This application is a continuation of U.S. application Ser. No. 11/871,104, filed Oct. 11, 2007, which is incorporated herein by reference. All publications and patent applications mentioned in this specification are incorporated herein, in their entirety, by reference to the same extent as if each individual publication or patent application was specifically and individually indicated to be incorporated by reference.
FIELD OF THE INVENTION The present invention relates, generally, to management of Bowden-type cables in articulating instruments or snake-like robots. More particularly, the present invention relates to managing Bowden-type cables to reduce or eliminate catastrophic permanent lateral plastic deformation (also referred to herein as kinking or herniation) of these cables in articulating instruments or snake-like robots.
BACKGROUND OF THE INVENTION The forms of robots vary widely, but all robots share the features of a mechanical, movable structure under some form of control. The mechanical structure or kinematic chain (analogous to the human skeleton) of a robot is formed from several links (analogous to human bones), actuators (analogous to human muscle) and joints permitting one or more degrees of freedom of motion of the links. A continuum or multi-segment robot is a continuously curving device, like an elephant trunk for example. An example of a continuum or multi-segment robot is a snake-like endoscopic device, like that under investigation by NeoGuide Systems, Inc., and described in U.S. Pat. Nos. 6,468,203; 6,610,007; 6,800,056; 6,974,411; 6,984,203; 6,837,846; and 6,858,005. Another example of a snake-like robotic device is shown and described in U.S. Patent Publication US2005/0059960 to Simaan, et al.
Snake-like robots often use Bowden cables to transfer forces from an actuator to particular sections or segments of the snake-like robot to effect articulation of that section or segment. Multiple, simultaneous articulations of the snake-like robot require the Bowden cables to go through multiple tortuous paths. One challenge faced by the practitioner is that Bowden cables can herniate under overloading conditions and axial loads placed upon them as a result of articulation. Various embodiments of the present invention address this issue.
SUMMARY OF THE INVENTION An embodiment of the present invention is a system for managing the transmission of force to articulate an elongate device or snake-like robot. The system, of this embodiment, has an elongate body comprising a plurality of articulatable segments. The system includes a plurality of coil pipes, where each coil pipe is fixed at its proximal end relative to an actuator, at its distal end relative to a proximal portion of one of the plurality of articulatable segments, and where the coil pipes extend along each segment in a spiral pattern. A plurality of tensioning members is provided, where the tensioning members are housed in the plurality of coil pipes. The proximal end of each tensioning member is coupled to the actuator, and the distal end extends out the distal end of the coil pipe and is coupled to the articulatable segment to which the distal end of the coil pipe is fixed. The coil pipe/tensioning member combination works like a Bowden cable. The tensioning of one or more of the tensioning members causes articulation of the articulatable segment. In an alternative embodiment of the present invention, the articulatable segments are constructed from at least two links and preferably at least four links jointed together. Preferably, the links are control rings, such as and without limitation vertebrae, and the joints are hinges between the vertebrae. In an alternative embodiment the spiral pattern comprises an approximate integral number of approximately full turns along each of the plurality of articulatable segments, and preferably approximately one full turn.
In an alternative system for managing the transmission of force in an articulating device, the system comprises an elongate body have a plurality of articulatable segments. Bowden cables are coupled at a proximal end to an actuator and at a distal end to a proximal portion of one of the articulatable segments. Actuation of one or more of the Bowden cables causes the articulation of one or more of the segments to which the Bowden cables are coupled. The Bowden cables extend along each segment in a spiral pattern.
In another embodiment coil pipes are constructed from approximately round wire, D-shaped wire or are centerless ground. A D-shaped coil pipe that is less susceptible to herniation or axial overloading, in accordance with an embodiment of the present invention, can comprise D-shaped wire coiled, around a mandrel, for example, into a pipe shape. The wire used to make this embodiment of coil pipe has a cross-section having two approximately parallel approximately flat sides, a convex side and a concave side approximately parallel to said convex side. Preferably, the concave side of the wire of a first coil approximately nests with the convex side of the wire in a second adjacent coil, and the approximately parallel flat sides form an interior and an exterior of the coil pipe. The convex and concave sides can have an approximately curved shape, such as and without limitation a portion of a circle. Alternatively, the convex and concave sides can have an angular shape, such as and without limitation a V-shape. Alternatively, the wire can have a square or rectangular cross-section. A coil pipe can also comprise approximately circular cross-section wire coiled, around a mandrel for example, into a pipe shape. In a further embodiment of the present invention the pipe shape is ground or otherwise has material removed to form approximately parallel exterior flat sides, thereby forming a centerless ground coil pipe.
BRIEF DESCRIPTION OF THE DRAWINGS The novel features of the invention are set forth with particularity in the claims that follow. A better understanding of the features and advantages of the present invention will be obtained by reference to the detailed description below that sets forth illustrative embodiments, in which the principles of the invention are utilized, and the accompanying drawings.
In the drawings:
FIG. 1 depicts an endoscope in accordance with an embodiment of the present invention;
FIG. 2 depicts an embodiment of a steerable distal portion or a controllable segment of an endoscope in accordance with the present invention;
FIGS. 3A through 3C depict a schematic diagram of either a steerable distal portion or a controllable segment of an endoscope in accordance with the present invention;
FIGS. 4A through 4F depict embodiments of vertebrae-type control rings in accordance with an embodiment of the present invention;
FIG. 5 depicts a schematic of how to arrange coil pipes and tendons relative to actuators and an articulatable segment or tip;
FIG. 6 provides a graphic for explaining static radial frictional forces between tendons and coil pipes in an embodiment of the present invention where the coil pipes are not spiraled;
FIGS. 7A and 7B depict a schematic of advancing an endoscope in a colon in accordance with an embodiment of the present invention;
FIG. 8 depicts a schematic of an undesirable bell-shape bend of a coil tube;
FIGS. 9A and 9B depict an embodiment of a coil pipe made with circular cross-section wire and a herniation of the coil pipe;
FIG. 10 depicts a centerless ground coil pipe in accordance with an embodiment of the present invention;
FIGS. 11A through 11F depict a coil pipe made with “D-shaped” wire in accordance with an embodiment of the present invention, and various embodiments of how to make “D-shaped” wire;
FIG. 12 depicts an illustration of coil pipe spiraled along a segment in accordance with an embodiment of the present invention;
FIG. 13 provides a graphic for explaining static radial frictional forces between tendons and coil pipes in an embodiment of the present invention where the coil pipes are spiraled;
FIGS. 14A and 14B provide a schematic for describing one alternative for spiraling of coil pipes along a segment in accordance with an embodiment of the present invention; and
FIGS. 15A and 15B depict an alternative embodiment of a steerable distal portion or a controllable segment.
