BACKGROUND OF THE INVENTION 1. Field of the Invention
The present invention relates to an instrument used together with an endoscope in a surgical operation using the endoscope.
2. Description of the Related Art
In a surgical operation using an endoscope, treatment tools such as forceps are used. An example of the treatment tool is disclosed in U.S. Pat. No. 6,245,085. In an operation using such a treatment tool, a hole (called a “port”) having a diameter of 5 to 10 mm is provided in a body wall, and the treatment tool is inserted through the hole. In this case, the area where treatment is possible is narrower in comparison with an open operation in which a portion of a body wall is cut and opened. Therefore, when an area to be treated is large or the position of the hole is inappropriate with respect to the part to be treated, the operation of the treatment tool may be difficult, or the treatment may be complicated. In such a case, if another hole is provided at another position, the damaged area in the patient's body is increased in size.
PCT International Publication, No. WO98/48687 discloses a treatment tool for solving the above problems. In the disclosed treatment tool, a treatment section and an operation section are not coaxially arranged. When using such a treatment tool, it is difficult for the operator to intuitively know the position to be treated. Additionally, a possible amount of offset between the treatment section and an inserted portion is restricted depending on the outer diameter of the hole provided in a body wall. In order to secure a sufficiently wide area which can be treated, the diameter of the hole must be large. Therefore, it is difficult to perform wide area treatment with low damage.
SUMMARY OF THE INVENTION An instrument for an endoscope according to the present invention includes:
a first insertion portion having an base end portion to which an operation section is connected;
an first offset portion extending outward from an axis of the first insertion portion;
a second insertion portion having a base end portion joined to the first offset portion and an element extending parallel to the axis of the first insertion portion;
a second offset portion which is joined to a head portion of the second insertion portion and reaches an extension of the axis of the first insertion portion;
a third insertion portion which is joined to the second offset portion and has a portion arranged on an axis which is substantially the same as at least a part of the axis of the first insertion portion; and
an inner hole formed through the first insertion portion, the first offset portion, the second insertion portion, the second offset portion, and the third insertion portion.
BRIEF DESCRIPTION OF THE DRAWINGSFIG. 1 is a diagram showing the structure of a surgical treatment tool as an embodiment of the instrument for the endoscope.
FIG. 2 is a sectional view showing the structure of an operation section.
FIG. 3 is a sectional view showing the structure of a treatment section.
FIG. 4 is a diagram showing a head portion of an insertion section and divisions of a scale provided in the treatment section.
FIG. 5 is a diagram showing a state in which the head side of the insertion section is linearly arranged.
FIG. 6 is a diagram explaining a method of using the surgical treatment tool.
FIG. 7 is a diagram explaining a method of using the surgical treatment tool.
FIG. 8 is a diagram explaining a method of using a conventional surgical treatment tool.
FIG. 9 is a diagram showing a variation of the insertion section.
FIG. 10 is a diagram showing the structure of a surgical treatment tool as the instrument for the endoscope.
FIG. 11 is a sectional view showing the structure of an operation section.
FIG. 12 is a sectional view showing the structure of a treatment section.
FIG. 13 is a diagram showing a method of using the surgical treatment tool and a state in which the tool is inserted in a living body.
FIG. 14 is a diagram showing a method of using the surgical treatment tool and explaining an operation for changing the position of the treatment section.
FIG. 15 is a diagram explaining a method of using a conventional surgical treatment tool.
FIG. 16 is a diagram showing the structure of a surgical treatment tool as the instrument for the endoscope, and a state in which a portion of the insertion section is inserted in a living body.
FIG. 17 is a diagram showing an example of the structure of a head portion and a base end portion of an insertion section.
FIG. 18 is a sectional view showing the structure of a surgical treatment tool as the instrument for the endoscope.
FIG. 19 is a sectional view showing a structure in which a tube is used instead of a wire.
FIG. 20 is a sectional view showing a part of a structure in which an ultrasonic motor is used instead of a wire.
FIG. 21 is a sectional view showing a part of a structure in which a rack and pinion mechanism and a pulley mechanism are used instead of a wire.
FIG. 22 is a diagram showing the structure of an observation instrument as the instrument for the endoscope.
FIG. 23 is a diagram showing a method of using the observation instrument.
FIG. 24 is a diagram showing a method of using the observation instrument.
PREFERRED EMBODIMENTS OF THE INVENTIONFirst EmbodimentFIG. 1 shows a surgical treatment tool as a first embodiment of the instrument for the endoscope.
Asurgical treatment tool1 has anoperation section2 operated by an operator, aninsertion section3 which extends from theoperation section2, and atreatment section4 provided at the head of theinsertion section3 so as to perform treatment on a living body.
Theinsertion section3 has anouter pipe5 formed by bending a metal pipe member having an outer diameter of 3 to 15 mm. Theouter pipe5 has afirst insertion portion10 connected to theoperation section2. Thefirst insertion portion10 extends along the axis of theoperation section2. Ahead portion10a(a far end portion) of thefirst insertion portion10 forms afirst bent portion5awhich is substantially perpendicularly bent. From thefirst bent portion5a, afirst offset portion11 extends in a direction perpendicular to the axis of thefirst insertion portion10. Ahead portion11a(a far end portion) of thefirst offset portion11 forms asecond bent portion5bwhich is substantially perpendicularly bent. From thesecond bent portion5b, asecond insertion portion12 extends parallel to the axis of thefirst insertion portion10.
Pins13aand13bpass through ahead portion12aof the second insertion portion12 (i.e., a head portion of the outer pipe5) in a direction perpendicular to the longitudinal axis of thesecond insertion portion12. Thepins13aand13bare also perpendicular to the first offsetportion11. To thehead portion12aof thesecond insertion portion12, abase portion14a(a near end portion) of a second offsetportion14 made of a metal pipe member having an outer diameter of 3 to 15 mm is attached via thepins13aand13bin a freely rotatable form.Pins15aand15bpass through ahead portion14b(a far end portion) of the second offsetportion14, in a direction perpendicular to the longitudinal axis of the second offsetportion14. Thepins15aand15bare arranged parallel to thepins13aand13b. To thehead portion14bof the second offsetportion14, abase portion16a(a near end portion) of athird insertion portion16 made of a metal pipe member having an outer diameter of 3 to 15 mm is attached via thepins15aand15bin a freely rotatable form.
The length of the second offsetportion14 is substantially the same as the length of the first offsetportion11. Thehead portion12aof thesecond insertion portion12 contacts thebase portion14aof the second offsetportion14 in a manner such that the longitudinal axes of thesecond insertion portion12 and the second offsetportion14 are at 90 degrees. In this arrangement, the second offsetportion14 is parallel to the first offsetportion11. The second offsetportion14 contacts thethird insertion portion16 in a manner such that the longitudinal axes of the two portions are at degrees. In this arrangement, thethird insertion portion16 is parallel to thefirst insertion portion10 and thesecond insertion portion12. In addition, thethird insertion portion16 and thefirst insertion portion10 are coaxial.
The length of thesecond insertion portion12 of theouter pipe5 is sufficiently longer than the length of a trocar (as a passage for connecting the inside and the outside of a coelom) which is provided at a coelom. In a state in which thesurgical treatment tool1 is inserted into the trocar, the insertion section can be advanced or withdrawn in the length direction of the trocar. Instead of the trocar, an assistant sleeve may be used as the passage for connecting the inside and the outside of the coelom.
