Embodiments of the present disclosure relate to devices, systems, and methods for treating body tissues, and more particularly for clipping and/or compressing body tissues.
Surgical clips are used during a variety of medical procedures to, for example, hold or clamp tissues together, squeeze blood vessels or other bodily lumens to reduce or prevent bleeding, etc. Clips may be introduced into a patient's body using various approaches, such as a subcutaneous approach, a minimally invasive approach, etc. In a subcutaneous approach, a patient's skin is penetrated to obtain entrance to a target site within the body to deploy a clip over target tissue, (e.g., to close a wound or surgical opening). In one approach, a clip is maneuvered to a target site within the body via an endoscope or other introducer inserted through a body lumen accessed, for example by a natural anatomical opening such as the mouth.
Certain treatments involve the deployment of multiple clips within the body. Many related art systems deliver only one clip at a time. If a second clip is required, the system or delivery instrument must be removed from the body to receive another clip or an entirely new clipping device. This process must be repeated until the desired number of clips has been deployed. As a result, the deployment of multiple clips may be complicated, time consuming, and expensive.
The following implementations may reduce the time and effort required to deploy multiple clips, simplifying the system, and/or performing this process more economically.
The present disclosure is directed to a clipping device, comprising a flexible insertion member extending from a proximal end which, during use remains outside a body accessible to a user to a distal end which is inserted into the body through a naturally occurring body lumen along with a control wire extending through the insertion member from the proximal end and a first clip including first and second jaws, each of the first and second jaws including an opening through which the control wire passes and a collapsible member coupled between the first and second jaws, the collapsible member being biased to urge the first and second jaws away from one another along an axis of the control wire to a first expanded configuration, the first and second jaws being movable against the bias of the collapsible member via the control wire to a second contracted configuration in which the first and second jaws are moved along the axis of the control wire toward one another to lockingly engage tissue received therebetween. The clipping device of claim 1, wherein the first clip further comprises a first locking member coupled to the first jaw and extending from the first jaw toward the second jaw, the first locking member being constructed so that, when the first and second jaws are moved toward one another into the second configuration, the first locking member lockingly engages the first jaw member.
In an embodiment, the first locking member may be formed as a rod extending from the first jaw toward the second jaw.
In an embodiment, a free end of the rod of the first locking member may include a locking arm extending away from the rod at an angle offset from a longitudinal axis of the rod to engage the second jaw.
In an embodiment, a proximal surface of the free end of the locking arm may be angled relative to a surface of the second jaw so that, as the free end of the rod moves proximally into contact with the second jaw, the locking arm deflects until the locking arm passes over the second jaw and locks against a proximal side thereof.
In an embodiment, the first jaw may extend from a first end including a first body engaging the collapsible member to a second end including a first tissue gripping tip.
In an embodiment, the second jaw may extend from a first end including a second body engaging the collapsible member to a second end including a second tissue gripping tip.
In an embodiment, the second end of the second jaw may include a third tissue gripping tip.
In an embodiment, the control wire may include an enlarged distal end engaging distal side of the opening in the first jaw so that proximal movement of the control wire relative to the first jaw draws the first jaw proximally relative to the second jaw, the enlarged end being configured to be movable to a second configuration to permit separation thereof from the first jaw to release the first clip.
In an embodiment, the enlarged distal end of the control wire may engage the opening in the first jaw with a pressure fit.
In an embodiment, the opening in the second jaw may include a rod receiving space and the rod may be lockingly received within the second channel in the second contracted configuration.
In an embodiment, the second and third tissue gripping tips may be separated from one another by an opening, the opening receiving at least a portion of the first jaw therein in the second contracted configuration, the opening includes an angled wall configured to lockingly engage the locking arm of the first locking member.
In an embodiment, the collapsible member may include first and second tabs received within corresponding slots formed in the first and second jaw.
In an embodiment, the device may further comprise a collapsible body portion connecting the first and second tabs, including first and second portions connected to one another at a joint, wherein in the first expanded configuration, the first and second portions are moved apart to enclose a first angle therebetween and wherein, in the second contracted configuration, the first and second arms enclose a second angle smaller than the first angle.
In an embodiment, the second angle may be 0.
In an embodiment, an outer profile of the first clip may be reduced when housed within the flexible insertion member, the outer profile expanding to a biased configuration when the first clip is advanced out of the flexible insertion member.
In an embodiment, the device may further comprise a second clip including third and fourth jaws, each of the third and fourth jaws including an opening through which the control wire passes and a second clip collapsible member coupled between the third and fourth jaws, the second clip collapsible member being biased to urge the third and fourth jaws away from one another along an axis of the control wire to a first expanded configuration, the third and fourth jaws being movable against the bias of the second clip collapsible member via the control wire to a second contracted configuration in which the third and fourth jaws are moved along the axis of the control wire toward one another to lockingly engage tissue received therebetween.