DETAILED DESCRIPTION OF THE INVENTION FIG. 1 depicts endoscope 10, a colonoscope in particular, in accordance with an embodiment of the present invention. Endoscope 10 has elongate body 12 with steerable distal portion 14, automatically controlled proximal portion 16, and flexible and passively manipulated proximal portion 18. The skilled artisan will appreciate that automatically controlled proximal portion 16 may also be flexible and passively manipulated, although it is preferred to provide automatically controlled proximal portion 16. The skilled artisan will also appreciate that elongate body 12 can have only steerable distal portion 14 and automatically controlled portion 16. Fiber optic imaging bundle 20 and illumination fiber(s) 22 may extend through elongate body 12 to steerable distal portion 14, or video camera 24 (e.g., CCD or CMOS camera) may be positioned at the distal end of steerable distal portion 14, as known by the skilled artisan. As the skilled artisan appreciates, a user views live or delayed video feed from video camera 24 via a video cable (e.g., wire or optical fiber, not shown) or through wireless transmission of the video signal. Typically, as will be appreciated by the skilled artisan, endoscope 10 will also include one or more access lumens, working channels, light channels, air and water channels, vacuum channels, and a host of other well known complements useful for both medical and industrial endoscopy. These channels and other amenities are shown generically as 26, because such channels and amenities are well known and appreciated by the skilled artisan.
Preferably, automatically controlled proximal portion 16 comprises a plurality of segments 28, which are controlled via computer and/or electronic controller 30. Such an automatically controlled endoscope is described in further detail in commonly assigned U.S. patent application Ser. No. 10/229,577 (now U.S. Pat. No. 6,858,005) and Ser. No. 11/750,988 (now U.S. Pat. No. 8,568,299), both previously incorporated herein by reference. Preferably, the distal end of a tendon (more thoroughly described below) is mechanically connected to a each segment 28 or steerable distal portion 14, with the proximal end of the tendon mechanically connected to actuators to articulate segments 28 or steerable distal portion 14, which is more fully described below and in U.S. patent application Ser. No. 10/229,577 (now U.S. Pat. No. 6,858,005) and Ser. No. 11/750,988 (now U.S. Pat. No. 8,568,299), both previously incorporated herein by reference. The actuators driving the tendons may include a variety of different types of mechanisms capable of applying a force to a tendon, e.g., electromechanical motors, pneumatic and hydraulic cylinders, pneumatic and hydraulic motors, solenoids, shape memory alloy wires, electronic rotary actuators or other devices or methods as known in the art. If shape memory alloy wires are used, they are preferably configured into several wire bundles attached at a proximal end of each of the tendons within the controller. Segment articulation may be accomplished by applying energy, e.g., electrical current, electrical voltage, heat, etc., to each of the bundles to actuate a linear motion in the wire bundles which in turn actuate the tendon movement. The linear translation of the actuators within the controller may be configured to move over a relatively short distance to accomplish effective articulation depending upon the desired degree of segment movement and articulation. In addition, the skilled artisan will also appreciate that knobs attached to rack and pinion gearing can be used to actuate the tendons attached to steerable distal portion 14. An axial motion transducer 32 (also called a depth referencing device or datum) may be provided for measuring the axial motion, i.e., the depth change, of elongate body 12 as it is advanced and withdrawn. As elongate body 12 of endoscope 10 slides through axial motion transducer 32, it indicates the axial position of the elongate body 12 with respect to a fixed point of reference. Axial motion transducer 32 is more fully described in U.S. patent application Ser. No. 10/229,577 (now U.S. Pat. No. 6,858,005), previously incorporated herein by reference.
In the embodiment depicted in FIG. 1, handle 34 is connected to illumination source 36 by illumination cable 38 that is connected to or continuous with illumination fibers 22. Handle 34 is connected to electronic controller 30 by way of controller cable 40. Steering controller 42 (e.g., a joy stick) is connected to electronic controller 30 by way of second cable 44 or directly to handle 34. Electronic controller 30 controls the movement of the segmented automatically controlled proximal portion 16, which is described more thoroughly below and in U.S. patent application Ser. No. 11/750,988 (now U.S. Pat. No. 8,568,299), previously incorporated herein by reference.
Referring to FIG. 2, steerable distal portion 14 and segments 28 of automatically controlled proximal portion 16 are preferably constructed from a plurality of links 46. Five links 46 are shown in this example for the sake of clarity, although the skilled artisan will recognize that any number of links may be used, the ultimate number being primarily defined by the purpose for which segments 28 or steerable distal portion 14 will be used. Each link 46 connects one joint (e.g., 47) to an adjacent joint (e.g., 47). Each link 46, in this embodiment, can move with two degrees of freedom relative to an adjacent link.
Referring now to FIG. 3A-C a schematic diagram of either steerable distal portion 14 or segments 28 is provided for discussion purposes and to explain a preferred system and method for articulating steerable distal portion 14 or segments 28. The skilled artisan will recognize that the system and method for articulation is the same for both steerable distal portion 14 and segments 28 of automatically controlled proximal portion 16. Therefore, the system and method for articulation will be described referring only to segments 28, with the recognition that the description also applies equally to steerable distal portion 14. It is noted that details relating to links 46, joints 47 and the interconnections of the links have been eliminated from this figure for the sake of clarity.