Aring20 is attached to the outer periphery of thesecond insertion portion12 where the ring can slide in the longitudinal axial direction of theinsertion portion12. In the outer periphery of thering20, a threaded hole (not shown) is provided. Thering20 can be fixed to a desired position of theouter pipe5 by screwing afastening screw21 into the threaded hole. To thering20, an end of anangle wire22 is fastened. Theangle wire22 passes through (i) awire guide23aprovided at a side of thehead portion12aof thesecond insertion portion12 toward the second offsetportion14, (ii) awire guide23bprovided at a side of thebase portion14aof the second offsetportion14 opposite a side toward the first offsetportion11, and (iii) awire guide23cprovided at thehead portion14bof the second offsetportion14 and at a position facing thethird insertion portion16, in turn, and is then fastened to a side of a base portion of thethird insertion portion16, which faces the second offsetportion14.
As shown inFIGS. 2 and 3, in theinsertion section3, a working channel30 (an inner hole) is formed from the inside of theouter pipe5 to the inside of thethird insertion portion16. In thechannel30, a coil31 (i.e., a driving force transmitting device) is inserted in a freely rotatable form. Thecoil31 is flexible and made of metal which can transmit torque. Inside thecoil31, a metal wire32 (i.e., a driving force transmitting device) is inserted in a manner such that thewire32 can freely advance or withdraw with respect to thecoil31.
A base end side of thecoil31 is inserted into amain body35 of theoperation section2. As shown inFIGS. 1 and 2, themain body35 has a cylindrical form, andcircular grooves35aand35bare respectively formed at head and base sides of the inner periphery of themain body35.Rings36 and37 are respectively inserted into thegrooves35aand35b. To the inner periphery of thering36, an outer peripheral face of a base portion of thecoil31 is fastened by a method such as brazing, welding, or adhesion. At the base end of themain body35, acap member38 is attached in a manner such that thecap member38 pushes thering36. Because of thecap member38, movement of thering36 in the axial direction is prevented, and a specific weight is applied to rotation of thering36 with respect to themain body35. To the inner periphery of thering37 at the head side, an outer peripheral face of thebase portion10a(the far end portion) of thefirst insertion portion10 is fastened by a method such as brazing, welding, or adhesion. At the head end of themain body35, acap member39 is attached in a manner such that thecap member39 pushes thering37. Because of thecap member39, movement of thering37 in the axial direction is prevented, and a specific weight is applied to rotation of thering37 with respect to themain body35.
A fixedhandle member40 extends directly outward from themain body35. Ahole40afor a finger is provided at the other end of the fixedhandle member40. In the vicinity of a base (i.e., an end) of the fixedhandle member40, a center portion of amovable handle member42 is attached via apin41 in a freely rotatable form. Ahole42afor a finger is provided at the other end of themovable handle member42. Anend portion42bof themovable handle member42 extends over the axis of themain body35, and a specific distance is secured between theend portion42band thecap member38. Agroove43 is formed in theend portion42b. Thegroove43 has anopen end43atoward thecap member38 and extends from the end face of theend portion42balong the length of themovable handle member42. The width of theopen end43ain a direction perpendicular to the length direction of thegroove43 is less than the width of the remaining portion of thegroove43. In thegroove43, afitting member44 is inserted through theopen end43a. A base end of thewire32 is fastened to thefitting member44 by a method such as brazing, welding, or adhesion. In thefitting member44, aspherical portion44ais provided which enters thegroove43. The diameter of thespherical portion44ais larger than the narrowed width of thegroove43. Thefitting member44 can freely slide along thegroove43. Owing to the fitspherical portion44a, thefitting member44 cannot be detached in a direction along the axis of the fitting member44 (i.e., in the axial direction).
As shown inFIG. 3, ahousing member50 is attached to the head side of thecoil31 by a method such as brazing, welding, or adhesion. A throughhole50ais formed at the center of thehousing member50. Thehousing member50 is inserted from the head side of thethird insertion portion16 and is fit to an inner peripheral face of thethird insertion portion16 in a freely rotatable form. In addition, anend face51aof aflange portion51 of thehousing member50 contacts an end face of thehead portion16b(the far end portion) of thethird insertion portion16. From the head portion of thehousing member50, a pair ofsupports52 extend in a manner such that thesupports52 are arranged parallel to each other along their axes and thus face each other, and a specific gap is provided between thesupports52. Apin53 passes through thesupports52 in a direction perpendicular to their axes. Thepin53 passes through a pair of clippingmembers55aand55bwhich are overlapped in a direction along the axis of thepin53. The clippingmembers55aand55bare each supported via thepin53 by thehousing member50 in a freely rotatable form, and head sides of theclipping members55aand55bfrom the center portion where thepin53 is provided can clip a portion of a living body. To base end sides of theclipping members55aand55bfrom the position of thepin53, base end portions of thelink members57aand57bare respectively coupled viapins56aand56bin a freely rotatable form. A head portion of a wirejoint member58 is held between base end portions of thelink members57aand57b, which are coupled to the wirejoint member58 via a pin59 in a freely rotatable form. The wirejoint member58 is fastened to an end of thewire32 by a method such as brazing. As shown inFIG. 4,divisions60 of a scale are provided on the surfaces of the pair of theclipping members55aand55b, thehousing member50, and thethird insertion portion16.
The operation of the present embodiment will be explained below.
First, thesurgical treatment tool1 is inserted into a trocar provided through a body wall of a patient. In the insertion process, thesecond insertion portion12 of theouter pipe5, the second offsetportion14, and thethird insertion portion16 are substantially linearly arranged, and thethird insertion portion16, the second offsetportion14, and thesecond insertion portion12 are inserted in turn from the trocar.
In treatment, thering20 is slid toward abase end portion12b(a far end portion corresponding to the secondbent portion5b) of thesecond insertion portion12. Theangle wire22 fastened to thering20 then pulls a head ring9 and the second offsetportion14 in turn. Thethird insertion portion16 rotates around thepins15aand15buntil thethird insertion portion16 contacts the head portion of the second offsetportion14 and thethird insertion portion16 and the second offsetportion14 are at degrees. The second offsetportion14 rotates around thepins13aand13buntil the second offsetportion14 contacts thehead portion12aof thesecond insertion portion12 and the second offsetportion14 and thesecond insertion portion12 form a 90 degree angle. When thefastening screw21 is screwed and fastened, thering20 is fastened to thesecond insertion portion12, and thethird insertion portion16 is fastened to the second offsetportion14, and the second offsetportion14 is fastened to thesecond insertion portion12.
As shown inFIG. 6, thetreatment section4 is inserted toward a treatment target part W3 through a trocar W2 provided at a body wall W1. In this state, the head portion of thesurgical treatment tool1 can be positioned at a desired position by appropriately moving thesurgical treatment tool1 in a direction A1 for angling thesurgical treatment tool1 with respect to the longitudinal axial direction of the trocar W2 or a direction A2 for advancing or withdrawing thesurgical treatment tool1 in a direction along the axis of the trocar W2. In addition, as shown inFIGS. 6 and 7, when the head portion from the firstbent portion5aof theouter pipe5 inserted in the trocar W2 is rotated around the longitudinal axial direction of the trocar W2, the head portion of thesurgical treatment tool1 can be arranged at various positions, so that the head portion can be positioned in a wider area.