The present disclosure is also directed to a system for clipping tissue, comprising a clip including first and second jaws, each of the first and second jaws including an opening through which a control wire passes and a collapsible member coupled between the first and second jaws, the collapsible member being biased to urge the first and second jaws away from one another along an axis of the control wire to a first expanded configuration, the first and second jaws being movable against the bias of the collapsible member via the control wire to a second contracted configuration in which the first and second jaws are moved along the axis of the control wire toward one another to lockingly engage tissue received therebetween, wherein movement of the control wire causes a corresponding movement of the first jaw relative to the second jaw to move the first and second jaws from the first expanded configuration to the second contracted configuration.
In an embodiment, the control wire may extend through a flexible insertion member from a proximal end actuatable by a user to a distal end connected to the first and second jaws, the control wire including an increased thickness portion at the distal end.
In an embodiment, the first jaw may extend from a first end including a first body engaging the collapsible member to a second end including a first tissue gripping tip and the second jaw extends from a first end including a second body engaging the collapsible member to a second end including second and third tissue gripping tips.
A method for causing hemostasis includes advancing a clip through a flexible insertion member to a target tissue site. The clip includes a first jaw and a second jaw coupled to one another by a collapsible member. Each of the first and second jaws includes an opening through which a control wire passes. The collapsible member is biased to urge the first and second jaws away from one another along an axis of the control wire. The method further includes actuating the control wire to move the first and second jaws out of the insertion member and then drawing tissue into a space between the first and second jaws. The method further includes withdrawing the control wire proximally a first distance to move the first jaw along an axis of the control wire proximally toward the second jaw until a locking element couples the first and second jaws to one another to lockingly engage tissue received therebetween. The method further includes withdrawing the control wire proximally by a second distance to disengage the control wire from the first and second jaws to release the clip from the control wire.
It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure, as claimed.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate exemplary embodiments of the present disclosure and together with the description, serve to explain the principles of the disclosure.
Reference will now be made in detail to embodiments of the present disclosure, 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.
Embodiments of the present disclosure relate to devices, systems, and methods for clipping tissue. The clipping device includes a flexible insertion member that can be inserted into a body along a tortuous path (e.g., through a natural body lumen accessed via a natural body opening, such as the mouth). The flexible insertion member is configured to receive one or more clips therethrough, the clips being configured to engage a portion of body tissue within the body. The exemplary clip includes first and second jaws, each including an opening through which a control wire passes. A collapsible member coupled between the first and second jaws is biased to urge the first and second jaws away from one another along an axis of the control wire to a first expanded configuration. The first and second jaws are moved toward one another against the bias of the collapsible member via the control wire to a second retracted configuration to lockingly engage tissue received therebetween.
Those skilled in the art will recognize that the present disclosure may be manifested in a variety of forms other than the specific embodiments described and contemplated herein. Accordingly, departure in form and detail may be made without departing from the scope and spirit of the present disclosure as described in the appended claims.
The insertion member 102 in this exemplary embodiment is formed of a flexible biocompatible material. For example, the insertion member 102 may be formed of a polymer such as polytetrafluoroethylene (PTFE), polyurethane, and so forth. Other suitable materials such as composites, metals, and so forth may also be used without deviating from the scope of the disclosure.
The clipping device 100 further includes one or more clips 106 housed within the lumen 101. Dimensions of the lumen 101 are selected to facilitate uninterrupted advancement of the clips 106 therethrough and out of a distal opening of the insertion member 102. To this end, the diameter of the lumen 101 is selected to be equal to or slightly larger than a profile of the clip 106.
The clip 106 includes a first jaw 110 and a second jaw 112 coupled to each other via a clip collapsible member 116. The collapsible member 116 includes first and second portions 111 and 113 connected to one another at a joint 109 forming an angle a therebetween. In some embodiments, the collapsible member 116 may be formed of a flexible, resilient material. The collapsible member 116 is biased toward an open position in which the angle a is increased may be moved when subjected to a compressive force to a closed, tissue-receiving position in which the angle a is reduced to bring the first and second jaws 110, 112 toward one another, as will be described in greater detail with respect to the exemplary method below. The first jaw 110 includes a first tissue gripping tip 122. The second jaw 112 includes two tissue gripping tips 124, 126 which form a V-shaped configuration defining an opening 108 therebetween. The second and third tips 124, 126 are configured to permit insertion of the first tip 122 therebetween when the clip 106 is moved to a locked configuration, as will be described in greater detail later on with respect to the exemplary method. The first and second jaws 110, 112 also include openings 114 extending therethrough sized to permit slidable insertion of a control wire 104 therethrough. A diameter of the opening 114 is selected to be equal to or slightly greater than a diameter of an increased diameter portion 128, 129 provided on the control wire 104. As will be described in greater detail later on, the increased diameter portion 128, 129 is adapted to be pulled through the opening 114 upon application of a predetermined threshold pressure thereto. It is noted that although the embodiments depicted herein include two increased diameter portions 128, 129, an alternate embodiment may include only one increased diameter portion 128 without changing the mode of operation of the device 100.