FIG. 3A shows a three-dimensional view of segment 28 in its substantially straight configuration. The most distal link 46A and most proximal link 46B are depicted as circles. Bowden cables extend down the length of elongate body 12 (not shown in FIGS. 3A-C) and comprise coil pipes 48 and tendons 50. The proximal end of the Bowden-type cable is coupled to an actuator (not shown) and the distal end is coupled to the segment for which it controls articulation. Coil pipes 48 house tendons 50 (i.e. a Bowden-type cable) along the length of elongate body 12 (not shown in FIGS. 3A-C) and coil pipes 48 are fixed at the proximal end of segment 28. Tendons 50 extend out of coil pipes 48 at the proximal end of segment 28 along the length of segment 28, and are mechanically attached to the distal portion of segment 28. It will be appreciated that the distal end of tendons 50 need only be attached to the segment being articulated by that tendon 50 at a location required to transfer the actuated force to that segment to effect articulation; the distal portion of the segment is provided by way of explanation and example, and not by way of limitation. In the variation depicted in FIG. 3A-C four tendons 50 are depicted to articulate segment 28, but more or fewer may be used. The coil pipe/tendon combination, or Bowden cables, can be used to apply force to articulate segments 28 and can be actuated remotely to deliver forces as desired to articulate segments 28. In this manner, actuation of one or more tendons 50 causes segment 28 to articulate. In the embodiment depicted, links 46 have joints 47 alternating by 90 degrees (see FIGS. 2 and 4). Thus, an assembly of multiple links 46 is able to move in many directions, limited only by the number of actuated joints. As will be appreciated by the skilled artisan, tendons 50 can be made from a variety of materials, which is primarily dictated by the purpose for which the endoscope will be used. Without limitation tendons 50 can be made from stainless steel, titanium, nitinol, ultra high molecular weight polyethylene, the latter of which is preferred, or any other suitable material known to the skilled artisan.
In the variation depicted in FIG. 3A-C, four tendons 50 are used to articulate segment 28, although more or fewer tendons could be used, as will be appreciated by the skilled artisan. Four tendons can reliably articulate segment 28 in many directions. Tendons 50 are attached at the most distal link 46A, for the purposes of this discussion but not by way of limitation, close to the edge spaced equally apart at 12, 3, 6, and 9 O'clock.
FIG. 3B-C show segment 28 articulated by independently pulling or slacking each of the four tendons 50. For example, referring to FIG. 3B, pulling on tendon 50 at the 12 O'clock position and easing tension on tendon 50 at the 6 O'clock position causes steerable distal portion 28 to articulate in the positive y-direction with respect to the z-y-x reference frame 52. It is noted that the most distal z-y-x coordinate frame 52distal rotates with respect to the z-y-x reference frame 52 and that P is the degree of overall articulation of segment 28. In this situation P is only along the positive y-axis, up, because only tendon 50 at the 12 O'clock position was pulled while easing tension or giving slack to tendon 50 at 6 O'clock. The tendons 50 at 3- and 9 O'clock were left substantially static in this example, and, thus, had approximately no or little affect on articulation of segment 28. The reverse situation (not depicted), pulling on tendon 50 at the 6 O'clock position and slacking or easing the tension on tendon 50 at the 12 O'clock position results in articulation of segment 28 in the negative y-direction, or down. Referring to FIG. 3C the same logic applies to articulate segment 28 in the positive x-direction (right) or a negative x-direction (left, not shown). Segment 28 can be articulated in any direction by applying varying tensions to the tendons off axis, e.g., applying tension to the tendons at 12 O'clock and 3 O'clock results in an articulation up and to the left.
Referring now to FIG. 4, links 46 may be control rings to provide the structure needed to construct steerable distal portion 14 and segments 28. FIG. 4A shows a first variation of a vertebra-type control ring 54 that forms segments 28 or steerable distal portion 14. FIG. 4B shows an end view of a single vertebra-type control ring 54 of this first variation. In this embodiment each vertebra-type control ring 54 define a central aperture 56 that collectively form an internal lumen of the device, which internal lumen is used to house the various access lumens, working channels, light channels, air and water channels, vacuum channels, and a host of other well known complements useful for both medical and industrial endoscopy. Vertebrae-type control rings 54 have two pairs of joints or hinges 58A and 58B; the first pair 58A projecting perpendicularly from a first face of the vertebra and a second pair 58B, located 90 degrees around the circumference from the first pair, projecting perpendicularly away from the face of the vertebra on a second face of the vertebra opposite to the first face. Hinges 58A and 58B are tab-shaped, however other shapes may also be used.
Referring briefly to FIG. 5, tension applied to tendon 50 by actuator 60 is isolated to a particular segment 28 by use of coil pipe 48 housing tendon 50, as previously described. Referring back again to FIG. 4A, vertebra-type control ring 54 is shown with four holes 60 through the edge of vertebra-type control ring 54 that may act as, e.g., attachment sites for tendon 50, as a throughway for tendon 50 in other vertebrae-type control rings 54 (links) of that particular segment 28 and/or attachment sites for coil pipes 48 when vertebra-type control ring 54 is the most proximal link in segment 28. The skilled artisan will appreciate that the number of tendons 50 used to articulate each segment 28 or tip 14 determines the number of holes 60 provided for passage of tendons 50.
The outer edge of vertebra-type control ring 54 in the variation depicted in FIG. 4A-B may be scalloped to provide bypass spaces 62 for tendons 50 and coil pipes 48 that control more distal segments 28 or tip 14, and that bypass vertebra-type control ring 54 and the present segment 28. These coil pipe bypass spaces 62, in this variation of the vertebrae-type control ring 54, preferably conform to the outer diameter of coil pipes 48. The number of coil pipe bypass spaces 62 vary depending on the number of tendons, and, therefore, the number of coil pipes needed to articulate all the segments 28 and steerable distal portion 14. It will be appreciated that not all vertebrae-type control rings 54 of a particular segment 28 need to have coil pipe bypass spaces 62. As described further below, intermediate vertebra-type control rings 54′ (FIG. 4C) between segments need not have coil pipe bypass spaces 62, rather the coil pipes can simply pass through the lumen formed by central aperture 56′. In this alternative, the lumen formed by central aperture 56′ house the various access lumens, working channels, light channels, air and water channels, vacuum channels, as described above, as well as coil pipe/tendon combinations that do not control that particular segment.