When the fixedhandle member40 and themovable handle member42 are grasped and brought close to each other, theend portion42bof themovable handle member42 leaves themain body35, and thefitting member44, fit to thegroove43 of theend portion42, is pulled toward the base end side in the axial direction. Accordingly, thewire32 is also pulled toward the base end side, and the wirejoint member58 attached to the head end of thewire32 pulls thelink members57aand57b. Then the pair of clippingmembers55aand55bcoupled to thelink members57aand57brotate around thepin53, and the head portions of theclipping members55aand55bapproach each other and close. When theoperation section3 is operated so as to open the fixedhandle member40 and themovable handle member42, theend portion43 moves toward thecap member38. Accordingly, thewire32 is pushed via thefitting member44, and the head portions of theclipping members55aand55bare separated and opened.
When the fixedhandle member40 is grasped and themain body35 is rotated with respect to theouter pipe5 around the axis of thefirst insertion portion10, thering36, having a specific frictional force for themain body35, rotates together with themain body35. Thecoil31 is fastened to thering36, and thehousing50 is fastened to the head portion of thecoil31. Therefore, rotation of thering36 is transmitted by thecoil31 to thehousing50 at the head side, and the pair of theclipping members55aand55bsupported by thehousing50 rotates around the axis of thethird insertion portion16. Accordingly, in response to the rotation of themain body35 around the axis of the fixedhandle member40, the pair of theclipping members55aand55brotate around the axis. In addition, when thering36 is rotated with respect to themain body35 against the specific friction force, for example, by applying a finger to a side face of thering36 exposed through awindow35aof the main body35 (seeFIG. 1), the rotation of thering36 is transmitted via thecoil31 to thehead treatment section4. Accordingly, the pair of theclipping members55aand55bcan be rotated around the axis without changing the position of the fixedhandle member40.
In the conventional technique, the area where treatment can be performed through a single trocar W2 is as shown inFIG. 8. In contrast, is the present embodiment, the area where treatment can be performed through a single trocar W2 is wider as shown inFIGS. 6 and 7. Therefore, a smaller number of trocars W2 is necessary in a surgical operation. A time period necessary for inserting trocars W2 in the body wall W1 and a time period necessary for pulling out the treatment tool from a trocar W2 and inserting the tool through another trocar W2 can be reduced, thereby reducing a time necessary for each surgical operation and also reducing damage to the patient.
In addition, thetreatment section4 and theoperation section2 are coaxially arranged; thus, it is easy for the operator to intuitively know the position of thetreatment section4, and the operator can easily operate the treatment tool. Accordingly, quick and reliable treatment can be performed.
Furthermore,divisions60 of a scale are provided in a head portion of the tool; thus, it is easy for the operator to visually determine the depth. In particular, in an endoscope operation performed with watching two-dimensional images, a safer and more reliable operation is possible.
FIG. 9 shows a variation. A shownsurgical treatment tool61 has abent pipe62 having a specific curvature, which can be inserted into a trocar. Thebent pipe62 has afirst insertion portion71 whose base end portion is connected to theoperation section2. The axis of thefirst insertion portion71 is aligned to the axis B1 of theoperation section2. From a head portion of thefirst insertion portion71, a first offsetportion72 extends, where theportions71 and72 form a single body. The first offsetportion72 is bent so as to leave the axis B1. A portion furthest from the axis B1 functions as asecond insertion portion73 joined to the first offsetportion72. Thesecond insertion portion73 is bent while generally extending in a direction substantially parallel to the axis B1. That is, thesecond insertion portion73 has an element parallel to the axis B1. At the head of thesecond insertion portion73, a second offsetportion74 is provided, which is bent toward the axis B1 and has a substantially symmetrical form with respect to the first offsetportion72. At the head of the second offsetportion74, athird insertion portion75 is provided, which extends substantially coaxially to the axis B1 so as to further leave theoperation section2. Thetreatment section4 is attached to thethird insertion portion75. Inside thebent pipe62, thecoil31 and thewire32 pass through in a freely rotatable form. In accordance with thesurgical treatment tool61, functions and effects similar to those described above can be obtained.
Second EmbodimentFIG. 10 shows a surgical treatment tool as a second embodiment of the instrument for the endoscope.
In asurgical treatment tool101, aninsertion section103 extends from anoperation section101, and atreatment section104 is provided at the head of theinsertion section103.
As shown inFIGS. 10 and 11, theoperation section102 has a fixedhandle member105 and amovable handle member106 which can slide along the fixed handle member105 (in the longitudinal axial direction). The fixedhandle member105 has aring105ato be caught by a finger, at the base side of the fixedhandle member105. In an intermediate portion of the fixedhandle member105, arail portion105bis provided, which has a long hole formed along the length of therail portion105b. Themovable handle member106 slides along therail portion105b. As shown inFIG. 11, on a head side of the fixedhandle member105, aU-shaped groove108 is provided for containing a coil107 (i.e., a driving force transmitting member). Thegroove108 has afirst section108aat the head side, which can accept the outer diameter of the coil107, asecond section108bwhich is larger than thefirst section108a, and athird section108cfor connecting thesecond section108band therail portion105b. To thesecond section108b, acoil holding member109, attached to a base end of the coil107, is pressed and fastened. Thecoil holding member109 is fastened to the base end of the coil107 by a method such as autosplice processing or brazing. A wire110 (i.e., a driving force transmitting member) passes through thethird section108c. To the base end of thewire110, awire holding member111 is fastened by a method such as clamping or brazing. Thewire holding member111 is contained in agroove106aprovided at a center of themovable handle member106. Thegrooves108 and106aare closed by caps (not shown) after the coil107 and thewire110 are respectively inserted.
As shown inFIG. 10, to a head portion of the fixedhandle member105, a cylindricalhandle fastening member112 is coaxially positioned and fastened by using ascrew112b. As shown inFIG. 11, a head portion of thehandle fastening member112 has ahole112awhich fits an outer periphery of aflange portion120aprovided in a base end (near end) portion of afirst insertion portion120. A ring-shapedcap member113 is attached to an end face on the head side of thehandle fastening member112, thereby restricting movement of thefirst insertion portion120 along the axis. Theoperating section102 is fixed to thefirst insertion portion120 in the longitudinal axial direction; however, theoperating section102 can freely rotate with respect to thefirst insertion portion120 around the axis.
Ahead portion120b(a far end portion) of thefirst insertion portion120 has a hole121awhich opens in a direction perpendicular to the axis of thefirst insertion portion120. Another hole121bis also provided, which is closer to the base end side, and a specific distance L1 is secured between the holes121aand121b. Pins122 and123 are respectively inserted into the holes121aand121b. The pin122 passes through a hole131aof abase end portion130aof a link member130 (i.e., a first offset portion), so that thebase end portion130aof thelink member130 is attached to thehead portion120bof thefirst insertion portion120 via the pin122 in a freely rotatable form. The pin123 passes through a hole136aof abase end portion135aof alink member135, so that thebase end portion135aof thelink member135 is attached to thehead portion120bof thefirst insertion portion120 via the pin123 in a freely rotatable form. Thelink members130 and135 are arranged parallel to each other.
Ahole131bis formed in ahead portion130bof thelink member130, and a specific distance L2 is secured between theholes131aand131balong the length of thelink member130. At a position away from thehole131bby a further distance L3 in the same direction, another hole131cis formed. Similarly, in ahead portion135bof thelink member135, a hole136bis provided so that the specific distance L2 is secured between the holes136aand136b.
