular to the longitudinal directions. As the second gear 20B rotates in one rotation direction, the first rotating operation wire 21A is pulled, and the second rotating operation wire 21B is loosened. As the second gear 20B rotates in the other rotation direction, the first rotating operation wire 21A is loosened, and the second rotating operation wire 21B is pulled.

FIG. 3 is a sectional view taken along a line III-III in FIG. 1. As shown in FIG. 3, inside the flexible tube section 5, the grip operation wire 16 extends in a state that its axis almost coincides with the longitudinal directions axis C of the flexible tube section 5. In addition, inside the flexible tube section 5, the first and second rotating operation wires 21A and 21B are provided to an outer direction side of an outer surface of the coil pipe 17. The first rotating operation wire 21A is spaced apart from the second rotating operation wire 21B by almost 180° in the directions about the axis. With this configuration, an inner diameter of the flexible tube section 5 is larger than the sum of outer diameters of the coil pipe 17 and coil pipes 23A and 23B.

FIGS. 4 to 6 are views showing the configuration of the distal direction side part of the treatment apparatus 1. As shown in FIGS. 4 to 6, a rotor 26 is provided between the distal treatment section 4 and the flexible tube section 5 while being fixed to the distal treatment section 4. A rotor support member 27 is provided between the rotor 26 and the flexible tube section 5. The rotor support member 27 is fixed to the flexible tube section 5. The rotor 26 is coupled to the rotor support member 27 so as to be rotatable to the directions about the axis. A cylindrical outer cover 29 is provided to the outer direction side of the rotor support member 27. The outer cover 29 is fixedly coupled to the flexible tube section 5. This configuration allows the distal treatment section 4 and the rotor 26 to rotate together to the directions about the axis relative to the flexible tube section 5, the rotor support member 27, and the outer cover 29.

As shown in FIGS. 4 to 6, the distal treatment section 4 includes a treatment section main body 25. A first clamping portion 35A and a second clamping portion 35B, which constitute the grip portion 6, are pivotably supported on the treatment section main body 25 through a coupling pin 36. The first and second clamping portions 35A and 35B can rotate together with the treatment section main body 25 to the directions about the axis relative to the flexible tube section 5. In addition, the first and second clamping portions 35A and 35B can rotate about the coupling pin 36 relative to the treatment section main body 25. When the first and second clamping portions 35A and 35B rotate relative to the treatment section main body 25, the grip portion 6 performs opening/closing movement between the closed state and the open state.

FIGS. 7 and 8 are views showing the configuration of the distal direction side part of the treatment apparatus 1 with the outer cover 29 being removed. As shown in FIG. 8, a proximal direction side part of the treatment section main body 25 (distal treatment section 4) is provided with a through hole 41. The coupling portion between the rotor 26 and the distal treatment section 4 is provided with a wire fixing portion 40 which fixes the distal ends of the first and second rotating operation wires 21A and 21B. The first rotating operation wire 21A, whose distal end is fixed to the wire fixing portion 40, extends to the outer direction side of the treatment section main body 25 through the through hole 41. Likewise, the second rotating operation wire 21B, whose distal end is fixed to the wire fixing portion 40, extends to the outer direction side of the treatment section main body 25 through the through hole 41.

In this embodiment, the rotor 26 is provided with the wire fixing portion 40. However, the embodiment is not limited to this. For example, the treatment section main body 25 of the distal treatment section 4 may be provided with the wire fixing portion 40 to which the distal ends of the first and second rotating operation wires 21A and 21B are fixed. That is, the wire fixing portion 40 is provided to the rotor 26 or a portion to the distal direction side of the rotor 26. In addition, although the distal treatment section 4 and the rotor 26 are separate members, they may be integrally formed. That is, the distal treatment section 4 and the rotor 26 may be configured to rotate to the direction about the axis relative to the flexible tube section 5.

As shown in FIG. 7, an outer surface of the rotor support member 27 is provided with a first convex portion 47A and a second convex portion 47B which protrude in the outer direction. The first convex portion 47A is spaced apart from the through hole 41 in the circumferential directions. The second convex portion 47B is spaced apart from the through hole 41 in the circumferential directions toward a direction opposite to a direction toward the first convex portion 47A. A first hole portion 46A and a second hole portion 46B are provided to a portion to the proximal direction side of the first convex portion 47A (second convex portion 47B) of the rotor support member 27.

As shown in FIGS. 7 and 8, the first rotating operation wire 21A, extending from the wire fixing portion 40 in the outer direction, extends on the outer surface of the rotor 26 along a first oblique direction inclining from the longitudinal directions to the circumferential directions. The first rotating operation wire 21A, extending on the outer surface of the rotor 26, abuts against the first convex portion 47A of the rotor support member 27. Making the first rotating operation wire 21A abut against the first convex portion 47A will change an extending direction of the first rotating operation wire 21A from the first oblique direction. The first rotating operation wire 21A is then inserted into the flexible tube section 5 from the first hole portion 46A. The first rotating operation wire 21A, inserted in the flexible tube section 5, extends to the rotating operation section (rotating operation handle 12).

The second rotating operation wire 21B, extending from the wire fixing portion 40 in the outer direction, extends on the outer surface of the rotor 26 along a second oblique direction inclining from the longitudinal directions to the circumferential directions toward a direction opposite to a direction toward the first oblique direction. The second rotating operation wire 21B, extending on the outer surface of the rotor, abuts against the second convex portion 47B of the rotor support member 27. Making the second rotating operation wire 21B abut against the second convex portion 47B will change an extending direction of the second rotating operation wire 21B from the second oblique direction. The second rotating operation wire 21B is then inserted from the second hole portion 46B into the flexible tube section 5. The second rotating operation wire 21B, inserted in the flexible tube section 5, extends to the rotating operation section (rotating operation handle 12).

As shown in FIG. 5, a distal end portion of the flexible tube section 5 is provided with a coil lock 45. A distal end of the coil pipe 17 used in grip operation, through which the grip operation wire 16 extends, is fixed to the coil lock 45. The grip operation wire 16 extends to the distal direction side of the distal end of the coil pipe 17.