FIG. 4D-E show another variation of vertebra-type control ring 64 in sectional and perspective views. In FIG. 4D-E, tendons 50 and coil pipes 48 that bypass a segment may be contained within body 66 (FIG. 4D) of vertebra-type control ring 64 in an alternative coil pipe bypassing space or quadrant 68, rather than the scallops 62 along the outer edge of vertebra-type control ring 54 as previously described. Quadrants 68 are the preferred way to handle coil pipes 48 that must by-pass a segment. Vertebra-type control ring 64 of FIG. 4D-4E show four coil pipe bypassing spaces/quadrants 68, but more or fewer may be used. It will be appreciated that cross bar 57 can pivot at hinge points 59 in one embodiment or may fixed relative to body 66. Other aspects of this variation of vertebra-type control ring are similar to that described above and are, accordingly, called out with the same reference number. It is noted that tie-off rods 104 can be used to tie off the distal ends of tendons 50 in this embodiment.
The skilled artisan will appreciate that coil pipes 48 by-passing a vertebrae via quadrants 68 will define an approximately cylindrical coil pipe containment space roughly defined by the outer diameter of vertebrae-type control ring 64. This space is loosely defined by the grouped coil pipes as they pass through and between the vertebrae. As described more thoroughly below, it is possible and preferred to have intermediate vertebra-type control rings without coil pipe bypassing spaces, as shown in vertebra-type control ring 54′ (FIG. 4C) or 65 (FIG. 4F). In either construction, central aperture 56 or 56′ of the control rings collectively forms a lumen (not shown) through which channels and cables necessary or desired for the endoscope function pass, as well as coil pipes and tendons by-passing that particular segment. Preferably, more proximal segments will have larger diameter vertebrae in order to provide larger quadrants 68 or central aperture 56 or 56′ to accommodate a larger number of coil pipes 48 that must reach the more distal segments 28 and tip 14. The more distal segments 28 and steerable distal portion 14 can be constructed with vertebrae-type control rings 64 or 65 having a smaller diameter, thereby making the distal portions of elongate body 12 have a smaller diameter. While this is preferred, the skilled artisan will recognize that any diameter vertebrae may be used limited only by the need to accommodate the coil pipes and tendons necessary to articulate segments 28 and steerable distal portion 14 of the endoscope.
Referring again to FIG. 5, coil pipes 48 are fixed at their distal and proximal ends between actuators 60 and the proximal end of segment 28 under control by those actuators. FIG. 5 shows only one segment 28 (which, as discussed, could also be steerable distal portion 14), and, for clarity, the other parts of a complete endoscope have been omitted from FIG. 5. When tendons 50 are placed under tension, the force is transferred across the length of segment 28; coil pipes 48 provide the opposite force at the proximal end of the segment being articulated in order to cause the articulation. This force is, primarily, a compression force or axial loading transferred along the length of the coil pipe where it is fixed between the actuator and the proximal end of the segment being articulated. A preferred embodiment of the present invention utilizes one actuator per tendon, and utilizes four tendons per segment, as described above, although only one actuator 60 is depicted for clarity. Details relating to actuator 60 and connecting actuator 60 to tendons 50 are described in U.S. patent application Ser. No. 10/988,212, previously incorporated by reference.
The skilled artisan will appreciate that articulation of multiple segments 28 along the length of elongate body 12 will require that many coil pipes 50 extend down the length of elongate body 12 and through coil pipe by-passing spaces, with the number decreasing by four coil pipes (in this example) at the proximal end of each segment. Thus, a 17 segmented elongate body (16 segments 28 and 1 tip 14) requires 68 coil pipes going into the proximal end of elongate body 12, which decreases by four coil pipes for each distally adjacent segment 28 (assuming one uses four tendon/coil pipes combinations per segment as in the present example). It also requires the actuation or tensioning of 68 tendons, with four tendons terminating at the distal end of each segment. This requires 68 actuators in this preferred embodiment, one actuator per tendon 50.
The skilled artisan will also appreciate that there is not a one to one correspondence between the force applied by actuators 60 at the proximal end of tendons 50 and the force realized at the distal end of tendons 50 to articulate segment 28. When elongate body 12 is in its substantially straight configuration, friction between tendons 50 and coil pipes 48 results in frictional losses along the length of the coil pipe while applying tension to articulate a segment or the tip. Articulation of segments 28 and steerable distal portion 14 results in further losses and inefficiencies for many reasons. For example, and without limitation, when elongate body 12 articulates (for example at the Sigmoid colon during a colonoscopy procedure), coil pipes 48 must move longitudinally along elongate body 12 to either “gain” or “lose” length depending whether coil pipes 48 are on the inner or outer portion of the bend created by the articulation. As described above, an embodiment of the present invention provides quadrants 68 or coil pipe by-passing spaces 62 that permit the passage of coil pipes 48 along elongate body 12 until they reach the proximal portion of the segment they control. The “gain” or “loss” of coil pipe length requires coil pipes 48 to slide up and down elongate body 12 and within quadrants 68 or coil pipe by-passing spaces 62 creating further frictional losses by virtue of friction between the coil pipes and/or between the coil pipes and the vertebra. There is also the additional friction created between a coil pipe and a tendon by virtue of the bend.