A pin137 is inserted into the hole136b. The pin137 is also inserted into a hole141aprovided in abase end portion140aof alink member140, so that thebase end portion140aof thelink member140 is coupled to thehead portion135bof thelink member135 via the pin137 in a freely rotatable form. Thelink member140 has ahole141bat a position away from the hole141aby a distance L1 toward the other end side. Apin138 is inserted into thehole141b. Thepin138 is also inserted into thehole131bof thelink member130 so that thehead portion130bof thelink member130 is coupled to thebase end portion140aof thelink member140 via thepin138 in a freely rotatable form.
Accordingly, aparallel link structure150 is formed by thefirst insertion portion120 and thelink members130,135, and140, that is, by four link members.
A pin139 is inserted into the hole131cof thelink member130. The pin139 is also inserted into a hole146aformed in abase end portion145aof alink member145, so that thebase end portion145aof thelink member145 is coupled to thehead portion130bof thelink member130 via the pin139 in a freely rotatable form. Thelink member145 has a hole146bat a position away from the hole146aby a distance L4 toward ahead portion145b. The distance L4 is sufficiently larger than the distance of a trocar W2 (seeFIG. 13) into which thesurgical treatment tool101 is inserted, so that thesurgical treatment tool101 can advance or withdraw through the trocar W2 while the surgical treatment tool is inserted in the trocar W2.
A pin147 is inserted into the hole146b. The pin147 is also inserted into a hole156aprovided in abase end portion155aof alink member155, so that thebase end portion155aof thelink member155 is coupled to thehead portion145bof thelink member145 via the pin147 in a freely rotatable form. Thelink member155 has a hole156bat a position away from the hole156aby the distance L3 toward the head end side. A pin157 is inserted into the hole156b. The pin157 is also inserted into a hole141cformed in ahead portion140bof thelink member140. The hole141cis formed at a position away from thehole141bby the distance L4 toward the other end side of thelink member140. Thehead portion140bof thelink member140 is coupled to thebase end portion155aof thelink member155 via the pin157 in a freely rotatable form.
Accordingly, aparallel link structure151 is formed by thelink members130,140,145, and155.
Thelink member140 has a hole141dat a position away from the hole141cby a distance L5 toward thehead portion140b. A pin158 is inserted into the hole141d. The pin158 is also inserted into a hole161aprovided in abase end portion160aof alink member160. Thebase end portion160aof thelink member160 is coupled to thehead portion140bof thelink member140 via the pin158 in a freely rotatable form.
Thelink member155 has a hole156cat a position away from the hole156bby the distance L2 toward thehead portion155b. A pin159 is inserted into the hole156c. The pin159 is also inserted into a hole166aprovided in abase end portion165aof ahead link member165. Thebase end portion165aof thehead link member165 is coupled to thehead portion155bof thelink member155 via the pin159 in a freely rotatable form. Thehead link member165 has a hole166bat a position away from the hole166aby the distance L5 toward the other end side. A pin167 is inserted into the hole166b. The pin167 is also inserted into a hole161bwhich is formed in thelink member160 at a position away from the hole161aby the distance L2 toward thehead portion160b. Thehead portion160bof thelink member160 is coupled to thebase end portion165aof thehead link member165 via the pin167 in a freely rotatable form.
Accordingly, aparallel link structure152 is formed by thelink members140,155, and160, and thehead link member165.
As shown inFIG. 12, in ahead portion165bof thehead link member165, ahole171 is formed so as to contain a cylindricalcoil holding member170 which is fit to thehole171. Thecoil holding member170 has a throughhole170afor accepting the outer diameter of the coil107. A head portion of the coil107 is inserted and fixed to the throughhole170a. Thecoil holding member170 has a smaller-diameter portion170bhaving a smaller outer diameter at substantially the center in the length direction of themember170. Apin172 fastened to thehead link member165 is received by the smaller-diameter portion170b. In accordance with the above structure, thecoil holding member170 and the coil107 are fastened to thehead link member165 in the longitudinal axial direction; however, they are freely rotatable with respect to thehead link member165 around the longitudinal axial direction.
To the head of the coil107, ahead housing member175 is fastened by a method such as brazing, welding, or adhesion. A throughhole175ais formed in a center portion of thehead housing member175. From the head of thehead housing member175, a pair ofsupports176 extends, to which apin177 is inserted in a direction perpendicular to the axes of the supports. A center portion of a pair of clippingmembers178aand178bis supported by thepin177 in a freely rotatable form. Ends oflink members180aand180bare respectively attached to base ends of the clippingmembers178aand178bvia thepins179aand179b. A head portion of a wirejoint member181 is held between the other ends of thelink members180aand180bwhich are coupled to each other by apin182 in a freely rotatable form. The wirejoint member181 is fastened to an end of thewire110 by a method such as brazing. A rotating operation of theoperation section102 is transmitted via the coil107 to thetreatment section104. In addition, an opening and closing operation of theoperation section102 is transmitted to thetreatment section104 by the wire passing through the coil107.
In theinsertion section103, twolink members130 and135 form the first offset portion extending away from the axis of theoperation section102. Twolink members140 and145 form the second insertion portion. Twolink members155 and160 form the second offset portion. Thehead link member165 functions as the third insertion portion.
The operation of the present embodiment will be explained below.
Theparallel link structure150 is moved so that thefirst insertion portion120 and thelink member140 are substantially linearly arranged. In thesurgical treatment tool101, in accordance with theparallel link structures150,151, and152, a variation in a distance from thebase end portions140aand145aof thelink members140 and145 as the second insertion portion to (the longitudinal axis of) thefirst insertion portion120 coincides with a variation in the distance from thehead portions140band145bof thelink members140 and145 to (the longitudinal axis of) thethird insertion portion165 which is present on an extension of the axis of thefirst insertion portion120. Therefore, as shown inFIG. 13, theparallel link structures151 and152 move together so that the elements from thetreatment section104 to theoperation section102 are substantially linearly arranged and can be inserted into the trocar W2. After the tool is inserted into the trocar W2 in this condition, theoperation section102 is operated so as to increase the distance between thefirst insertion portion120 and thelink member140. As shown inFIG. 14, according to theparallel link structures150,151, and152, thetreatment section104 also moves so as to depart from thelink member140, and, an offset F1 from an insertion section of the trocar W2 to thetreatment section104 is changed. In addition, when thesurgical treatment tool101 is made to advance or withdraw for the trocar W2, an insertion depth D1 of thetreatment section104 in the axial direction of the trocar W2 is changed. In the above operations, a constant positional relationship is established between thetreatment section104, thefirst insertion portion120, and theoperation section102.
When theoperation section102 is rotated with respect to thefirst insertion portion120 around the axial direction, the rotation is transmitted to thetreatment section104 via the coil107 fastened to theoperation section102. Therefore, in response to the rotation of theoperation section102, thetreatment section104 rotates with respect to thehead link member165 around the axis.
When themovable handle member106 is slid along the fixedhandle member105 toward the base end side thereof, thewire110 is pulled and the heads of the clippingmembers178aand178bof thetreatment section104 move to close. When themovable handle member106 is slid along the fixedhandle member105 toward the head side thereof, thewire110 is pushed inside and the heads of the clippingmembers178aand178bof thetreatment section104 move to be opened.