FIG. 9 is an enlarged view of a range X1 in FIG. 5. FIG. 10 is an enlarged view of a range X2 in FIG. 6. As shown in FIGS. 9 and 10, a coupling shaft 51 as a wire distal member is provided to the distal direction side of the grip operation wire 16. The coupling shaft 51 is provided in a state that the coupling shaft 51 is fixed to the grip operation wire 16 through a junction member 52. When the grip operation wire 16 is pulled or loosened, the coupling shaft 51 moves in the longitudinal directions. The coupling shaft 51 includes a large-diameter portion 53, and a small-diameter portion 54 continuous to the proximal direction side of the large-diameter portion 53. A step portion 55 is provided between the large-diameter portion 53 and the small-diameter portion 54. The step portion 55 includes a curved surface 57 having an arcuated section taken parallel to the longitudinal directions axis C.

A shaft bearing 61 as a coupling member is fixed to the inner surface of the rotor 26. The shaft bearing 61 can rotate together with the distal treatment section 4 and the rotor 26 to the directions about the axis relative to the coupling shaft 51. The shaft bearing 61 includes a first coupling portion 62 with which the coupling shaft 51 is coupled to the shaft bearing 61 so as to be movable in the longitudinal directions. An accommodation portion 63, in which the large-diameter portion 53 of the coupling shaft 51 is accommodated, is formed in the shaft bearing 61. The accommodation portion 63 is provided with an opening portion 65 which is open toward the distal direction. A hole-like portion 67 is formed to the proximal direction side of the accommodation portion 63 so as to communicate with the accommodation portion 63. The small-diameter portion 54 of the coupling shaft 51 extends through the hole-like portion 67. The small-diameter portion 54 of the coupling shaft 51 is coupled to the junction member 52 at a portion to the proximal direction side of a proximal end of the shaft bearing 61.

A proximal direction side part of the shaft bearing 61 is provided with a first regulation portion 69 which is configured to regulate an amount of movement of the coupling shaft 51 in the proximal direction. The first regulation portion 69 is formed by providing a step on the inner surface of the shaft bearing 61. Making the step portion 55 of the coupling shaft 51 abut against the first regulation portion 69 will prevent the movement of the coupling shaft 51 in the proximal direction. That is, the step portion 55 serves as the first abutment portion, which is configured to prevent the movement of the coupling shaft 51 in the proximal direction by abutting against the first regulation portion 69. The step portion 55 abuts against the first regulation portion 69 of the shaft bearing 61 on the curved surface 57. In the above manner, with the first coupling portion 62, the coupling shaft 51 is coupled to the shaft bearing 61 so as to be movable in the longitudinal directions.

An actuated member 71 is provided to the distal direction side of the coupling shaft 51 while being connected to the grip portion 6. The shaft bearing 61 includes a second coupling portion 72 to which the actuated member 71 is coupled so as to be rotatable together with the distal treatment section 4 to the directions about the axis relative to the coupling shaft 51 and the flexible tube section 5. In addition, the actuated member 71 is coupled to the shaft bearing 61 so as to be movable in the longitudinal directions. The actuated member 71 includes a columnar portion 73, and first and second rod-like portions 75A and 75B extending from the columnar portion 73 in the distal direction. The first rod-like portion 75A is connected to the first clamping portion 35A through a first connecting portion 76A, and the second rod-like portion 75B is connected to the second clamping portion 35B through a second connecting portion 76B (see FIGS. 5 and 6). A step portion 77 is provided between the columnar portion 73 and the first rod-like portion 75A (second rod-like portion 75B).

The shaft bearing 61 is provided with a second regulation portion 79 which is configured to regulate an amount of movement of the actuated member 71 in the distal direction. The second regulation portion 79 is formed by providing a step on the inner surface of the shaft bearing 61. Making the step portion 77 of the actuated member 71 abut against the second regulation portion 79 will prevent the movement of the actuated member 71 in the distal direction. That is, the step portion 77 serves as the second abutment portion, which is configured to prevent the movement of the actuated member 71 in the distal direction by abutting against the second regulation portion 79. In the above manner, the actuated member 71 is coupled to the second coupling portion 72 of the shaft bearing 61 so as to be rotatable to the directions about the axis relative to the coupling shaft 51. The actuated member 71 is a moving member coupled to the second coupling portion 72 of the shaft bearing 61 so as to be movable in the longitudinal directions relative to the shaft bearing 61. In addition, the shaft bearing 61 is a rotating member coupled to the coupling shaft 51 at the first coupling portion 62 so as to be rotatable together with the actuated member 71 to the directions about the axis relative to the coupling shaft 51.

An actuated state of the actuated member 71 changes in accordance with the movement of the coupling shaft 51 in the longitudinal directions. The actuated state of the actuated member 71 changes between the first actuated state in which the grip portion 6 is actuated to the closed state (indicated by the solid lines in FIG. 1) and the second actuated state in which the grip portion 6 is actuated to the open state (indicated by the dotted lines in FIG. 1).

FIG. 5 is a view showing the distal direction side part of the treatment apparatus 1 when the actuated member 71 is in the first actuated state. In the first actuated state, the actuated member 71 is not in contact with the coupling shaft 51, and hence no force acts from the coupling shaft 51. When no force acts from the coupling shaft 51, the actuated member 71 changes to the first actuated state due to, for example, the biasing force of a biasing member (not shown). In addition, the first rod-like portion 75A is biased by, for example, an elastic force to a state in which it opens in a direction of an arrow A1 in FIG. 5. Likewise the second rod-like portion 75B is biased by, for example, an elastic force to a state in which it opens in a direction of an arrow A2 in FIG. 5. In the first actuated state, the inner surface of the shaft bearing 61 regulates the opening movement of the first and second rod-like portions 75A and 75B. Regulating the opening movement of the first and second rod-like portions 75A and 75B prevents the first and second clamping portions 35A and 35B from pivoting from the closed state relative to the treatment section main body 25. Therefore, when the actuated member 71 is in the first actuated state, the grip portion 6 is actuated to the closed state.

