Articulation joint with bending member

Abstract

The present disclosure provides an articulation joint that can include a plurality of articulation links, wherein each articulation link can include an elongate body having a proximal end, a distal end, an outer surface, and a first lumen extending from the proximal end to the distal end. Each articulation link can further include a plurality of arms extending radially outward from the elongate body, wherein each arm includes an inner end attached to the outer surface of the elongate body and a second lumen extending from a proximal side of the arm to a distal side of the arm. The articulation joint can also include a bending member positioned within the first lumen of the elongate body and a control member positioned within a plurality of second lumens, wherein each of the plurality of second lumens includes a common longitudinal axis.

Claims

1. An articulation assembly, comprising: a sheath; an articulation link within the sheath, wherein the articulation link includes a central passage, wherein surface portions of the articulation link define one or more sides of a peripheral passage, the peripheral passage being radially outward of the central passage, and wherein the peripheral passage includes curved sides and straight sides; and a lumen configured to receive a control member; wherein a surface portion of the sheath defines one of the curved sides of the peripheral passage, and wherein at least one of the curved sides of the peripheral passage is formed by a wall of the lumen.

2. The articulation assembly of claim 1, wherein the surface portions of the articulation link define (a) at least one of the curved sides and (b) the straight sides of the peripheral passage.

3. The articulation assembly of claim 1, wherein the articulation link includes a cylindrical portion defining the central passage.

4. The articulation assembly of claim 3, wherein the articulation link includes a pair of straight surface portions extending radially-outwardly from the cylindrical portion, wherein the peripheral passage extends between the pair of straight surface portions, and wherein the pair of straight surface portions define the straight sides of the peripheral passage.

5. The articulation assembly of claim 4, wherein the articulation link includes a peripheral cylindrical portion at an end of a straight surface portion of the pair of straight surface portions.

6. The articulation assembly of claim 1, wherein the curved sides of the peripheral passage include a radially-inner convex side and a radially-outer concave side.

7. The articulation assembly of claim 1, further including a bendable member extending through the central passage, wherein the articulation link is one of a plurality of articulation links mounted on the bendable member.

8. The articulation assembly of claim 7, wherein adjacent articulation links of the plurality of articulation links have opposing surfaces separated by a gap, and wherein the bendable member is exposed at the gap.

9. The articulation assembly of claim 1, wherein one side of the peripheral passage is defined by a wall of the central passage.

10. The articulation assembly of claim 1, wherein the at least one curved side formed by the wall of the lumen is between a curved side of the peripheral passage and a straight side of the peripheral passage.

11. An articulation assembly, comprising: a sheath; a bendable member within the sheath; a plurality of articulation links within the sheath, wherein the plurality of articulation links are mounted on the bendable member such that a central passage of each of the plurality of articulation links surrounds a portion of the bendable member, wherein adjacent articulation links of the plurality of articulation links have opposing surfaces separated by a gap, and wherein the bendable member is exposed at the gap between the opposing surfaces of the adjacent articulation links; wherein surface portions of each of the plurality of articulation links define one or more sides of a peripheral passage, the peripheral passage being radially outward of the central passage, and wherein the peripheral passage includes curved sides and straight sides.

12. The articulation assembly of claim 11, wherein an inner surface at least one articulation link of the plurality of articulation links is fixedly coupled to an outer surface of the bendable member.

13. The articulation assembly of claim 11, wherein the opposing surfaces extend parallel to each other when the bendable member is in a straight configuration.

14. The articulation assembly of claim 11, wherein a surface portion of the sheath defines one of the curved sides of the peripheral passage.

15. The articulation assembly of claim 14, wherein one side of the peripheral passage is defined by a wall of the central passage.

16. The articulation assembly of claim 11, wherein each of the plurality of articulation links includes a lumen configured to receive a control member, wherein at least one of the curved sides of the peripheral passage is formed by a wall of the lumen.