According to the present embodiment, regarding a single trocar W2, a wider area treatment is possible in comparison with conventional instruments. The number of trocars W2 necessary in a surgical operation can be reduced, and a time period necessary for inserting trocars W2 in a body wall W1 and a time period necessary for pulling out the treatment tool from a trocar W2 and inserting the tool through another trocar W2 can be reduced, thereby reducing a time necessary for each surgical operation and also reducing damage to the patient.
In addition, thetreatment section104 and theoperation section102 are coaxially arranged; thus, it is easy for the operator to intuitively know the position of thetreatment section104, and the operator can easily operate the treatment tool.
Furthermore, in conventional instruments, as shown inFIG. 15, an operation section must be moved for a trocar W2 as a fulcrum in a direction opposite to a direction in which a treatment section is moved in a coelom. In this case, the operation is not performed intuitively, and thus considerable time is necessary for the operator to become experienced. According to the present embodiment, as shown inFIG. 14, the direction in which theoperation section102 moves coincides with that of thetreatment section104, in any case of vertical, right-left, or front-back movement. Therefore, an intuitive operation can be performed, and less time is necessary for the operator to become experienced.
In addition, in conventional instruments which are greatly restricted by the trocar W2, approach to a specific position in a coelom is permitted in a single direction depending on the position where the trocar is inserted. Therefore, it is difficult for the operator to perform the operation. In the present embodiment, as shown inFIGS. 13 and 14, the direction of approach to a specific position in a coelom can be changed by adjusting the offset amount of thetreatment section104 for the trocar W2 (in the direction perpendicular to the axis of the trocar W2), or the amount of insertion in the direction of the axis of the trocar W2. Therefore, the operation can be performed considerably easily. It is unnecessary to consciously perform the above adjustment of the offset amount or the amount of insertion. Such adjustment is possible when the operator moves theoperation section102 with a feeling as if the trocar W2 were not present. As the operation can be easily performed, treatment can be performed more safely and reliably. Therefore, a time period necessary for each surgical operation can be reduced, and both the patient and operator receive less burden.
Third EmbodimentFIG. 16 shows a surgical treatment tool as a third embodiment of the instrument for the endoscope.
Asurgical treatment tool201 has aninsertion section203 extending from the head of anoperation section202, and atreatment section204 is provided at the head of theinsertion section203.
Theinsertion section203 is made of ahollow pipe line205 which is flexible and has an appropriate degree of hardness. Abase end portion205a(a near end) of thehollow pipe line205 is connected to a side of ahead portion206a(a far end) of a handle-side housing206 (as a first insertion portion) which is made of a rigid pipe member. In the handle-side housing206, acommunication passage207 is provided, which is joined to thehollow pipe line205. In addition, to thehead portion206aof the handle-side housing206, amagnet208 is fastened, which has a surface finished so that the surface can easily slide on a body wall W1.
Ahead portion205bof thehollow pipe line205 is connected to abase end portion209aof a head housing member209 (as a third insertion portion) made of a rigid pipe member. Ahead portion205bof thehollow pipe line205 is joined to acommunication passage210 of thehead housing member209. To abase end portion209aof thehead housing member209, amagnet211 is fastened, which has a surface finished so that the surface can easily slide on the body wall W1.
Thehollow pipe line205 consists of a first offsetportion205cincluding a part extending in a radial direction with respect to the axis of the handle-side housing206, asecond insertion portion205dwhich is bent but generally arranged parallel to the axis of the handle-side housing206, and a second offsetportion205econnected to thehead housing member209.
According to the above-described structure, a channel212 (an inner hole) as a continuous inner pipe line is formed through thecommunication passage207 of the handle-side housing206, thehollow pipe line205, and thecommunication passage210 of thehead housing member209. Atreatment tool220 for a soft endoscope is inserted into thechannel212 from the base end side of the handle-side housing206, where thetool220 has a length corresponding to the length of thechannel212.
Thetreatment tool220 has ahandle portion221 from which aninsertion portion222 extends. Ahead treatment portion223 for performing treatment is provided at the head of theinsertion portion222.
Theinsertion portion222 has aflexible coil224 which can transmit torque. Awire225 passes through thecoil224 in a manner such that thewire225 can freely move forward or backward. A specific length of ahead portion224aof thecoil224 is not flexible, where this length substantially coincides with the length of thehead housing member209. Similarly, a specific length of abase end portion224bof thecoil224, closer to thehandle portion221, is not flexible, where this length substantially coincides with the length of the handle-side housing member206. Therefore, if thehead portion224aor thebase end portion224bof thecoil224 protrudes from thehousing member206 or209, the protruding portion is not bent.
As shown inFIG. 17, when amultiple thrust mechanism231 is provided at abase end portion206bof the handle-side housing206 so as to support thebase end portion224bin theinsertion portion222, the rigidity can be improved. Similarly, when amultiple thrust mechanism230 is provided at ahead portion209bof thehead housing member209 so as to support thehead portion224ain theinsertion portion222 of thetreatment section220, the rigidity can also be improved.
Thehandle portion221 as shown inFIG. 16 has a fixedhandle member240 and amovable handle member241 which can slide along the fixed handle member240 (in the longitudinal axial direction). To the fixedhandle member240, thebase end portion224bof thecoil224 is fastened. To themovable handle member241, a base end portion of thewire225 is fastened.
Thehead treatment portion223 has a pair of clippingmembers245aand245bwhich can be freely opened and closed. Base ends of the clippingmembers245aand245bare respectively connected to linkmembers180aand180bin a freely rotatable form. Ends of thelink members180aand180bare connected to a head portion of thewire225 in a freely rotatable form. The pair of clippingmembers245aand245bcan be opened or closed by moving thewire225 forward or backward.
The operation of the present embodiment will be explained below.
After thehead housing member209 is inserted into a coelom through a trocar W2, themagnet208, provided at the head of the handle-side housing, is made to approach the body wall. Accordingly, themagnet211, provided at the base end side of thehead housing member209, is pulled toward the body wall by magnetic force. Simultaneously, thehollow pipe line205 is bent so that the handle-side housing206 and thehead housing member209 are linearly arranged on either side of the body wall. In this state, when thehandle portion221 is moved along the body wall, thehollow pipe line205 is bent because magnetic force generated by themagnets208 and211 is greater than a force against bending of thehollow pipe line205. A linear arrangement of the handle-side housing206 and thehead housing member209 is maintained. When thehandle portion221 is moved along the body wall W1, thehead treatment portion223 moves in the same direction as the direction of the movement of thehandle portion221, similarly to when in a state in which no trocar W2 is present.
When thehandle portion221 is pushed toward the body wall W1 while the position of the handle-side housing206 is maintained, and thetreatment tool220 proceeds along thechannel212. Thehead treatment portion223 then protrudes from the head of thehead housing member209, where the amount of protrusion coincides with the amount of pushing (i.e., the moving distance) of thehandle portion221. In this process, thehead portion224aof thecoil224 is not flexible; thus, when this portion protrudes from thehead housing member209, various operations can be performed without bending. When thehandle portion221 is withdrawn from the body wall, thetreatment tool220 is withdrawn along thechannel212. The head treatment portion213 is also withdrawn, where the amount of withdrawal coincides with the amount of withdrawal of thehandle portion221. During the above operations, the distance and the positional relationship between thehandle portion221 and thehead treatment portion223 are maintained to be constant. Thehead treatment portion223 moves together with thehandle portion221, similarly in a state in which no body wall W1 is present.