Frictional losses caused by the coil pipe/tendon bending (by virtue of a segment bending) reduce the working force available to articulate segments. The frictional loss is dependent on the material coefficient of friction and the accumulated bend (total tortuosity) of the coil pipe/tendon as elongate body 12 moves through a tortuous path. Total tortuosity is the amount of accumulated bend along the length of a coil pipe, which is closely approximated by the amount of accumulated bend along the length of that portion of elongate body 12 through which the coil pipe travels. For example an S-bend through the Sigmoid colon would contribute approximately 2.times.90.degree. or 180.degree. to the total tortuosity. As a segment bends coil pipes/tendons within that segment will also bend. The tendon tension applies a normal load towards the center of curvature of the coil pipe, as depicted in FIG. 6 that graphically depicts a coil pipe going through a 180 bend around a column.
Referring to FIG. 6, the static friction for coil pipes extending down the length of elongate body 12 can be represented by the following balanced equations, where θ is the total tortuosity. Delta_F is constant with a given load L on either tendon. Note there are at least three sources of friction: (1) friction between the tendons and the coil pipe; (2) friction between the coil pipes and the ring structures; and (3) friction between the individual coil pipes.
∫−π/2π/2Delta_F*cos(θ)dθ=2*L; (units of Delta_F are in force/angle)
Delta_F*[sin(π/2)−(sin(−π/2))]=2*L;
Delta_F*[1−(−1)]=2*L
Delta_F=L
Having found Delta_F, the general normal cable loading is FN=Delta_F*θ=L*θ. The static radial friction is, therefore, Fr(θ)=FN*μ=Delta_F*θ*μ=L*θ*μ (μ is coefficient of friction). Note that this equation has been solved for an ideal, hypothetical situation where the coil pipe is bent around a hypothetical column and static equal load is place at either end of the tendon going through the coil pipe. The same analysis applies for the static friction between a coil pipe and ring structures of a segment, where L is the given external load on the coil pipe. The solution is the same, but will have different loads (L) and different coefficients of friction (μ). This is a reasonable model to assess the static frictional loads for a coil pipe going through a segment comprised of vertebra-type ring structures having a total tortuosity of θ. Therefore, the static friction force for 180 degrees of accumulated tortuosity (two ninety degree bends or an S-bend, for example) is Fr (π)=π*L*μ. The calculation for brake free forces and dynamic resistance loads is more complicated but can also be solved with an exponentially decaying resistance load.
Additionally, but related, elongate body 12 may enter more than one tortuous bend simultaneously. Referring to FIG. 7A-B, this occurs when, for example and without limitation, performing a colonoscopy with an embodiment of the present invention elongate body 12 must move through a highly tortuous path. Electronic controller 30, in a preferred embodiment, controls the articulation of each segment 28 to take the shape of adjacent segments or tip as elongate body 12 is advanced through a tortuous path, such as the colon. Referring to FIG. 7A, a user articulates steerable distal portion 14 to select a desired path, through the Sigmoid colon S for example (an approximate S-bend or 180 degrees of total tortuosity), and then advances the endoscope through the anus A. Electronic controller 30 knows the shape of segments 28 and steerable distal portion 14 prior to the advancement of elongate body 12 into the colon, as described more thoroughly in U.S. patent application Ser. No. 11/019,963, previously incorporated herein by reference. Electronic controller 30 causes adjacent segments to adopt the shape of the segment or steerable distal portion immediately preceding it. Therefore, upon advancing elongate body 12 through the colon C, electronic motion controller 30 will maintain the approximate tortuous S-shape of the Sigmoid colon S in elongate body 12 by automatically controlling segments 28 to adopt the approximate shape of the immediately preceding segment. This follow-the-leader technique is further described in U.S. patent application Ser. No. 11/019,963, previously incorporated herein by reference. As described above, coil pipes 48 need to slide along elongate body 12 to accommodate the “gain” or “loss” of coil pipe length resulting from the articulation of elongate body 12. Recall from the equation above that the frictional force is proportional to both total tortuosity and the material coefficient of friction. There are two coefficients of friction of interest, one for the tendon against the internal lumen of the coil pipe, and the other for the coil pipe against the vertebra-type ring structures.
Referring to FIG. 7B, when steerable distal portion 14 of elongate body 12 enters into a second tortuous bend, at the splenic flexure F1 of the colon for example, coil pipes 48 need to accommodate the “gain” or “loss” of coil pipe length for both the new bend in the splenic flexure F1 and for the first S-bend at the Sigmoid colon S. As the user advances elongate body 12 into the transverse colon T electronic controller 30 continues to maintain the bends at the splenic flexure F1 and the Sigmoid colon S. However, coil pipes 48 need to slide the entire length of elongate body 12 (as described above), including through the first tortuous proximal bend in the Sigmoid colon S, and the second tortuous more distal bend in the splenic flexure F1 to accommodate for the “loss” and “gain” of coil pipe length.
It was found that coil pipes 48 did not have the ability to slide along the length of elongate body 12 when in such a tortuous state. Without wishing to be bound by any particular theory, the inventors believe that the frictional forces between the coil pipes and the vertebra-type ring structures bind the coil pipes and they are unable to slide along the length of elongate body 12. Referring to FIG. 8, catastrophically the coil pipe exits the coil pipe containment boundary (discussed previously) in a severe bell-curve type shape 70, or adopts severe bends (not shown) within the coil pipe containment boundary. This bell-curve bend 70 and/or other severe bends in coil pipes 48 dramatically increases friction between coil pipes 48 and tendons 50, and also stiffens the segments requiring greater forces to achieve the desired articulation than would otherwise be required without the bell-curve or other severe bends in the coil pipes. As the segments having bell-shape curve 70 and/or other severe bends in coil pipe 48 straighten, the excess coil pipe length is no longer required to accommodate the bend in that particular segment of elongate body 12. Therefore, coil pipe 48 moves back into the coil pipe containment area and/or the other severe bends begin to straighten as the bend in segment 28 begins to straighten, but in doing so coil pipe 48 frequently herniates. The skilled artisan will appreciate that herniation of the coil pipe can be caused by a variety of mechanisms. Moreover, the skilled artisan will appreciate that bell-curve shape 70 or other severe bends can occur anywhere along the length of elongate body 12, and the location of such bends is not limited to the bending segments. A herniation, as will be described more fully below, is a permanent or plastic lateral deformation of the coil pipe. The primary cause of a herniation is believed by the inventors (without wishing to be bound by any particular theory) to be the result of the coil pipes binding (i.e. inability to slide or significantly reduced ability to slide) along the length of elongate body 12.