17. The articulation assembly of claim 16, wherein the at least one curved side formed by the wall of the lumen is between a curved side of the peripheral passage and a straight side of the peripheral passage.

18. The articulation assembly of claim 11, wherein each of the plurality of articulation links does not directly contact another of the plurality of articulation links.

19. An articulation assembly, comprising: a sheath; and an articulation link within the sheath, wherein the articulation link includes a cylindrical portion defining a central passage, wherein surface portions of the articulation link define one or more sides of a peripheral passage, the peripheral passage being radially outward of the central passage, wherein the peripheral passage includes curved sides and straight sides, wherein the articulation link includes a pair of straight surface portions extending radially-outwardly from the cylindrical portion, wherein the peripheral passage extends between the pair of straight surface portions, wherein the pair of straight surface portions define the straight sides of the peripheral passage, wherein the articulation link includes a peripheral cylindrical portion at an end of a straight surface portion of the pair of straight surface portions, and wherein a surface portion of the sheath defines one of the curved sides of the peripheral passage.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description, serve to explain the principles of the invention.

(2) FIG. 1 is a perspective view of a device, according to an exemplary embodiment of the invention;

(3) FIG. 2 illustrates an articulation joint, according to an exemplary embodiment of the invention;

(4) FIG. 3 illustrates a plan view of one embodiment of an articulation link, in accordance with the disclosed technology;

(5) FIG. 4 illustrates a bent articulation joint, according to an exemplary embodiment of the invention;

(6) FIG. 5 illustrates another embodiment of an articulation joint, according to an exemplary embodiment of the invention;

(7) FIG. 6 illustrates another articulation joint, according to an exemplary embodiment of the invention;

(8) FIG. 7 illustrates a plan view of a link of an articulation joint having no support member, according to an exemplary embodiment of the invention; and

(9) FIG. 8 illustrates a plan view of a link of an articulation joint having an eccentric center channel, according to an exemplary embodiment of the invention.

DESCRIPTION OF THE EMBODIMENTS

(10) Reference will now be made to exemplary embodiments of the invention, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.

(11) FIG. 1 depicts a device 2, according to an exemplary embodiment. Device 2 can include a medical device configured for use with a surgical method, including a therapeutic or diagnostic procedure. Device 2 can include an endoscope, a guide tube, a catheter, a guidewire, or other type of elongate medical device. In some embodiments, device 2 can include a flexible instrument, such as, for example, a grasper, a dissector, scissors, a stapler, an electrosurgical device, or other type of endoscopic or laparoscopic instrument. Further, device 2 may be used for procedures within or adjacent to various body organs, such as, an esophagus, a heart, a stomach, a pelvic area, a bladder, an intestine, or a gastrointestinal, urinary, or pulmonary tract.

(12) Device 2 may be configured for insertion into a patient's body through an anatomical opening. In other embodiments, device 2 may be used in natural orifice transluminal endoscopic surgery (NOTES) procedures or single incision laparoscopic surgical (SILS) procedures. Accordingly, device 2 can be shaped and sized for placement into a patient via a body cavity or an incision.

(13) Device 2 can be configured to operate with one or more instruments (not shown) used in various surgical procedures. For example, device 2 can include one or more lumens (not shown) configured to receive a grasper, a pair of scissors, a hook, an ablation device, or other type of surgical instrument. Device 2 may also be configured to operate with, or include, insufflation, irrigation, suction, imaging, or systems used in endoscopic, laparoscopic, or other surgical procedures.

(14) Device 2 can include a shaft 4 having a proximal end 6 and a distal end 8. Proximal end 6 can be manipulated by an operator to control distal end 8. For example, proximal end 6 can include one or more knobs, dials, levers, triggers, handles, or other devices (not shown) configured to move distal end 8 relative to proximal end 6.