FIG. 11 is a view showing the distal direction side part of the treatment apparatus 1 when the actuated member 71 is in the second actuated state. When the grip operation wire 16 is loosened by gripping operation with the grip operation handle 11, the coupling shaft 51 as a wire distal member moves in the distal direction. When the coupling shaft 51 moves in the distal direction while the actuated member 71 is in the first actuated state, the coupling shaft 51 comes into contact with the actuated member 71. As a consequence, a force acts from the coupling shaft 51 to the actuated member 71. This causes the actuated member 71 to move in the distal direction and changes the actuated state to the second actuated state. That is, when the actuated member 71 moves from the first actuated state in the distal direction in accordance with the movement of the coupling shaft 51 in the distal direction, the actuated state changes to the second actuated state. In the second actuated state, the inner surface of the shaft bearing 61 does not regulate the opening movement of the first and second rod-like portions 75A and 75B. For this reason, the first rod-like portion 75A opens in the direction of an arrow A1 in FIG. 11, and the second rod-like portion 75B opens in the direction of an arrow A2 in FIG. 11. When the first rod-like portion 75A opens, the first clamping portion 35A pivots in a direction of an arrow B1 in FIG. 11 relative to the treatment section main body 25. When the second rod-like portion 75B opens, the second clamping portion 35B pivots in a direction of an arrow B2 in FIG. 11 relative to the treatment section main body 25. When, therefore, the actuated member 71 is in the second actuated state, the grip portion 6 is actuated to the open state.

When the grip operation wire 16 is pulled by performing grip operation with the grip operation handle 11, the coupling shaft 51 as a wire distal member moves in the proximal direction. When the coupling shaft 51 moves in the proximal direction while the actuated member 71 is in the second actuated state, no force acts from the coupling shaft 51 to the actuated member 71. As described above, when no force acts from the coupling shaft 51, the actuated member 71 moves in the proximal direction, and the actuated member 71 changes to the first actuated state. That is, when the actuated member 71 moves in the proximal direction from the second actuated state in accordance with the movement of the coupling shaft 51 in the proximal direction, the actuated state changes to the first actuated state. When the actuated member 71 changes to the first actuated state, the grip portion 6 is actuated to the closed state.

The function of the treatment apparatus 1 according to this embodiment will be described next. When rotating the distal treatment section 4 of the treatment apparatus 1 to the directions about the axis relative to the flexible tube section 5, the rotating operation handle 12 is rotated in one rotation direction. This pulls the first rotating operation wire 21A and loosens the second rotating operation wire 21B through the bevel gear 20. When the first rotating operation wire 21A is pulled, the distal treatment section 4 rotates in the first rotation direction which is one rotation direction.

FIG. 12 is a view explaining the rotating movement of the distal treatment section 4. The first rotating operation wire 21A extends on the outer surface of the rotor 26, between the wire fixing portion 40 and the first convex portion 47A, along the first oblique direction inclining from the longitudinal directions to the circumferential directions. In this case, the first oblique direction is a direction inclining from the longitudinal directions to the first rotation direction. As shown in FIG. 12, when the first rotating operation wire 21A is pulled, a force F acts on the rotor 26 in the first oblique direction. The force F is decomposed into a force F1 in the longitudinal directions and a rotational force F2 in the first rotation direction (circumferential directions). The rotational force F2 rotates the rotor 26 in the first rotation direction. At this time, the distal treatment section 4 rotates together with the rotor 26 to the directions about the axis. In the above manner, the distal treatment section 4 and the rotor 26 rotate in the first rotation direction relative to the flexible tube section 5 and the rotor support member 27.

On the other hand, when the rotating operation handle 12 is rotated in the other rotation direction, the first rotating operation wire 21A is loosened and the second rotating operation wire 21B is pulled through the bevel gear 20. Pulling the second rotating operation wire 21B will rotate the distal treatment section 4 in the second rotation direction opposite to the first rotation direction. The second rotating operation wire 21B extends on the outer surface of the rotor 26, between the wire fixing portion 40 and the second convex portion 47B, along the second oblique direction inclining from the longitudinal directions to the circumferential directions. In this case, the second oblique direction is a direction inclining from the longitudinal directions to the second rotation direction. When the second rotating operation wire 21B is pulled, a force acts on the rotor 26 in the second oblique direction. The force in the second oblique direction is decomposed into a force in the longitudinal directions and a rotational force in the second rotation direction (circumferential directions). With the rotational force in the second rotation direction, the rotor 26 rotates in the second rotation direction. At this time, the distal treatment section 4 rotates together with rotor 26 to the directions about the axis. In the above manner, the distal treatment section 4 and the rotor 26 rotate in the second rotation direction relative to the flexible tube section 5 and the rotor support member 27.

When gripping a tissue or the like with the grip portion 6 of the distal treatment section 4, the grip operation handle 11 is moved in the longitudinal directions relative to the operation section main body 10 to pull or loosen the grip operation wire 16. When no force acts from the coupling shaft 51, the actuated member 71 changes to the first actuated state. In the first actuated state, the inner surface of the shaft bearing 61 regulates the opening movement of the first and second rod-like portions 75A and 75B. Since the opening movement of the first and second rod-like portions 75A and 75B is regulated, the first and second clamping portions 35A and 35B do not pivot from the closed state relative to the treatment section main body 25. As a consequence, the grip portion 6 is actuated to the closed state.

When the grip operation wire 16 is loosened by performing griping operation with the grip operation handle 11, the coupling shaft 51 as a wire distal member moves in the distal direction. When the coupling shaft 51 moves in the distal direction while the actuated member 71 is in the first actuated state, the coupling shaft 51 comes into contact with the actuated member 71, and a force acts from the coupling shaft 51 onto the actuated member 71 in the distal direction. With this operation, the actuated member 71 moves in the distal direction, and the actuated state changes to the second actuated state. In the second actuated state, the inner surface of the shaft bearing 61 does not regulate the opening movement of the first and second rod-like portions 75A and 75B. For this reason, the opening movement of the first rod-like portion 75A makes the first clamping portion 35A pivot relative to the treatment section main body 25 in the direction of the arrow B1 in FIG. 11, and the opening movement of the second rod-like portion 75B makes the second clamping portion 35B pivot relative to the treatment section main body 25 in the direction of the arrow B2 in FIG. 11. As a consequence, the grip portion 6 is actuated to the open state.

When the grip operation wire 16 is pulled by performing griping operation with the grip operation handle 11, the coupling shaft 51 as a wire distal member moves in the proximal direction. When the coupling shaft 51 moves in the proximal direction while the actuated member 71 is in the second actuated state, no force acts from the coupling shaft 51 onto the actuated member 71. As described above, when no force acts from the coupling shaft 51, the actuated member 71 moves in the proximal direction and changes to the first actuated state. When the actuated member 71 changes to the first actuated state, the grip portion 6 is actuated to the closed state. The grip portion 6 then grips a tissue or the like in the closed state.