Referring to FIG. 9, coil pipes 48 are typically made of circular cross-section high tensile strength wire 72 wound in a tight coil to form a hollow pipe-like structure. The larger the tensile strength the more difficult it will be to make the material plastically deform. In a preferred embodiment high tensile 302, 303 or 304 VT SST was specified with a tensile strength greater than about 40,000 PSI. In a herniated coil pipe 48H (FIG. 9B) at least one of the coils 74 is permanently, laterally displaced, thereby significantly decreasing the effective diameter through which tendon 50 may pass. This results in a concomitant catastrophic increase in the frictional losses caused by friction between the coil pipe and the tendon passing therethrough. This lateral displacement also significantly reduces column strength of the coil pipe, thereby significantly reducing the ability to articulate a segment. In addition to significantly reducing the amount of force delivered by tendon 50 to articulate the segment or tip, the additional friction will prematurely wear out tendon 50.
Without wishing to be bound by any particular theory, the inventors believe that the coil pipes rubbing on the vertebrae (or other ring structure) as the coil pipes re-enter the coil pipe containment area or otherwise straighten cause lateral forces on the coil pipes, which cause the coil pipes to resist axial movement or bind leading them to herniate. The inventors further hypothesize, again without wishing to be bound by any particular theory, that the ridges 76 (FIG. 9A) of the coiled wire 72 bump along the vertebrae or ring structure as the coil pipes re-enter the coil pipe containment area or otherwise straighten creating additional forces on the coil pipe structure. This is further exacerbated, again without being bound by any particular theory, by the bell-shaped curve or other severe bends separating the coils similar to the bending of a spring, thereby making the ridges more pronounced.
FIG. 10 depicts an embodiment of centerless ground coil pipe 78 in accordance with an embodiment of the present invention. As described above coil pipes 48 slide along the length of elongate body 12 as segments 28 articulate along a tortuous path. Adding lubricity between coil pipes 48 is, therefore, desired. However, using a lubricant, such as oil or other substance, is not highly desired because, at a minimum, the lubricant wears out making more frequent service of the endoscope necessary. Centerless ground coil pipe 78 is essentially the same as coil pipe 48 described above, but approximately half the diameter of coil wire 72 (shown in shadow) on either side of centerless ground coil pipe 78 is ground away or removed to create the centerless ground coil pipe 78. The opposing flat sides 80 provide increased lubricity between coil pipes as they slide up and down elongate body 12, and also provide increased lubricity as “excess” coil pipe length slides back into the coil pipe containment area or otherwise straightens. The skilled artisan will appreciate that any appropriate lubricant may also be used in combination with the centerless ground coil pipes, although this is not preferred. The inventors found that this solution did not sufficiently resolve the binding and ultimate herniation of the coil pipes. The inventors hypothesize that the design is sound, but the less preferred outcome of the solution resulted from the difficulty in reliably manufacturing centerless ground coil pipes with substantially opposing substantially flat sides.
In accordance with an alternative embodiment of the present invention FIG. 11A depicts D-shaped coil pipe 82 made from D-shaped wire 84. In this embodiment convex portion 90 of D-shaped wire approximately nests in concave portion 92 of D-shaped wire (FIG. 11A). D-shaped wire 84 can be manufactured in a number of ways as will be appreciated by the skilled artisan. In one embodiment, referring to FIG. 11B, round wire 72 is rolled by first roller 91 or “Turkshead die” into an approximate oval shape 93 and the wire is rotated approximately 90 degrees and fed into second roller 94 or “Turkshead die.” Second roller 94 creates the concave shape 92 and convex shape 90 at opposite ends of the parallel substantially flat sides 86 created by first roller 91. Alternatively, D-shaped wire can be formed by extrusion or by pulling a fully annealed or soft wire through one or more dies as shown in FIG. 11C. First, wire 72 is pulled through die 92 to obtain an approximately oval shaped wire 96. Oval shaped wire 96 is then pulled through die 98 to provide the concave shape 92 and convex shape 90 at opposite ends of the parallel substantially flat sides 86. The wire is then hardened to hold a set shape as in a coil pipe. The skilled artisan will appreciate that dies 95 and 98 can be a single die and that orientation of the die or rotation of the wire is a matter of manufacturing choice. This would also be true with the orientation of first and second rollers discussed above.
Manufacture of D-shaped coil pipe 82 with D-shaped wire is similar to the manufacture of coil pipe made with circular wire. Referring to FIG. 11D, the main difference is that D-shaped wire 84 needs to be oriented with one of the flat sides 86 against mandrel 88. Preferably, the convex portion 90 of the “D” approximately nests into the concave portion 92 of the “D” as the D-shaped wire is wound onto the mandrel to form the coil pipe.
Nesting convex portion 90 into concave portion 92 provides for a higher surface area contact between wires of each coil than a coil pipe manufactured with circular cross section wire, particularly when the coil pipe is under compressive stresses. Additionally, the sides of convex portion 90 and concave portion 92 provide resistance against herniation upon application of lateral forces. Like the centerless ground coil pipe 78, D-shaped coil pipe 82 also provides increased lubricity by virtue of substantially flat portions 86 of D-shaped coil pipe 82. D-shaped coil pipe 82 worked better than centerless ground coil pipe 78 in preventing herniations, and is therefore more preferred over centerless ground coil pipe 78. Additionally, the manufacturability of D-shaped coil pipe 82 is more consistent than that of the centerless ground coil pipe 78, which adds to the preference of D-shaped coil pipe 82. Furthermore, orienting coil pipe 48 to grind off or flatten the sides to achieve centerless ground coil pipe 78 can prove challenging, as discussed above. The skilled artisan will appreciate that shapes of wire other than D-shaped may be used in accordance with the present invention. For example the concave and convex portion of D-shaped coil pipe 82 may have any geometrical shape that can nest together. These may include, without limitation, V-shaped coil pipe 94 (FIG. 11E). Furthermore, an alternative embodiment, though not preferred, could be square or rectangular cross-section wire oriented to have flat sides against each other, as shown in FIG. 11F, which also will provide resistance against herniation upon application of lateral forces. Additionally, a benefit of using Bowden-type cables made from coil pipes is that they are flexible even when under compressive load. D-shaped coil pipes also remain very flexible under high compressive loads.