(15) Shaft 4 can also include an articulating portion 9. As shown in FIG. 1, articulating portion 9 can be located at or near distal end 8. In other embodiments, articulating portion 9 can be located anywhere along shaft 4, or encompass the entire length of shaft 4. In operation, an operator can manipulate articulation portion 9 to move distal end 8 up, down, left, or right. As indicated above, the disclosed technology relates to improvements in an articulation joint for a steerable medical device.

(16) According to some exemplary embodiments, articulation portion 9 can be configured to provide axial stiffness based on one or more structures located generally at or about a central region of articulation portion 9. For example, a central part of articulation portion 9 can be configured to provide most of the axial stiffness of articulation portion 9 while an outer part of articulation portion 9 may provide less axial stiffness than that provided by the central part of articulation portion 9. For example, as described below and shown in FIG. 7, a bending member 225 may be configured to provide more axial stiffness than the axial stiffness provided by a cover 220. An axially stiff center may not add significant bending stress to articulation portion 9, permitting lower bending stiffness.

(17) As described below in more detail, a central part of articulation portion 9 may be configured to provide a major part of the load bearing for an articulation mechanism under tension. In addition to providing at least the majority of compressive load bearing, the central part may also provide a pivoting axis for articulation portion 9. Articulation portion 9 may also include an outer part that provides little or no compression strength. Accordingly, the outer part may be formed from low cost, low durometer plastic, or low durometer braid. Various embodiments of articulation portion 9 are described as follows.

(18) FIG. 2 illustrates an articulation joint 10 in accordance with one embodiment of the disclosed technology. Articulation joint 10 can include a number of articulation links 12, 14, 16, 18. Each articulation link can include an elongate body 20 having a first lumen 23 (see FIG. 3) that can be configured to receive a bending member 125. Elongate body 20 can be cylindrical or another shape, and may include a longitudinal axis 19 extending along the length of elongate body 20.

(19) Bending member 125 can be configured to flex to permit relative movement between articulation links 12-18. For example, bending member 125 can include a spring 34 (see FIG. 2), an elastomeric rod 127 (see FIG. 4), or another type of elastic member that may be located within first lumen 23. In some embodiments, spring 34 may be tightly wound or more loosely wound depending on the desired stiffness, looseness, or compressibility of articulation joint 10. To retain bending member 125 in articulation links 12-18, one or more elongate bodies 20 may be fixedly coupled to bending member 125. For example, a proximal-most or a distal-most elongate body 20 can be fixedly attached to bending member 125 by a friction fit, crimping, welding, adhesive, or another joining method.

(20) As shown in FIGS. 2 and 3, elongate body 20 can also include a distal end 40, a proximal end 42, and an outer surface 44. As explained below, distal end 40 of articulation link 14 may be configured to moveably engage proximal end 42 of a proximally-located adjacent articulation link 12. This relative movement can permit selective bending of articulating portion 9.

(21) As shown in FIGS. 2 and 3, each articulation link 12-18 can also include two or more arms 22a, 22b, 22c and 22d that may extend radially outwards from elongate body 20. Specifically, arm 22 may extend outwards from an outer surface 44 of elongate body 20. In the embodiments shown herein, each articulation link 12-18 has four radially extending arms 22a-22d equally spaced about elongate body 20. However, it will be appreciated that a greater or lesser number of arms 22a-22d, and unequal arm spacing, could be used. For example, some articulation links 12-18 may include two arms 22 while others may have three or more arms 22.

(22) As shown in FIG. 3, each of the outer ends of the arms 22a-22d can include, respectively, a second lumen 24a-24d. Second lumen 24 can also be located anywhere along arm 22. Further, second lumens 24a-24d can be aligned generally parallel to longitudinal axis 19 of elongate body 20. Moreover, each second lumen 24a-24d of articulation link 12 may be in longitudinal alignment with corresponding second lumens 24a-24d of other articulation links 14-18. Because second lumen 24 can be configured to receive a control member 30, aligning second lumens 24a-24d along common longitudinal axes allows for placement of control members 30a-30d through the commonly aligned second lumens 24a-24d. The second lumens 24a-24d may be positioned away from the pivoting axis.

