Surgical stapling methods and tools which allow a surgeon to create several different predetermined amounts of tissue constriction using the same staple (11) loaded in such a tool (31). A stapling tool (31) holding one or more staples in an effector section (35) contains a mechanism for spreading th
Surgical stapling methods and tools which allow a surgeon to create several different predetermined amounts of tissue constriction using the same staple (11) loaded in such a tool (31). A stapling tool (31) holding one or more staples in an effector section (35) contains a mechanism for spreading the pointed ends of a staple to one of several spaced apart distances as controlled by an actuator-indicator (43). Depending upon the distance the pointed ends have been spread when the staple is implanted into tissue (51), the amount of constriction accomplished by the staple is varied. An improved staple construction (61) of increased rigidity is also shown.
대표청구항▼
1. A surgical stapling tool which comprises: a main body which includes a handle portion,an effector extending from said body which holds at least one surgical staple having two legs with pointed ends and a crown connector interconnecting the opposite ends of the legs,said effector including a first
1. A surgical stapling tool which comprises: a main body which includes a handle portion,an effector extending from said body which holds at least one surgical staple having two legs with pointed ends and a crown connector interconnecting the opposite ends of the legs,said effector including a first mechanism for adjusting the distance between the pointed ends of the legs so they become spaced apart a precise desired distance that is one of several different distances while the distance between upper ends of the legs at the crown connector remains unchanged,an actuator-indicator incorporated in said body for operating said first mechanism,a second mechanism which causes the effector to implant the staple into body tissue or organ tissue so as to achieve a precise amount of constriction, which constriction is dependent upon the one of said several different precise spaced apart distances to which the pointed ends were adjusted, andan actuator for causing said second mechanism to operate. 2. The stapling tool of claim 1 wherein said first mechanism applies force to the interior surfaces of the legs to spread the pointed ends of the legs further apart to achieve said precise desired distance which is greater than the distance between upper ends of the legs at the crown connector. 3. The stapling tool of claim 1 wherein the legs and the crown connector are coplanar and the legs each have a shallow curvature with concave interior surfaces of the legs facing each other. 4. The stapling tool of claim 1 wherein said second mechanism is designed to drive a staple formed of shape memory material directly into body or organ tissue in which the staple is being implanted. 5. The stapling tool of claim 1 wherein said second mechanism is designed to hold the crown connector of a staple made of non-shape memory metal alloy and drives the staple into the tissue in a manner so as to bend the legs and effect plastic deformation thereof into a constricting shape at the time of implantation into body or organ tissue by applying force to exterior surfaces of the legs. 6. In combination, the stapling tool of claim 5 and a plurality of surgical staples each of which comprises two legs having pointed free ends and a crown connector interconnecting the upper ends of said legs, said staples being essentially planar and formed completely of wireform material having an I-beam cross-section where two parallel flanges flank a central web, which flanges are oriented perpendicular to the plane of the staple. 7. The stapling tool of claim 1 wherein said effector is designed to hold a planar staple made from metal alloy wire having an I-beam cross section in the form of a web and two parallel flanges, with said I-beam flanges in each leg being aligned perpendicular to the plane of the staple. 8. A surgical stapling tool which comprises: a main body that includes a handle portionan effector extending from said body which holds at least one planar surgical staple having two legs with points at one end and a crown connector interconnecting the opposite ends of the legs which planar staple is made from metal alloy wire having an I-beam cross section which has a web between two flanges, with the I-beam flanges in each leg being aligned perpendicular to the plane of the staple,said effector including a first mechanism for spreading the legs of said staple to adjust the distance between the pointed ends of the legs,an actuator-indicator incorporated in said body for operating said first mechanism to change the distance between the pointed ends to one of several precise spaced-apart distances that are different and each greater than the distance between the upper ends of the legs at the crown connector,a second mechanism which causes the effector to implant the staple into body tissue or organ tissue so as to achieve a precise amount of constriction, which constriction amount is dependent upon the particular precise, spaced-apart distance to which the pointed ends were adjusted, anda trigger for causing said second mechanism to operate. 9. The stapling tool of claim 8 wherein said first mechanism applies force to interior surfaces of the legs. 10. In combination, the stapling tool of claim 8 and a plurality of surgical staples each of which comprises two legs having pointed free lower ends and a crown connector interconnecting the upper ends of said legs, said staples being essentially planar and formed completely of wireform material having an I-beam cross-section, where the two flanges are parallel and oriented perpendicular to the plane of the staple. 11. The combination of claim 10 wherein the two flanges of the staple are about equal in length and about equal in thickness. 12. The combination of claim 11 wherein the cross sectional shape of the web has a thickness within about 25% of the thickness of each flange and a length which is not more than about 50% greater in length than each flange. 13. A surgical stapling tool which comprises: a main body which includes a handle portion,an effector extending from said body which holds at least one surgical staple having two legs with pointed ends and a crown connector interconnecting the opposite ends of the legs, with the legs and the crown connector being coplanar,said legs each being formed with a continuous arcuate shallow curvature with concave interior surfaces of the legs facing each other,said effector including a first mechanism for adjusting the distance between the pointed ends of the legs so the pointed ends become spaced apart a precise desired distance that is one of several different distances,an actuator-indicator incorporated in said body for operating said first mechanism,a second mechanism which causes the effector to implant the staple into body tissue or organ tissue so as to achieve a precise amount of constriction, which constriction is dependent upon the one of said several different spaced apart distances to which the pointed ends were adjusted, andan actuator for causing said second mechanism to operate. 14. The stapling tool of claim 13 wherein said first mechanism adjusts the distance between the pointed ends while the distance between upper ends of the legs at the crown connector remains unchanged. 15. The stapling tool of claim 13 wherein said first mechanism applies force to the interior surfaces of the legs to spread the pointed ends of the legs further apart to achieve said precise desired distance, which distance is greater than the distance between upper ends of the legs at the crown connector. 16. The stapling tool of claim 13 wherein said second mechanism is designed to drive a staple formed of shape-memory metal directly into the tissue in which it is being implanted. 17. The stapling tool of claim 13 wherein said second mechanism is designed to hold the crown connector of a staple made of non-shape memory metal alloy and to drive it into the tissue in a manner so as to bend the legs and effect plastic deformation into a constricting shape at the time of implantation into the tissue by applying force to exterior surfaces of the legs.
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