When thehandle portion221 is rotated with respect to the handle-side housing206, the rotation is transmitted via thecoil224 to thehead treatment portion223, and thehead treatment portion223 rotates by the same amount of rotation as that of the rotation of thehandle portion221.
When themovable handle member241 is moved forward or backward along the fixedhandle member240, thewire225 also moves forward or backward. Therefore, the clippingmembers245aand245b, coupled to thewire225 via thelink members180aand180b, are opened or closed.
According to the present embodiment, through a single trocar W2, a wider area treatment is possible in comparison with conventional instruments. The number of trocars W2 necessary in a surgical operation can be reduced, and a time period necessary for inserting trocars W2 in a body wall W1 and a time period necessary for pulling out the treatment tool from a trocar W2 and inserting the tool through another trocar W2 can be reduced, thereby reducing a time necessary for each surgical operation and also reducing damage to the patient.
In addition, the treatment section and the operation section are substantially coaxially arranged; thus, it is easy for the operator to intuitively know the position of the treatment section, and the operator can easily operate the treatment tool.
In conventional instruments, an operation section must be moved for a trocar as a fulcrum in a direction opposite to a direction in which a treatment section is moved in a coelom. In this case, the operation is not performed intuitively, and thus considerable time is necessary for the operator to become experienced. According to the present embodiment, the direction in which thehandle portion221 of thetreatment tool220 or the handle-side housing206 moves coincides with that of thehead treatment portion223 or thehead housing member209, in any case of vertical, right-left, or front-back movement. Therefore, an intuitive operation can be performed, and less time is necessary for the operator to become experienced.
Fourth EmbodimentFIG. 18 shows a surgical treatment tool as a fourth embodiment of the instrument for the endoscope.
Asurgical treatment tool301 has aninsertion section303 extending from the head of anoperation section302, and atreatment section304 is provided at the head of theinsertion section303.
Theoperation section302 has a fixedhandle member305 and amovable handle member306 which can freely advance or withdraw along the fixedhandle member305 along the axis thereof. Ahook307 is provided at the head side of the fixedhandle member305. Thehook307 is inserted in a freely rotatable form through a smaller-inner-diameter portion310aas a base end portion (a near end) of a handle-side connection member310 which is made of an L-shaped hollow member. Accordingly, the fixedhandle member305 can be rotated with respect to afirst insertion portion313 of the handle-side connection member310.
Theinsertion section303 includes the handle-side connection member310 which has a firstbent portion311 at a head portion (a far end) of thefirst insertion portion313. Thefirst insertion portion313 is parallel to the axis of theoperation section302. The handle-side connection member310 bends perpendicularly at the firstbent portion311, and has aslide portion312 extending from thebent portion311 in a direction perpendicular to the axis of theoperation section302. A head portion of theslide portion312 is fit to a base end portion of aguide portion320 of anintermediate connection member315 in a manner such that the fit portion can freely advance or withdraw.
Theintermediate connection member315 has a secondbent portion321 at an end portion of theguide portion320. The secondbent portion321 bends perpendicularly, and asecond insertion portion325 extends from the secondbent portion321 parallel to the axis of theoperation section302. A thirdbent portion326 is provided at the head of thesecond insertion portion325. The thirdbent portion326 bends perpendicularly, and aguide portion330 extends from the thirdbent portion326, where theguide portion330 is perpendicular to thesecond insertion portion325. Theguide portion330 is arranged parallel to theguide portion320. Theintermediate connection member315 is a hollow member having a general shape close to that of the letter U. To a head portion of theguide portion330 of theintermediate connection member315, a base end portion of aslide portion341 of ahead connection member340 is fit in a manner such that the fit portion can freely advance or withdraw. Thehead connection member340 has a fourthbent portion342 at a head portion of theslide portion341 which extends parallel to theguide portion330. The fourthbent portion342 bends perpendicularly, and athird insertion portion343 extends from the fourthbent portion342 parallel to the axis of theoperation section302. Therefore, thehead connection member340 is a hollow member having a general shape close to that of the letter L.
The thirdbent portion326 close to the head of theintermediate connection member315 and the fourthbent portion342 of thehead connection member340 are made of an elastic material, and thus can have substantially linear forms when being inserted into a trocar W2. However, the thirdbent portion326 and the fourthbent portion342 have a certain degree of hardness by which they are not deformed by external force applied when treatment is performed after the insertion into a living body. In addition, the distance between the secondbent portion321 and the thirdbent portion326 of theintermediate connection member315 is sufficiently longer than the length of the trocar W2 into which thesurgical treatment tool301 is inserted. Therefore, thesurgical treatment tool301 can be advanced or withdrawn for the trocar W2 while the section from the secondbent portion321 to the thirdbent portion326 of theintermediate connection member315 is inserted into the trocar W2.
In theinsertion portion303, theslide portion312 of the handle-side connection member310 and theguide portion320 of theintermediate connection member315 form a first offset portion which can freely expand or contract. Theguide portion330 of theintermediate connection member315 and theslide portion341 of thehead connection member340 form a second offset portion which can freely expand or contract. The direction of the expansion and contraction is perpendicular to the axis of theoperation section302 and thetreatment section304.
In thehead connection member340, ahook350 of thetreatment section304 is fit through a smaller-inner-diameter portion345 of thethird insertion portion343. Thehook350 is provided at a base end side of ahead connection member351. Thehook350 restricts movement of thehead housing member351 with respect to thehead connection member340 in the axial direction. However, thehead connection member351 is freely rotatably connected to thehead connection member340 around the axis thereof. Thehead connection member351 has a throughhole351ain the axial direction.
From a head portion of thehead housing member351, a pair ofsupports352 extends, and a center part of a pair of clippingmembers354aand354bis supported in a freely rotatable form by apin353 which is mounted to thesupports352. At the base end sides of the pair of clippingmembers354aand354b, ends oflink members356aand356bare respectively supported bypins355aand355bin a freely rotatable form. The other ends of thelink members356aand356bare fastened to a head portion of awire connection member358 via apin357.
In theinsertion section303, inner pipe lines of the handle-side connection member310, theintermediate connection member315, and thehead connection member340 are joined and communicate with each other, thereby forming a working channel360 (i.e., an inner hole). A wire361 (i.e., a driving force transmitting device) passes through thechannel360. Thewire361 is a metal wire having a superior torque transmitting performance. A base end portion of thewire361 is drawn into theoperation section302 and fastened to awire holding member362 by a method such as brazing or clamping. Thewire holding member362 is fastened to themovable handle member306 by a method such as press fitting or adhesion. A head portion of thewire361 is fastened to the base end side of thewire connection member358 by a method such as brazing, clamping, or adhesion. Thewire connection member358 is forced toward the head side by an elastic member such as acoil spring363. Therefore, when theoperation section302 is operated, the operation is transmitted via thewire361 to thetreatment section304, so that the pair of clippingmembers354aand354bis opened, closed, or rotated.
In thechannel360, apulley370 is attached to the firstbent portion311 of the handle-side connection member310. To a head portion of theslide portion312 of the handle-side connection member310, apulley371 is attached. To a base end portion of theguide portion320 of theintermediate connection member315,pulleys372aand372bare attached, each of which can independently rotate. Apulley373 is attached to the secondbent portion321 of theintermediate connection member315. Apulley374 is attached to the thirdbent portion326 of theintermediate connection member315. Additionally, pulleys375aand375bare attached to a head portion of theintermediate connection member315. Each of thepulleys375aand375bcan independently rotate. Apulley376 is attached to a base end portion of theslide portion341 of thehead connection member340. Apulley377 is attached to the fourthbent portion342 of thehead connection member340. Thewire361 is hung on each of thepulleys370,371,372a,373,374,375a,376, and377 in turn.