(23) As shown in FIG. 2, a single control member 30 can be positioned within a plurality of corresponding second lumens 24a-24d located on a plurality of articulation links 12-18. Each set of corresponding second lumens 24a-24d, stacked longitudinally and aligned on a common longitudinal axis, can receive a common control member 30a-30d. For example, control member 30a can pass through a plurality of second lumens 24a, wherein each second lumen 24a is generally aligned along a common longitudinal axis 31a. Similarly, control member 30b can pass through corresponding second lumens 24b on at least articulation links 12-18, wherein each second lumen 24b is generally aligned along a common longitudinal axis 31b.

(24) Longitudinal axes 31a and 31b can be parallel and laterally displaced from each other or from longitudinal axis 19. Thus, when articulation joint 10 is in a generally straight configuration, control members 30a-d can be generally parallel to each other. As such, control members 30a-d can have longitudinal axes 31a-d that are generally parallel to and laterally displaced from each other.

(25) In operation, a single control member 30 can pass freely through one or more articulation links 12-18 to selectively move articulation joint 10. One or more control members 30 may extend through shaft 4 and terminate at a distal region of shaft 4, for example, at a most distal link. In some embodiments, a handle, lever, dial, or control knob can be moved to selectively tension one or more control members 30 to steer distal end 8 of shaft 4 in a desired direction.

(26) Control member 30 can include a wire, a cable, a ribbon, a rod, or any suitable elongate member. Control member 30 can include a distal end, a stop, a loop, or other mechanism that secures it to a distal-most or a proximal-most articulation link so that it does not pull through articulation links 12-18. It is also contemplated that at least part of control member 30 can include an outer sheath and an inner core wire. In some embodiments, the outer sheath can be sized to frictionally engage second lumen 24 of articulation link 12, a distal-most articulation link, or a proximal-most articulation link.

(27) In the embodiment shown in FIGS. 2 and 3, a support member 26 extends generally around the outer ends of the arms 22a-22d. Support member 26 may be configured to provide rigidity to one or more arms 22, such as, for example, torsional rigidity. Also, support member 26 may extend between two or more arms 22 and may be any suitable shape, such as, for example, a radial hoop. In some embodiments, support member 26 may include a straight member or may extend generally from a mid-point of one or more arms 22.

(28) As shown in FIG. 3, articulation link 12 can include a number of spaces 28a-28d in the areas between arms 22a-22d. A tube, shaft, wire, or other component of a medical instrument could be routed through spaces 28a-28d. It is also contemplated that a working channel or other elongate structure could be routed through the center of first lumen 23 within bending member 125. For example, one or more flexible endoscopic instruments could be passed through lumen 23 and/or spaces 28a-28d.

(29) To permit movement of articulation joint 10, articulation links 12-18 may include one or more contact surfaces configured to permit relative movement between articulation links 12-18. A contact surface may also be configured to reduce or prevent adjacent articulation links 12-18 from rotating about longitudinal axis 19 with respect to each other while allowing deflection from longitudinal axis 19. For example, FIG. 4 shows a bent articulation joint 10 deviating from longitudinal axis 19.

(30) In one embodiment, a contact surface can include a concave or a convex surface. As shown in FIG. 4, articulation link 14 can include one or more convex surfaces 32 located at proximal end 42 of elongate body 20 that fit within corresponding one or more concave surfaces 34 located at distal end 43 of articulation link 12. Articulation link 14 can also include a second contact surface 38 located at the distal end 40 of elongate body 20.

(31) In the embodiment shown in FIG. 4, contact surface 32 and contact surface 38 at each end of elongate body 20 are offset and rotated about the longitudinal axis by 90 with respect to each other. Such an offset of contact surfaces permits adjacent articulation links to pivot in different directions relative to each other, wherein each direction is offset by 90 relative to the other. This allows, for example, left-right and up-down movement of articulation joint 10. Other embodiments can include no offset or a different angle of offset.