FIG. 12 depicts a preferred alternative embodiment for managing the coil pipes that reduces or eliminates the herniation problem by reducing or eliminating the need for the coil pipes to slide along the entire length of elongate body 12. As described above, coil pipe 48 must slide up or down the entire length of elongate body 12 to accommodate a bend in a segment. Referring to FIG. 12, spiraling coil pipes 48 along elongate body 12 and segments 28 significantly reduces and effectively eliminates the herniation problems identified above. Without wishing to be bound by any particular theory, the inventors hypothesize that the spiraled coil pipe localizes the movement or slacking of the coil pipes to an area at or close to the segment undergoing articulation. Therefore, again without wishing to be bound by any particular theory, when a segment articulates the spiraled coil pipe moves within or near a segment locally, thereby reducing or eliminating the need for the coil pipe to slide up or down the entire length of the elongate body. An analogy, again without wishing to be bound by any particular theory, would be a rope or cable made of spiraled strands bending over a pulley; the gain and loss of length of the individual strands in the rope takes place locally at the point of the bend around the pulley, because the strands alternate from the outside to the inside of the bend; the inside strand section gives what the outside strand needs.
The inventors observed that the spiraled coil pipes did not exit the coil pipe containment area in bell shaped curves or exhibit other extreme bends as described above, and they observed little to no herniation of the coil pipes. Spiraling the coil pipes will reduce or prevent herniation with D-Shaped, centerless ground or circular wire coil pipes as well. However, circular wire coil pipes are preferred for ease of manufacturing reasons.
The main benefit with using a spiraled structure identified by the inventors is reduced friction between a coil pipe and vertebra-type ring structures by virtue of the elimination or reduction of sliding of the coil pipes along the elongate body. There is a relatively smaller increase of frictional forces resulting from the increase of overall length of coil pipe through which a tendon must pass, and an increase of overall tortuosity as a result of spiraling the coil pipes along elongate body 12.
The static friction from a spiral loading differs from that of radial loading described above. Tendon tension, as described for radial loading, applies a normal load toward the center of curvature and results in static radial friction of Fr(¶)=¶*L*μ for 180 degrees of total tortuosity. Static radial loading for a spiraled coil pipe can be solved and calculated in the same fashion. It is noted that because, as hypothesized by the inventors, spiraling localizes coil pipe movement to a segment undergoing a bend friction for coil pipes sliding against vertebra-type ring structures is reduced or eliminated. Referring to FIG. 13, cable load L is assumed to be the same at both ends of the spiral. Balanced equations follow, where γ is the spiral angle and θ is, again, total tortuosity, which as noted is increased by virtue of the spiral:
∫−π/2π/2Delta_F*cos(θ)dθ=2*L*sin(γ); units of Delta_F are in force/angle
Delta_F*[sin(π/2)−(sin(−π/2))]=2*L*sin(γ);
Delta_F*[1−(−1)]=2*L**sin(γ)
Delta_F=L*sin(γ)
Having found Delta_F the general normal cable loading is FN=Delta_F*θ*sin(γ)=L*θ*sin(γ). The static radial friction is, therefore, Fr(θ)=FN*μ=Delta_F*θ*sin(γ)*μ=μ*L*θ*sin(γ). Note that this equation has been solved for an ideal, hypothetical situation where the coil pipe is spiraled around a hypothetical column 180° and static equal load is place at either end of the tendon going through the coil pipe. This is a reasonable model to assess the static frictional loads for a coil pipe spiraling through a segment comprised of vertebra-type ring structures. It must be recalled, however, that total tortuosity is now increased as a result of the spiraling.
Total tortuosity is the sum of all angles of bends in a coil pipe from its proximal end assuming the coil pipes are not spiraled along the elongate body. However, as will be appreciated, the spiral angle γ adds to the total tortuosity, but under larger (high degree of) bends of a segment the amount of tortuosity added by for small spiral angles (γ) is approximately the same as that of a non-spiraled embodiment undergoing the same multiple bends, so long as the spiraling is not excessive. Excessive spiraling with large spiral angle γ or wrapping the coil pipe too many times around a segment has a deleterious affect for several reasons. One reason is that the increased number of wraps dramatically increases the length of the coil pipe, thereby increasing the friction between the coil pipe and the tendon. More importantly, the overall tortuosity θ increases to an unacceptable level with the increased number of wraps (which proportionally increases the static friction) and spiral angle, i.e., friction added (Fr≈μ*L*·θ*sin(γ)) increases directly with spiral angle. The inventors reasoned that too much spiraling would result in the detriment of increased friction by virtue of the increase of total tortuosity (θ) out weighing the benefit of reducing or eliminating binding. Numerically the inventors determined that a single 360 degree spiral, or approximately one wrap along each segment is the preferred amount of spiraling. It was determined empirically and numerically that approximately one 360 degree spiral wrap per segment of approximately 10 cm along the elongate body reduced or eliminated the need for the coil pipe to slide between segments to accommodate a bend, thereby reducing or eliminating herniation, and that this benefit far outweighed any increase of friction resulting from the amount of tortuosity added by the spiraled coil pipes. It was also determined numerically that an integral number of spiral wraps was preferred to ensure localization of coil pipe movement during the bending of a segment. The skilled artisan will appreciate the amount of spiraling or wraps used will depend on the system and the purpose for which the system will be used. It will also be appreciated that the spiral angle (γ) need not be constant along the length of a segment.