The treatment apparatus 1 is provided with the coupling shaft 51 as a wire distal member which is fixed to the grip operation wire 16. The coupling shaft 51 is coupled to the first coupling portion 62 of the shaft bearing 61 as a coupling member so as to be movable in the longitudinal directions relative to the shaft bearing 61. In addition, the actuated member 71 is coupled to the second coupling portion 72 of the shaft bearing 61 so as to be rotatable together with the distal treatment section 4 to the directions about the axis relative to the coupling shaft 51 and the flexible tube section 5. Since the actuated member 71 is rotatable together with the distal treatment section 4 relative to the coupling shaft 51, no torsion occurs in the grip operation wire 16 when the distal treatment section 4 rotates relative to the flexible tube section 5.

The first coupling portion 62 of the shaft bearing 61 is provided with the first regulation portion 69 which is configured to regulate the amount of movement of the coupling shaft 51 in the proximal direction. The coupling shaft 51 includes the step portion 55 (first abutment portion) which is configured to prevent the movement of the coupling shaft 51 in the proximal direction by abutting against the first regulation portion 69. Providing the first regulation portion 69 and the step portion 55 couples the coupling shaft 51 to the first coupling portion 62 while the coupling shaft 51 is movable in the longitudinal directions relative to the shaft bearing 61. The second coupling portion 72 of the shaft bearing 61 is provided with the second regulation portion 79 which is configured to regulate the amount of movement of the actuated member 71 in the distal direction. The actuated member 71 includes the step portion 77 (second abutment portion) which is configured to prevent the movement of the actuated member 71 in the distal direction by abutting against the second regulation portion 79. Providing the second regulation portion 79 and the step portion 77 couples the actuated member 71 to the second coupling portion 72 while the actuated member 71 is movable in the longitudinal directions relative to the shaft bearing 61.

The shaft bearing 61 is a rotating member which is coupled to the coupling shaft 51 at the first coupling portion 62 so as to be rotatable together with the actuated member 71 to the directions about the axis relative to the coupling shaft 51. The step portion 55 of the coupling shaft 51 includes the curved surface 57 which abuts against the first regulation portion 69 of the shaft bearing 61. Since the curved surface 57 of the coupling shaft 51 abuts against the first regulation portion 69, the contact area is small when the step portion 55 abuts against the first regulation portion 69. For this reason, even when the shaft bearing 61 rotates together with the distal treatment section 4 to the directions about the axis relative to the coupling shaft 51 while the step portion 55 is in contact with the first regulation portion 69, the friction between the step portion 55 and the first regulation portion 69 is small.

The treatment apparatus 1 having the above arrangement therefore has the following effects. The treatment apparatus 1 according to this embodiment is provided with the coupling shaft 51 serving as a wire distal member fixed to the grip operation wire 16. When the grip operation wire 16 is pulled or loosened, the coupling shaft 51 moves in the longitudinal directions. As the coupling shaft 51 moves in the longitudinal directions, the actuated state of the actuated member 71 changes between the first actuated state in which the grip portion 6 is actuated to the closed state and the second actuated state in which the grip portion 6 is actuated to the open state. Changing the actuated state of the actuated member 71 makes the grip portion 6 perform opening/closing movement to grip a tissue or the like. In this case, the coupling shaft 51 is coupled to the first coupling portion 62 of the shaft bearing 61 serving as a coupling member so as to be movable in the longitudinal directions relative to the shaft bearing 61. In addition, the actuated member 71 is coupled to the second coupling portion 72 of the shaft bearing 61 so as to be rotatable together with the distal treatment section 4 to the directions about the axis relative to the coupling shaft 51 and the flexible tube section 5. Since the actuated member 71 is rotatable together with the distal treatment section 4 relative to the coupling shaft 51, no torsion occurs in the grip operation wire 16 even when the distal treatment section 4 rotates relative to the flexible tube section 5. In the above manner, it is possible to provide the treatment apparatus 1 which exhibits high operability in the rotating operation of rotating the distal treatment section 4 without causing any torsion in the grip operation wire 16 serving as a grip operation transfer member.

The first coupling portion 62 of the shaft bearing 61 is provided with the first regulation portion 69 which is configured to regulate the amount of movement of the coupling shaft 51 in the proximal direction. The coupling shaft 51 includes the step portion 55 (first abutment portion) which is configured to prevent the movement of the coupling shaft 51 in the proximal direction by abutting against the first regulation portion 69. Providing the first regulation portion 69 and the step portion 55 can couple the coupling shaft 51 to the first coupling portion 62 so as to allow the coupling shaft 51 to move in the longitudinal directions relative to the shaft bearing 61. In addition, the second coupling portion 72 of the shaft bearing 61 is provided with the second regulation portion 79 which is configured to regulate the amount of movement of the actuated member 71 in the distal direction. The actuated member 71 includes the step portion 77 (second abutment portion) which is configured to prevent the movement of the actuated member 71 in the distal direction by abutting against the second regulation portion 79. Providing the second regulation portion 79 and the step portion 77 can couple the actuated member 71 to the second coupling portion 72 so as to allow the actuated member 71 to move in the longitudinal directions relative to the shaft bearing 61.

Modification of First Embodiment

A modification of the first embodiment will be described with reference to FIGS. 13 to 18. The same reference numerals as in the first embodiment denote the same parts and parts having the same functions, and a description of them will be omitted.

FIG. 13 is a view showing the configuration of the treatment apparatus 1 according to the first modification of the first embodiment. As shown in FIG. 13, the operation section 3 of the treatment apparatus 1 is provided with a grip operation section 81 which is configured to perform the grip operation of gripping a tissue or the like with the grip portion 6. The grip operation section 81 includes a fixed handle 85 fixed to the operation section main body 10, and a movable handle 87 which is pivotably supported on the fixed handle 85 through a connecting pin 86. The movable handle 87 can pivot about the connecting pin 86 relative to the fixed handle 85. A proximal end of the grip operation wire 16 is connected to the movable handle 87. Pivoting the movable handle 87 in a direction to close relative to the fixed handle 85 will pull the grip operation wire 16. Pivoting the movable handle 87 in a direction to open relative to the fixed handle 85 will loosen the grip operation wire 16.