The handle-side connection member310 and thehead connection member340 are connected viawires380 and381 passing through thechannel360. Thewires380 and381 (driving force transmitting devices) are made of a metal material having low expandability, and may be made of a super fiber such as Kevlar.
A base end portion of thewire380 is fastened to a head portion of theslide portion312 of the handle-side connection member310. In thechannel360, thewire380 is hung on apulley383 attached to the secondbent portion321 of theintermediate connection member315, apulley384 attached to the thirdbent portion326, and apulley375battached to a head portion of theguide portion330 of theintermediate connection member315 in turn, and then fastened to the base end of theslide portion341 of thehead connection member340.
A base end portion of thewire381 is fastened to a head portion of theslide portion312 of the handle-side connection member310. In thechannel360, thewire381 is hung on apulley372battached to a base end portion of theguide portion320 of theintermediate connection member315, apulley382 attached to the secondbent portion321, and apulley383 attached to the thirdbent portion326 in turn, and then fastened to a base end portion of theslide portion341 of thehead connection member340.
The lengths of thewires380 and381 are adjusted so that theoperation section302 and thetreatment section304 are coaxially arranged. In theslide portion312 of the handle-side connection member310, aslit312ais provided so as to accept thepulleys372aand372bof theintermediate connection member315. Similarly, in a base portion of thehead connection member340, aslit341ais provided so as to accept thepulleys375aand375bof theintermediate connection member315. According to theslits312aand341a, the handle-side connection member310 and thehead connection member340 can move for theintermediate connection member315 without interfering with thepulleys372a,372b,375a, and375b.
The operation of the present embodiment will be explained below.
When thethird insertion portion343 is inserted into a coelom, the thirdbent portion326 of theintermediate connection member315 and the fourthbent portion342 of thehead connection member340, made of an elastic material, can be transformed into a substantially linear form.
When the fixedhandle member305 of theoperation section302 is rotated with respect to the handle-side connection member310 of theinsertion section303, thewire361 rotates. The rotation is transmitted to thehead housing member351 via thewire361, and thetreatment section304 rotates with respect to thehead connection member340.
When themovable handle member306 is withdrawn along the fixedhandle member305, thewire361 pulls thewire connection member358 toward the base end side against a force by thespring363, so that the pair of clippingmembers354aand354bare closed. When themovable handle member306 is released, the pair of clippingmembers354aand354bare opened by the force of thespring363.
When theoperation section302 is moved parallel to a body wall W1 (e.g., in a horizontal direction) so that theoperation section302 approaches theintermediate connection member315, the base end portion of thewire381 is pulled, and thehead connection member340, to which the head portion of thewire381 is fastened, is drawn toward theintermediate connection member315. In this process, thetreatment section304 moves in the same direction as the direction in which theoperation section302 moves. When theoperation section302 is moved parallel to the body wall W1 (e.g., in a horizontal direction) so that theoperation section302 leaves theintermediate connection member315, the base end portion of thewire380 is pulled, and thehead connection member340, to which the head portion of thewire380 is fastened, is drawn so that thehead connection member340 leaves theintermediate connection member315. In this process, thetreatment section304 moves in the same direction as the direction in which theoperation section302 moves.
According to the present embodiment, through a single trocar W2, a wider area treatment is possible in comparison with conventional instruments. The number of trocars W2 necessary in a surgical operation can be reduced, and a time period necessary for inserting trocars W2 in a body wall W1 and a time period necessary for pulling out the treatment tool from a trocar W2 and inserting the tool through another trocar W2 can be reduced, thereby reducing a time necessary for each surgical operation and also reducing damage to the patient.
In addition, thetreatment section304 and theoperation section302 are substantially coaxially arranged; thus, it is easy for the operator to intuitively know the position of thetreatment section304, and the operator can easily operate the treatment tool.
In conventional instruments, an operation section must be moved around a trocar as a fulcrum in a direction opposite to a direction in which a treatment section is moved in a coelom. In this case, the operation is not performed intuitively, and thus considerable time is necessary for the operator to become experienced. According to the present embodiment, the direction in which theoperation section302 moves coincides with that of thetreatment section304, in any case of vertical, right-left, or front-back movement. Therefore, an intuitive operation can be performed, and less time is necessary for the operator to become experienced.
In addition, in conventional instruments which receive more restriction from the trocar, approach to a specific position in a coelom is permitted only in a single direction depending on the position where the trocar is mounted. Therefore, it is difficult for the operator to perform the operation. In the present embodiment, the direction of approach to a specific position in a coelom can be changed by adjusting the offset amount of thetreatment section304 for the trocar W2 (in the direction perpendicular to the axis of the trocar W2), or the amount of insertion along the axis of the trocar W2. Therefore, the operation can be performed considerably easily. It is unnecessary to consciously perform the above adjustment of the offset amount or the amount of insertion. Such adjustment is possible when the operator moves theoperation section302 with a feeling as if the trocar W2 were not present. As the operation can be easily performed, treatment can be performed more safely and reliably. Therefore, a time period necessary for each surgical operation can be reduced, and both patient and operator receive less burden.
Instead of thewire361, A tube containing a fluid may be used for transmitting the opening/closing operation or the rotation to thetreatment section304.FIG. 19 shows asurgical treatment tool301aas an example. A tube390 (i.e., a driving force transmitting device) is coupled to theoperation section302, and is hung on thepulleys371,372a,373,374,375a,376, and377 in turn, and is coupled to thehead housing member351 of theoperation section302. The base end side of thetube390 is connected to acylinder391 which is fixed in the fixedhandle member306. In thecylinder391, apiston392, which is fastened to themovable handle member306, is slidably arranged. The head side of thetube390 is connected acylinder393 which is fixed in thehead housing member351. In thecylinder393, apiston394, which is connected to the base end side of thewire connection member358, is slidably inserted. Thetube390 is made of a flexible material, and is filled with a fluid such as physiological saline (solution), oil, or air.
Instead of thewires380 and381, a tube395 (i.e., a driving force transmitting device) is used. Thetube395 is fixed along theintermediate connection member315 and is connected to acylinder396 in theguide portion320 of theintermediate connection member315. In thecylinder396, apiston397 is inserted from the side where the secondbent portion321 is present, parallel to the axis of theguide portion320 of theintermediate connection member315, in a manner such that thepiston397 can freely slide. Thepiston397 is fastened to the head portion of the handle-side connection member310. To a head portion of thetube395, acylinder398 is connected. In thecylinder398, apiston399 is inserted from the side where thehead connection member340 is present, parallel to the axis of theguide portion330 of theintermediate connection member315, in a manner such that thepiston397 can freely slide. Thepiston399 is connected to theslide portion341 of thehead connection member340. Thetube395 is filled with a fluid such as physiological saline, oil, or air.
In thesurgical treatment tool301a, the opening/closing operation is transmitted from theoperation section302 to thetreatment section304 via a fluid such as physiological saline. Power is transmitted via a fluid such as physiological saline, provided in thetube395, and thecylinders396 and397; thus, thetreatment section304 moves in the same direction as the direction in which theoperation section302 moves. According to thesurgical treatment tool301a, a more exact feel for grasping a tissue, or a more subtle force applied to the heads of the clipping members132aand132bis transmitted to the operator, thereby allowing safer treatment. The other effects obtained by thesurgical treatment tool301aare the same as those obtained by thesurgical treatment tool301.