Referring back to FIG. 4D-F, in an embodiment of the present invention, quadrants 68 of vertebrae type control ring 64 are used to maintain coil pipes 48 spiraled along elongate body 12. In this embodiment more than one vertebra-type control ring 64 in a segment has quadrants 68, and the coil pipes are passed through the quadrants to established the preferred approximately one spiral wrap per segment. In another preferred embodiment, referring briefly to FIG. 15A, distal (not shown) and proximal vertebrae-type control rings 64 of each segment have quadrants 68, and intermediate vertebrae-type control rings 65 do not have quadrants 68. In this preferred embodiment the quadrants are approximately longitudinally aligned, and coil pipes are passed through the aligned quadrants after spiraling within the intermediate control rings 65 to achieve the preferred approximately one spiral wrap. It will be appreciated that the number of coil pipes passing through the quadrants will be equally divided between the quadrants, although other configurations can be used. The skilled artisan will appreciate that many different configurations and mechanisms may be used to maintain the spiral along the length of elongate body 12.
Referring to FIG. 14, coil pipes 48 are routed through quadrants 68 (not shown) in proximal vertebra-type control ring 64 in segment 28, through vertebra-type control rings 65 without quadrants in that segment, through quadrants 68 (not shown) in distal vertebra-type control ring 64 in that segment. The working channel, fiber optics cable, suction channel, video cable and the like (not shown) are routed through central opening 56 of vertebra-type control rings 64 and through the lumen (along with the coil pipes) created by intermediate vertebra-type control rings 65 without quadrants. The vertebrae 64 with the quadrants are then rotated relative to each other to achieve the amount of desired spiraling of the coil pipes, the rotation being depicted graphically in FIG. 148. Hinging of the vertebrae will maintain the spiral, as will be appreciated by the skilled artisan. As noted, approximately a full spiral wrap of 2n per segment 28 is preferred, but the skilled artisan will appreciate that the number of wraps will depend on the purpose for which the device will be used. As will also be appreciated, only four coil pipes are depicted with the other details of the segments and endoscope being omitted from FIG. 14 for purposes of clarity. It is noted that the skilled artisan will appreciate many different configurations of vertebra-type control rings with and without quadrants can be used to achieve the desired spiraling.
As noted, at least one vertebra control ring 64 with quadrants 68 is used per segment and preferably two to maintain the preferred spiral structure of the coil pipes by-passing that segment, and that the remaining vertebra-type control rings of that segment do not have quadrants. As discussed above, central opening 56 of vertebra-type control ring 64 provides a location for passing working channels, optical cables and the like through vertebra-type control ring 64 and quadrants 68 provide a separate by-pass space for coil pipes not controlling articulation of that particular segment, and for maintaining the spiral structure of the coil pipes. The remaining control rings 65 of a segment have no by-pass space. Rather, the coil pipes, the working channel, air line, water line, suction line, optical cables and the like all pass through the central lumen created by central opening 56′ (FIG. 4F) of vertebra-type control rings 65 by aligning vertebra-type control rings 65, and are not separated by quadrants 68 as in vertebra-type control rings 64.
Referring again to FIG. 15, tendons 50 controlling a particular segment are kept separate from the spiraled coil pipes, the working channel, air line, water line etc. by intermediate ring structures 100 attached at the hinge between control rings 65 not having quadrants 68. These intermediate ring structures 100 (FIG. 15B) are situated between vertebra control rings 65. Four holes 102 are shown in ring structure 100 through which tendons 50 controlling articulation of that segment run. More holes may be used per tendon depending on how force is applied to the segment via the tendon(s), and the total number of holes depends on the number of tendons 50 used to control the segment, tour in this example. In the proximal vertebra-type control ring 64 having quadrants 68, holes 60 are where coil pipes controlling that segment terminate and are fixed. As described above, tendon 50 extends out of the coil pipe and along the segment through holes 100 and then terminate at the distal end of the segment at tie off rods 104 of the distal vertebra-type control ring 64. The skilled artisan will recognize that tendon 50 controlling a particular segment need only terminate somewhere within that segment such that force can be effectively transferred to and along that segment to effect articulation.
This preferred embodiment has the advantage of, at least, (1) spiraling the coil pipes along the length of the elongate body, as described above, and (2) providing relatively unconstrained space in vertebra-type control rings 65 without quadrants 68 intermediate to vertebra-type control rings 64 having quadrants 68, such that coil pipes can move locally and relatively unconstrained to accommodate articulation of that particular segment. The inventors believe, again without wishing to be bound by any particular theory, that this permits the coil pipes to move locally and accommodate the bend in a segment without having to slide the entire length of the elongate body, thereby not binding the coil pipes and the concomitant reduction or elimination of herniations in the coil pipes.
The skilled artisan will appreciate there are many different ring structures and many different ways to achieve the desired spiral structure of coil pipes. For example, and without limitation, the coil pipes could be spirally arranged in scalloped by-pass spaces 62 in the outer edge of vertebra-type control ring 60 (FIG. 4A-B), although this is less desirable because it moves the coil pipes further away from the desired longitudinal centerline of elongate body 12, and these spaces have more friction than when the coil pipes are passed through quadrants 68 or the center 65 of vertebrae. Additionally, the skilled artisan will appreciate that quadrants 68 can exist in more than one vertebra-type control ring 64 within a segment, and that more or fewer than four quadrants can be used. The skilled artisan will appreciate how to orient quadrants on one vertebra relative those on an other vertebra(e) having quadrants within a segment and along the elongate body to achieve the desired spiral arrangement of coil pipes.
The foregoing description, for purposes of explanation, used some specific nomenclature to provide a thorough understanding of the invention. Nevertheless, the foregoing descriptions of the preferred embodiments of the present invention are presented for purposes of illustration and description and are not intended to be exhaustive or to limit the invention to the precise forms disclosed; obvious modification and variation are possible in view of the above teachings.