As described above, as indicated by the first modification, the configuration of pulling or loosening the grip operation wire 16 is not limited to that in the embodiment described above. Likewise, the configuration of pulling or loosening the first and second rotating operation wires 21A and 21B is not limited to that in the embodiment described above.

FIG. 14 is a view showing the distal direction side part of the treatment apparatus 1 according to the second modification of the first embodiment. As shown in FIG. 14, the rotor support member 27 in this modification is not provided with the first and second convex portions 47A and 47B. Instead of these parts, the rotor support member 27 is provided with a first guide portion 82A and a second guide portion 82B. The first guide portion 82A includes a first insertion hole 83A. The second guide portion 82B includes a second insertion hole 83B.

As shown in FIG. 14, the first rotating operation wire 21A, extending from the wire fixing portion 40, extends on the outer surface of the rotor 26 along the first oblique direction inclining from the longitudinal directions to the first rotation direction. The first rotating operation wire 21A is then inserted into the first insertion hole 83A of the first guide portion 82A. Inserting the first rotating operation wire 21A into the first insertion hole 83A of the first guide portion 82A will change the extending direction of the first rotating operation wire 21A from the first oblique direction. The first rotating operation wire 21A, whose extending direction has been changed from the first oblique direction by the first guide portion 82A, is inserted from the first hole portion 46A into the flexible tube section 5. The first rotating operation wire 21A, which has been inserted into the flexible tube section 5, extends to the rotating operation section (rotating operation handle 12).

On the other hand, the second rotating operation wire 21B, extending from the wire fixing portion 40, extends on the outer surface of the rotor 26 along the second oblique direction inclining from the longitudinal directions to the second rotation direction. The second rotating operation wire 21B is then inserted into the second insertion hole 83B of the second guide portion 82B. Inserting the second rotating operation wire 21B into the second insertion hole 83B of the second guide portion 82B will change the extending direction of the second rotating operation wire 21B from the second oblique direction. The second rotating operation wire 21B, whose extending direction has been changed from the second oblique direction by the second guide portion 82B, is inserted from the second hole portion 46B into the flexible tube section 5. The second rotating operation wire 21B, which has been inserted into the flexible tube section 5, extends to the rotating operation section (rotating operation handle 12).

As described above, according to the second modification, the configuration of changing the extending direction of the first rotating operation wire 21A from the first oblique direction and the configuration of changing the extending direction of the second rotating operation wire 21B from the second oblique direction are not limited to those in the embodiment described above. That is, this apparatus may be provided with a direction changing portion which is configured to make the first rotating operation wire 21A extend to the rotating operation section by changing, from the first oblique direction, the extending direction of the first rotating operation wire 21A, which has extended from the wire fixing portion 40 onto the outer surface of the rotor 26 along the first oblique direction. Likewise, the apparatus may be provided with a direction changing portion which is configured to make the second rotating operation wire 21B extend to the rotating operation section by changing, from the second oblique direction, the extending direction of the second rotating operation wire 21B, which has extended from the wire fixing portion 40 onto the outer surface of the rotor 26 along the second oblique direction.

In addition, the first and second convex portions 47A and 47B may be provided to the distal direction side part of the flexible tube section 5. That is, the first and second convex portions 47A and 47B may be provided to the distal direction side part of the flexible tube section 5 or another member such as the rotor support member 27 provided between the flexible tube section 5 and the distal treatment section 4 while being fixed to the flexible tube section 5.

FIG. 15 is a view showing an configuration between the grip operation wire 16 and the grip portion 6 according to the third modification of the first embodiment. As shown in FIG. 15, in this modification, as in the first embodiment, the coupling shaft 51 as a wire distal member is provided in a state that the coupling shaft 51 is fixed to the grip operation wire 16. The coupling shaft 51 is coupled to the first coupling portion 62 of the shaft bearing 61 so as to be movable in the longitudinal directions relative to the shaft bearing 61. The actuated member 71, to be connected to the grip portion 6, is coupled to the second coupling portion 72 of the shaft bearing 61. The actuated member 71 can rotate together with the shaft bearing 61 to the directions about the axis relative to the coupling shaft 51. The first coupling portion 62 of the shaft bearing 61 is provided with the first regulation portion 69 which is configured to regulate the amount of movement of the coupling shaft 51 in the proximal direction. The coupling shaft 51 includes the step portion 55 which is configured to prevent the movement of the coupling shaft 51 in the proximal direction by abutting against the first regulation portion 69.

In this modification, instead of the step portion 55, the first regulation portion 69 of the shaft bearing 61 is provided with a curved surface 89, having an arcuated section taken parallel to the longitudinal directions axis C of the flexible tube section 5, which abuts against the step portion 55 of the coupling shaft 51. Since the step portion 55 abuts against the curved surface 89 of the first regulation portion 69, the contact area is small when the step portion 55 abuts against the first regulation portion 69. For this reason, even when the shaft bearing 61 rotates together with the distal treatment section 4 to the directions about the axis relative to the coupling shaft 51 in a state that the step portion 55 is in contact with the first regulation portion 69, the friction between the step portion 55 and the first regulation portion 69 is small.

As described above, according to the third modification, it is possible to use any configuration in which the contact area is small when the step portion 55 abuts against the first regulation portion 69. With such an configuration, even when the shaft bearing 61 rotates together with the distal treatment section 4 to the directions about the axis relative to the coupling shaft 51 while the step portion 55 is in contact with the first regulation portion 69, the friction between the step portion 55 and the first regulation portion 69 is small. Therefore, when the distal treatment section 4 rotates relative to the flexible tube section 5 while the step portion 55 is in contact with the first regulation portion 69, it is possible to prevent a deterioration in operability in rotating operation.

FIG. 16 is a view showing the configuration between the grip operation wire 16 and the grip portion 6 according to the fourth modification of the first embodiment. As shown in FIG. 16, in this modification, as in the first embodiment, the coupling shaft 51, which is a wire distal member, is provided so as to be fixed to the grip operation wire 16. In this modification, the inner surface of the rotor 26 is not provided with the shaft bearing 61. Instead of this part, the inner surface of the rotor support member 27 is provided with a shaft bearing 90. That is, the shaft bearing 90 is a fixing member provided so as to be fixed to the flexible tube section 5.