As shown inFIG. 20, instead of thewire361, anultrasonic motor401 connected to thehead connection member340 may be used. Anoutput shaft402 of theultrasonic motor401 can be driven in either of (i) a direct acting direction (indicated by the arrow C1 inFIG. 20) for moving forward or backward along the axis of thehead connection member340, and (ii) a rotational direction (indicated by the arrow C2 inFIG. 20) around the axis of thehead connection member340. To a head portion of theoutput shaft402 of theultrasonic motor401, the base end portions of thelink members356aand356bare coupled via apin357 in a freely rotatable form.
To theultrasonic motor401, a signal output from amotor driver404 is sent via asignal line403. Themotor driver404 is connected to aposition sensor405, anencoder406, and apower supply407. Theposition sensor405 is provided in theoperation section302, so as to measure the position of themovable handle member306 with respect to the fixedhandle member305 in theoperation section302. Theencoder406 measures an amount of rotation when theoperation section302 is rotated with respect to the handle-side connection member310. Based on data output from theposition sensor405 and theencoder406, themotor driver404 controls theultrasonic motor401 so that a degree of opening/closing and an amount of rotation of the pair of the clippingmembers354aand354bof thetreatment section304 coincide with an amount of movement of the operation section302 (corresponding to an amount of movement of the movable handle member306) and an amount of rotation of theoperation section302. Instead of themotor driver404, another kind of an actuator such as a DC (direct current) motor may be used.
In treatment, theoperation section302 is rotated with respect to the handle-side connection member310. Theencoder406 measures the amount of rotation. Themotor driver404 sends and outputs a signal to theultrasonic motor401 so that theoutput shaft402 rotates in the direction C2 in accordance with the measured amount of rotation. Accordingly, thetreatment section304 rotates with respect to thehead connection member340.
When themovable handle member306 is withdrawn along the fixedhandle member305, theposition sensor405 measures the amount of this movement. Themotor driver404 sends an output signal to theultrasonic motor401 so that theoutput shaft402 withdraws in the direction C1 in accordance with the measured amount of movement. Accordingly, the pair of clippingmembers354aand354bis closed. When themovable handle member306 is advanced along the fixedhandle member305, theposition sensor405 measures the amount of this movement, similarly. Themotor driver404 outputs and sends a signal to theultrasonic motor401 so that theoutput shaft402 advances in the direction C1 in accordance with the measured amount of movement. Accordingly, the pair of clippingmembers354aand354bis opened. Effects obtained by thesurgical treatment tool400 are similar to those obtained by thesurgical treatment tool301.
As shown inFIG. 21, a rack and pinion mechanism and a pulley mechanism may be used. In asurgical treatment tool500, arack501 is fastened to the head portion of the handle-side connection member310. Therack501 is engaged with apinion502 which is attached to the base end portion of theintermediate connection member315 in a freely rotatable form. Ashaft503 extends in a direction perpendicular to the axis of theslide portion312. Thepinion502 is fastened to apulley504 which is fastened to theshaft503 where thepinion502 and thepulley504 are integrally formed. Abelt505 is hung around (an outer periphery of) thepulley504. Thisbelt505 is also hung around (an outer periphery of) apulley506 which is arranged in the secondbent portion321. Theshaft510 functions as the rotation shaft of thepulley506, and is attached to theintermediate connection member315, parallel to the axis of thesecond insertion portion325 in a freely rotatable form. A head portion of theshaft510 reaches the thirdbent portion326 in which apulley511 is attached to the shaft. Abelt512 is hung around (an outer periphery of) thepulley511. Thebelt512 is also hung around (an outer periphery of) a pulley513 which is contained in thehead connection member340 and is attached to ashaft514 and apinion515. Theshaft514 is attached to the head portion of theguide portion330 of theintermediate connection member315 in a freely rotatable form. Thepinion515 is engaged with arack516 which is fastened to a base end portion of theslide portion341 of thehead connection member340, parallel to the axis of theslide portion341. InFIG. 20, thecoil31 or thewire32 for transmitting a driving force from theoperation section302 is not shown.
In treatment, theoperation section302 is made to approach theintermediate connection member315. Thepinion502 then rotates around theshaft503, and accordingly, thepulley504 rotates. This rotation is transmitted via thebelt505 to thepulley506, and thepulley511 also rotates in the same direction via theshaft510. The rotation of thepulley511 is transmitted via thebelt512 to the pulley513. Thepinion515 fastened to the pulley513 then rotates around theshaft514. Therack516, engaged with thepinion515, is fastened to thehead connection member340; thus, thehead connection member340 and thetreatment section304 move toward theintermediate connection member315, as theoperation section302 moves. When theoperation section302 is moved so that theoperation section302 leaves theintermediate connection member315, rotation is also transmitted similarly, and thetreatment section304 also moves so as to leave theintermediate connection member315. When the rack and pinion mechanism close to theoperation section302 and the rack and pinion mechanism close to thetreatment section304 have the same structure, the amount and the direction of movement of theoperation section302 coincide with those of thetreatment section304. Effects obtained by thesurgical treatment tool500 are similar to those obtained by thesurgical treatment tool301.
The embodiments are not limited to the above-descried structures, and any appropriate combination between embodiments may be possible.
In the above embodiments, the instrument for the endoscope may be an observation instrument having an imaging device such as a CCD (charge coupled device) or a CMOS (complementary metal oxide semiconductor) instead of thetreatment section4,104, or304, or thehead treatment section223. The part to be observed can be changed by a function similar to that described in either embodiment. In comparison with a conventional hard endoscope, a wider area observation is possible. The position of theoperation section2,102,302, or thehandle221 and the position of an observation device provided at the head of the instrument have a constant relationship. Therefore, it is possible to solve a problem of a conventional endoscope having a bent structure in which it is difficult to understand the observation direction, and possible to intuitively change the observed part.FIG. 22 shows an example of an observation instrument. Anobservation instrument600 has aninsertion section303. To a smaller-inner-diameter portion310aof a handle-side connection member310, anadaptor601 is attached, to which acord602 is joined. Thecord602 includes avideo cable603 and anelectric cable604 which are coated. Thevideo cable603 and theelectric cable604 pass through theinsertion section303 and reach anobservation section605 provided on the head side. Theobservation section605 has animaging unit606 and aradiating device607. Theimaging unit606 has an imaging device and an objective optical system, and an image signal output from the imaging device is output to thevideo cable603. As the imaging device, a CCD or a CMOS may be used. The radiatingdevice607 emits light by receiving electric power from theelectric cable604, and may be an LED (light emitting diode). The position of thesecond insertion portion325 is offset with respect to thefirst insertion portion313 and thethird insertion portion343. Therefore, as shown inFIG. 23, when thefirst insertion portion313 side is rotated with respect to the axis of the trocar W2, the position of theobservation section605 can be changed in a coelom, thereby easily changing an observation field R1 of view. As shown inFIG. 24, when thefirst insertion portion313 is moved in parallel in a direction F1 with respect to thesecond insertion portion325, thethird insertion portion343 moves in the same direction via thewires380 and381 (seeFIG. 22). The field R1 of view of thethird insertion portion343 is then horizontally moved.