(32) In other embodiments, articulation link 12 can include one or more pivoting surfaces (not shown). Pivoting surfaces can include a joint or a hinge configured to allow pivoting between adjacent articulation links. Other types of couplings between articulation links 12-18 are also possible. For example, contact surfaces can include a ball and socket type coupling, whereby the ball contact surface of an articulation link couples with corresponding socket contact surface on an adjacent articulation link.

(33) In contrast to the embodiments shown above, the adjacent articulation links shown in FIG. 5 are joined by a flexible section 370. In particular, an articulation joint 350 has a number of articulation links 352-358. As shown, each articulation link 352-358 includes an elongate body 360, a spring 365 extending therethrough, and a number of radial arms with lumens for receiving a control member, as previously described. Flexible section 370 can include a living hinge formed using a plastic material. In some embodiments, a V-shaped notch may provide sufficient flexibility to operate as a hinge-like device. For example cutouts 372 and 374 located on either side of flexible section 370 can define the extent of bending that can occur between adjacent articulation links. Adjacent flexible sections 370 can also be alternating in their alignment and offset by 90, as shown.

(34) FIG. 6 illustrates another alternative embodiment of an articulation joint 210. Specifically, articulation joint 210 includes a number of articulation links 202, 204, and 206 that are physically separated along a longitudinal axis 219. Separating articulation links 202-206 can permit greater flexibility of articulation joint 210, reduce wear to articulation links 202-206, or simplify manufacture of articulation joint 210.

(35) FIGS. 6 and 7 show an elongate body 215 having a first lumen 223 extending therethrough and surrounding bending member 225. Articulation link 202 can also include various numbers of arms 212. As shown in FIG. 7, articulation link 202 includes four arms 212a-212d extending radially outward from an outer surface 244 of elongate body 215. The outer ends of arms 212a-212d include second lumens 224a-224d configured to receive control members 230a-230d. As previously explained, although FIGS. 6 and 7 show four radially extending arms 212a-212d, a lesser or greater number of arms could be included depending, for example, upon the number of control members 230a-d.

(36) In contrast to the embodiments shown above, articulation links 202-206 do not include any support structure connecting two or more arms 212a-212d. Cover 220 can extend about one or more articulation links 202-206. As described above, the spaces between arms 212a-212d and cover 220 may define a number of spaces 228a-228d. Cover 220 may aid in transmitting torque along the length of articulation joint 210 or form a protective outer surface of articulation joint 210. Cover 220 may include a braid, a wire, a mesh, or other material that may aid in transmitting torque along articulation joint 210.

(37) FIG. 8 is a cross-sectional view of a single articulation link 112, according to another exemplary embodiment. As shown, articulation link 112 can include an elongate body 120 having a first lumen 123 and a number of radially extending arms 122a-122d, wherein each arm can include a second lumen 124a-124d. As explained above, control members (not shown) can be passed through one or more second lumens 124a-124d and support member 126 may link the outer ends of the arms 122a-122d.

(38) In the embodiment shown, elongate body 120 and lumen 123 are asymmetrically located from the center of articulation link 112. That is, elongate body and lumen 123 are centered on a longitudinal axis that is offset with respect to the central longitudinal axis of articulation link 112. This can permit preferential bending in a single direction of an articulation joint formed from such articulation links 112. In the embodiment shown in FIG. 8, articulation link 112 can bend more easily in the direction of arm 122d due to the greater length of the arm 122d with respect to the remaining arms 122a-122c.

(39) The embodiments described herein are exemplary only, and it will be apparent to those skilled in the art that various modifications and variations can be made in the disclosed systems and processes without departing from the scope of the invention. Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. It is intended that the specification and examples be considered as exemplary only, with a true scope of the invention being indicated by the following claims.