The coupling shaft 51 is fixed to a first coupling portion 91 of the shaft bearing 90 so as to be movable in the longitudinal directions relative to the shaft bearing 90. The first coupling portion 91 of the shaft bearing 90 is provided with a first regulation portion 92 which is configured to regulate the amount of movement of the coupling shaft 51 in the proximal direction. The coupling shaft 51 includes the step portion 55 which is configured to prevent the movement of the coupling shaft 51 in the proximal direction by abutting against the first regulation portion 92. In addition, the actuated member 71, to be connected to the grip portion 6, is coupled to a second coupling portion 95 of the shaft bearing 90. The actuated member 71 is coupled to the second coupling portion 95 of the shaft bearing 61 so as to be rotatable to the directions about the axis relative to the shaft bearing 90. The second coupling portion 95 of the shaft bearing 90 is provided with a second regulation portion 96 which is configured to regulate the amount of movement of the actuated member 71 in the distal direction. The actuated member 71 includes the step portion 77 which is configured to prevent the movement of the actuated member 71 in the distal direction by abutting against the second regulation portion 96.

In this modification, the step portion (second abutment portion) 77 of the actuated member 71 is provided with a curved surface 97, having an arcuated section taken parallel to the longitudinal directions axis C of the flexible tube section 5, which abuts against the second regulation portion 96 of the shaft bearing 90. Since the curved surface 97 of the step portion 77 abuts against the second regulation portion 96, the contact area is small when the step portion 77 abuts against the second regulation portion 96. For this reason, even when the actuated member 71 rotates together with the distal treatment section 4 to the directions about the axis relative to the shaft bearing 90 and the coupling shaft 51 while the step portion 77 is in contact with the second regulation portion 96, the friction between the step portion 77 and the second regulation portion 96 is small.

FIG. 17 is a view showing the configuration between the grip operation wire 16 and the grip portion 6 according to the fifth modification of the first embodiment. As shown in FIG. 17, in this modification, as in the fourth modification of the first embodiment, the coupling shaft 51, which is a wire distal member, is provided in a state that the coupling shaft 51 is fixed to the grip operation wire 16. The coupling shaft 51 is coupled to the first coupling portion 91 of the shaft bearing 90 so as to be movable in the longitudinal directions relative to the shaft bearing 90. In addition, the actuated member 71, to be connected to the grip portion 6, is coupled to the second coupling portion 95 of the shaft bearing 90. The actuated member 71 is rotatable to the directions about the axis relative to the shaft bearing 90 and the coupling shaft 51. The second coupling portion 95 of the shaft bearing 90 is provided with the second regulation portion 96 which is configured to regulate the amount of movement of the actuated member 71 in the distal direction. The actuated member 71 includes the step portion 77 which is configured prevent the movement of the actuated member 71 in the distal direction by abutting against the second regulation portion 96.

In this modification, instead of the step portion 77, the second regulation portion 96 of the shaft bearing 90 is provided with a curved surface 99, having an arcuated section taken parallel to the longitudinal directions axis C of the flexible tube section 5, which abuts against the step portion 77 of the actuated member 71. Since the step portion 77 abuts against the curved surface 99 of the second regulation portion 96, the contact area is small when the step portion 77 abuts against the second regulation portion 96. For this reason, even when the actuated member 71 rotates together with the distal treatment section 4 to the directions about the axis relative to the coupling shaft 51 and the shaft bearing 90 while the step portion 77 is in contact with the second regulation portion 96, the friction between the step portion 77 and the second regulation portion 96 is small.

As described above, according to the fourth and fifth modifications, this apparatus may be provided with the shaft bearing 90, which is a fixing member, to which the actuated member 71 is coupled at the second coupling portion 95 so as to be rotatable to the directions about the axis, instead of the shaft bearing 61, which is a rotating member, which is coupled to the coupling shaft 51 at the first coupling portion 62 so as to be rotatable together with the actuated member 71 to the directions about the axis relative to the coupling shaft 51. In this case, the shaft bearing 90 is provided in a state that the shaft bearing 90 is fixed to the flexible tube section 5. In this case, it is possible to use any configuration in which the contact area is small when the step portion 77 abuts against the second regulation portion 96. With such an configuration, even when the actuated member 71 rotates together with the distal treatment section 4 to the directions about the axis relative to the coupling shaft 51 and the shaft bearing 90 while the step portion 77 is in contact with the second regulation portion 96, the friction between the step portion 77 and the second regulation portion 96 is small. Therefore, when the distal treatment section 4 rotates relative to the flexible tube section 5 while the step portion 77 is in contact with the second regulation portion 96, it is possible to prevent a deterioration in operability in rotating operation.

FIG. 18 is a view showing the configuration of the distal direction side part of the treatment apparatus 1 according to the sixth modification of the first embodiment. As shown in FIG. 18, the first clamping portion 35A of the grip portion 6 is provided in a state that the first clamping portion 35A is fixed to the treatment section main body 25. In addition, the second clamping portion 35B of the grip portion 6 is pivotably supported on the treatment section main body 25 through the coupling pin 36. The second clamping portion 35B can rotate together with the treatment section main body 25 to the directions about the axis relative to the flexible tube section 5. The second clamping portion 35B can pivot about the coupling pin 36 relative to the treatment section main body 25. When the second clamping portion 35B pivots relative to the treatment section main body 25, the second clamping portion 35B performs opening/closing movement relative to the first clamping portion 35A of the treatment section main body 25.

The actuated member 71 is connected to the second clamping portion 35B. When the grip operation wire 16 is pulled or loosened with the grip operation handle 11, the actuated member 71 moves in the longitudinal directions in accordance with pulling or loosening of the grip operation wire 16, as described above. As the actuated member 71 moves, the second clamping portion 35B pivots about the coupling pin 36 relative to the treatment section main body 25. As the actuated member 71 moves in the distal direction, the second clamping portion 35B pivots in a direction to open relative to the first clamping portion 35A. On the other hand, when the actuated member 71 moves in the proximal direction, the second clamping portion 35B pivots in a direction to close relative to the first clamping portion 35A.

As described above, according to the sixth modification, the configuration of the grip portion 6 is not limited to that in the above embodiment. That is, the distal treatment section 4 may include the grip portion 6 which is configured to perform opening/closing movement between the closed state and the open state.

Second Embodiment

The second embodiment of the present invention will be described next with reference to FIG. 19. The same reference numerals as in the first embodiment denote the same parts and parts having the same functions, and a description of them will be omitted.

FIG. 19 is a view showing the configuration of the distal direction side part of the treatment apparatus 1 according to the second embodiment. As shown in FIG. 19, in this embodiment, an outer surface of a first rotating operation wire 21A is provided with a first stopper member 101A in a fixed state. When the first rotating operation wire 21A is pulled or loosened by rotating a rotating operation handle 12, the first stopper member 101A moves in the longitudinal directions. Likewise, an outer surface of a second rotating operation wire 21B is provided with a second stopper member 101B in a fixed state. When the second rotating operation wire 21B is pulled or loosened by rotating a rotating operation handle 12, the second stopper member 101B moves in the longitudinal directions.

A rotor support member 27 is provided with a first bearing portion 102A which is configured to prevent the movement of the first stopper member 101A in the distal direction by making the first stopper member 101A abut against the first bearing portion 102A. Likewise, the rotor support member 27 is provided with a second bearing portion 102B which is configured to prevent the movement of the second bearing portion 102B in the distal direction by making the second stopper member 101B abut against the second bearing portion 102B.

While the distal treatment section 4 and a rotor 26 are in a neutral state, in which they are not rotating to the directions about the axis relative to a flexible tube section 5, the first stopper member 101A is spaced apart from the first bearing portion 102A by a predetermined distance L0 in the proximal direction. When the first stopper member 101A moves from the neutral state by the distance L0 in the distal direction, the first stopper member 101A abuts against the first bearing portion 102A. This prevents the movement of the first stopper member 101A in the distal direction. This regulates an amount of loosening of the first rotating operation wire 21A. Regulating the amount of loosening of the first rotating operation wire 21A will regulate an amount of pulling of the second rotating operation wire 21B. That is, the first stopper member 101A and the first bearing portion 102A constitute a first regulation portion 100A which is configured to regulate the amount of pulling of the second rotating operation wire 21B.

In the neutral state, the second stopper member 101B is spaced apart from the second bearing portion 102B by a predetermined distance L0 in the proximal direction. When the second stopper member 101B moves from the neutral state by the distance L0 in the distal direction, it abuts against the second bearing portion 102B. This prevents the movement of the second stopper member 101B in the distal direction. This regulates an amount of loosening of the second rotating operation wire 21B. Regulating the amount of loosening of the second rotating operation wire 21B will regulate an amount of pulling of the first rotating operation wire 21A. That is, the second stopper member 101B and the second bearing portion 102B constitute a second regulation member 100B which is configured to regulate the amount of pulling of the first rotating operation wire 21A.

The treatment apparatus 1 having the above arrangement therefore has the following effects in addition to the same effects as those of the first embodiment. That is, in the treatment apparatus 1 according to this embodiment, the first stopper member 101A and the first bearing portion 102A are configured to regulate the amount of pulling of the second rotating operation wire 21B. Likewise, the second stopper member 101B and the second bearing portion 102B are configured to regulate the amount of pulling of the first rotating operation wire 21A. Regulating the amount of pulling of the first and second rotating operation wires 21A and 21B will regulate the amount of rotation of a distal treatment section 4 and the rotor 26. This prevents excessive rotation of the distal treatment section 4, and hence can prevent the wire from being cut at a wire fixing portion 40.

Note that in the above embodiment, the first bearing portion 102A and the second bearing portion 102B are provided on the rotor support member 27. However, the embodiment is not limited to this. That is, the first bearing portion 102A and the second bearing portion 102B may be provided to the distal direction side of the flexible tube section 5 in a fixed state relative to the flexible tube section 5. It is therefore not preferable to provide the first bearing portion 102A and the second bearing portion 102B in the flexible tube section 5. If the first bearing portion 102A and the second bearing portion 102B are provided in the flexible tube section 5, a change in the shape of the flexible tube section 5 greatly influences the regulation of the amount of pulling of the first and second rotating operation wires 21A and 21B. It is also not preferable to provide the first and second bearing portions 102A and 102B to the rotor 26. Since the first and second rotating operation wires 21A and 21B extend on the outer surface of the rotor 26, the first and second bearing portions 102A and 102B are formed so as to protrude on the outer surface of the rotor 26 in the outer direction. This increases a diameter of the rotor 26.

Third Embodiment

The third embodiment of the present invention will be described next with reference to FIGS. 20 to 22. The same reference numerals as in the first embodiment denote the same parts and parts having the same functions, and a description of them will be omitted.

FIG. 20 is a view showing the configuration of the distal direction side part of the treatment apparatus 1 according to the third embodiment. As shown in FIG. 20, in this embodiment, as in the first embodiment, inside a flexible tube section 5, a first rotating operation wire 21A extends through a coil pipe (first coil pipe) 23A used in rotating operation. A second rotating operation wire 21B extends through a coil pipe (second coil pipe) 23B used in rotating operation. The embodiment is also provided with a first grip operation wire 16A and a second grip operation wire 16B. The first and second grip operation wires 16A and 16B are pulled or loosened together by operation with a grip operation handle 11. Pulling or loosening the first and second grip operation wires 16A and 16B will move a coupling shaft 51 as a wire distal member in the longitudinal directions.

FIG. 21 is a sectional view taken along a line 21-21 in FIG. 20. As shown in FIG. 21, inside the flexible tube section 5, the first rotating operation wire 21A is spaced apart from the second rotating operation wire 21B by almost 180° in the directions about the axis. The first grip operation wire 16A extends spaced apart (by almost 90° in the directions about the axis in this embodiment) from the coil pipe 23A and the coil pipe 23B in the directions about axis. In addition, the second grip operation wire 16B extends space apart by almost 180° from the first grip operation wire 16A in the directions about the axis. In addition, the flexible tube section 5 is internally provided with a coil pipe (third coil pipe) 105 through which the first grip operation wire 16A, the second grip operation wire 16B, the coil pipe 23A, and the coil pipe 23B extend. In the first embodiment, the inner diameter of the flexible tube section 5 needs to be larger than the sum of the outer diameter of the coil pipe 17 and the outer diameters of the coil pipes 23A and 23B. In contrast to this, in the third embodiment, the inner diameter of the flexible tube section 5 may be larger than the sum of the outer diameters of the coil pipes 23A and 23B and a wall thickness of the coil pipe 105.

FIG. 22 is a view showing an example of the interior of the flexible tube section 5 while the shape of the flexible tube section 5 has changed. In the state shown in FIG. 22, with a change in the shape of the flexible tube section 5, the coil pipes 23A and 23B and the first and second grip operation wires 16A and 16B have moved. The coil pipes 23A and 23B are inscribed in the coil pipe 105, and the coil pipes 23A and 23B are circumscribed to each other. In this state, assume that a circle R1 is a reference circle, which is one of two circles R1 and R2 circumscribed around the coil pipes 23A and 23B and inscribed in the coil pipe 105, and which has a smaller diameter in the two circles R1 and R2. The diameter of the first grip operation wire 16A is smaller than that of the reference circle R1. Likewise, the diameter of the second grip operation wire 16B is smaller than that of the reference circle R1. With this configuration, the contact areas between the first grip operation wire 16A and the coil pipes 23A, 23B, and 105 decrease regardless of how the coil pipes 23A and 23B and the first and second grip operation wires 16A and 16B move. With regard to the second grip operation wire 16B as well, the contact portions with the coil pipes 23A and 23B and 105 decrease.

The treatment apparatus 1 having the above configuration has the following effects in addition to the same effects as those of the first embodiment. That is, in the treatment apparatus 1 according to this embodiment, the inner diameter of the flexible tube section 5 may be larger than the sum of the outer diameters of the coil pipes 23A and 23B and the wall thickness of the coil pipe 105. For this reason, it is possible to decrease the diameter of the flexible tube section 5 as compared with the first embodiment (the inner diameter of the flexible tube section 5 needs to be larger than the sum of the outer diameters of the coil pipe 17 and coil pipes 23A and 23B).

In the treatment apparatus 1, the diameter of the first grip operation wire 16A is smaller than that of the reference circle R1. Likewise, the diameter of the second grip operation wire 16B is smaller than the diameter of the reference circle R1. This reduces the contact portions between the first grip operation wire 16A and the coils 23A, 23B, and 105 regardless of how the coil pipes 23A and 23B and the first and second grip operation wires 16A and 16B move. Likewise, this also reduces the contact portions between the second grip operation wire 16B and the coil pipes 23A and 23B and 105. This makes it possible to ensure the sliding property of the first and second grip operation wires 16A and 16B when they are pulled or loosened.

The following are technical items as other characteristic features of the present invention.

Note
(Appendant Claim 1)

A treatment apparatus comprising:

a flexible tube section which extends in longitudinal directions, and which has a longitudinal directions axis;

a distal treatment section which includes a grip portion configured to perform opening/closing movement between an open state and a closed state, and which is provided to a distal direction side of the flexible tube section so as to be rotatable to the directions about an axis relative to the flexible tube section;

a grip operation section which is provided to a proximal direction side of the flexible tube section, and which is configured to perform grip operation of the grip portion;

a grip operation wire which extends from the grip operation section into the flexible tube section and, which is configured to be pulled or loosened by the grip operation with the grip operation section;

a wire distal member which is provided to the distal direction side of the grip operation wire to be fixed to the grip operation wire, and which is configured to be moved in the longitudinal directions by pulling or loosening the grip operation wire;

an actuated member which is provided to the distal direction side of the wire distal member so as to be connected to the grip portion, and whose actuated state is configured to change, in accordance with movement of the wire distal member in the longitudinal directions, between a first actuated state in which the grip portion is actuated to the closed state and a second actuated state in which the grip portion is actuated to the open state; and

a coupling member including a first coupling portion to which the wire distal member is coupled to so as to move in the longitudinal directions, and a second coupling portion to which the actuated member is coupled so as to rotate together with the distal treatment section to the directions about the axis relative to the wire distal member and the flexible tube section.

(Appendant Claim 2)

The treatment apparatus of appendant claim 1, further comprising:

a rotor which is provided between the distal treatment section and the flexible tube section so as to rotate together with the distal treatment section to the directions about the axis relative to the flexible tube section;

a rotating operation section which is provided to the proximal direction side of the flexible tube section, and which is configured to perform rotating operation of the distal treatment section;

a first rotating operation wire which has a distal end fixed to the rotor or to a portion to the distal direction side of the rotor, and which extends into the flexible tube section to the rotating operation section through an outer surface of the rotor, the first rotating operation wire being configured to be pulled by the rotating operation with the rotating operation section to rotate the distal treatment section in a first rotation direction;

a second rotating operation wire which has a distal end fixed to the rotor or to a portion to the distal direction side of the rotor, and which extends into the flexible tube section to the rotating operation section through the outer surface of the rotor so as to be spaced apart by substantially 180° from the first rotating operation wire in the directions about the axis, the second rotating operation wire being configured to be pulled by the rotating operation with the rotating operation section to rotate the distal treatment section in a second rotation direction opposite to the first rotation direction;

a first coil pipe which is provided in the flexible tube section, and through which the first rotating operation wire extends;

a second coil pipe which is provided in the flexible tube section, and through which the second rotating operation wire extends; and

a third coil pipe which is provided in the flexible tube section, and through which the grip operation wire, the first coil pipe, and the second coil pipe extend,

wherein the grip operation wire includes

a first grip operation wire which extends in the third coil pipe to be spaced apart from the first coil pipe and the second coil pipe in the directions about the axis, and

a second grip operation wire which extends in the third coil pipe to be spaced apart from the first grip operation wire by substantially 180° in the directions about the axis.

(Appendant Claim 3)

The treatment apparatus of appendant claim 2, wherein

the first grip operation wire having a diameter smaller than that of a reference circle, which is one of two circles circumscribed around the first coil pipe and the second coil pipe and inscribed in the third coil pipe in a state that the first coil pipe and the second coil pipe are inscribed in the third coil pipe and the first coil pipe and the second coil pipe are circumscribed to each other, and which has a smaller diameter in the two circles, and

the second grip operation wire has a diameter smaller than that of the reference circle.

Additional advantages and modifications will readily occur to those skilled in the art. Therefore, the invention in its broader aspects is not limited to the specific details and representative embodiments shown and described herein. Accordingly, various modifications may be made without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents.

	Number	Date	Country
Parent	PCT/JP2011/073420	Oct 2011	US
Child	13483725		US

TREATMENT APPARATUS

Information

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CPC

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Abstract

Description

Claims

Priority Claims (1)

CROSS-REFERENCE TO RELATED APPLICATIONS

Continuations (1)