As indicated above, the collapsible member 116 is biased toward an open position, in which the distal end of the portion 111 is separated from the proximal end of the portion 113 while their joined ends form an angle a therebetween. In the open position, the angle a is selected to be sufficiently close to 180 degrees so that the clip 106 may pass through the lumen 101. In the open position, the angle a between the two portions 111 and 113 can be as great as 180 degrees such that the two portions 111 and 113 are substantially co-linear substantially parallel to a longitudinal axis of the control wire 104, although a smaller angle may be used without deviating from the scope of the disclosure. For example, any angle smaller than 180 degrees may be used as long as an outer profile of the collapsible member 116 is small enough to permit insertion of the assembled clip through the lumen 101.
The collapsible member 116 is movable to a closed position by pulling the control wire 104 proximally to cause the first jaw 110 to move proximally toward the second jaw 112, as will be described in greater detail with respect to the exemplary method below. A hypotube (not shown) is positioned proximally of a proximalmost one of the clips 106 to prevent the clips 106 from being withdrawn proximally as the control wire 104 is retracted. Rather, the hypotube (not shown) remains in position against a proximal end of the proximalmost clip 106, countering the proximally directed force from the control wire 104 and causing the collapsible member 116 to move to the closed position. The hypotube (not shown) is formed as an elongated hollow tube housed within the lumen 101 and having an opening extending therethrough, the opening being sized to permit the control wire 104 to be slidably received therethrough and prevent the clip 106 from being drawn thereinto. In the closed configuration, the angle a formed between the two portions 111, 113 is reduced relative to the open configuration. In one embodiment, the angle a is 0 degrees in the closed position such that the two portions 111 and 113 are pressed against one another. The collapsible member 116 further includes a first tab 115 coupling the collapsible member 116 to the first jaw 110 and a second tab 117 coupling the collapsible member 116 to the second jaw 112. The first and second jaws 110 and 112 include first and second slots 140, 142 configured to receive the first and second tabs 115 and 117, therein. The collapsible member 116 may be permanently attached to the first and second jaws 110, 112 using an adhesive or any other attachment means known in the art.
Generally, the clips 106 may remain in the open, expanded configuration when housed within the lumen 101 of the insertion member 102. In the expanded configuration, the jaws 110, 112 of clips 106, are separated from one another by a distance substantially equal to the length of the collapsible member 116.
The clip 106 further includes a locking member 118 extending from an inner surface of the first jaw 110 toward the second jaw 112. The locking member 118 in this embodiment is a rod 119 extending proximally from a first end coupled to the first jaw 110 to a free end with a locking arm 121 extending away therefrom at an angle. The rod 119 in this embodiment is substantially parallel to a longitudinal axis of the control wire 104 while the locking arm 121 extends away from the free end as an extension angled downward relative to the rod 119 and forming an acute angle therewith. In an operative configuration, the first jaw 110 is drawn toward the second jaw 112 and, as the locking member 118 passes through the opening 108, the locking arm 121 engages a wall 144 at the opening 108. The wall 108 is angled so that, as the locking member 118 slides thereover, the locking member 118 is deflected upward. Once the locking arm 121 has passed proximally beyond the wall 144, a biasing force causes the locking member 118 to deflect downward to its original configuration. In this position, the locking arm 121 lockingly engages a proximal wall of the second jaw 112 locking the first and second jaws 110, 112 together in the locked configuration. As would be understood by those skilled in the art, the locking member 118 is formed of a material that is substantially flexible so that the locking member 118 is capable of deflecting over the wall 108 without fracturing. Alternatively, the locking member 118 may include a predetermined structure, such as a bend that can be deflected upon meeting the second jaw 112, such that the two jaws 110 and 112 can be engaged in the locked state.
In accordance with an exemplary method, the insertion device 102 is loaded with a predetermined number of clips 106 corresponding to the requirements of a particular procedure. The insertion device 102 is then advanced to a target site in the body. Once the target location is reached, the control wire 104 and hypotube (not shown) are advanced distally to effect a corresponding distal advancement of the clips 106 until a distal-most one of the clips 106 exits the lumen 101 facing the target tissue site. Specifically, the control wire 104 includes first and second enlarged portions 128, 129 provided thereon, the enlarged portions having substantially spherical shapes although other shapes are envisioned within the scope of the disclosure. As the control wire 104 is advanced distally, engagement of the second enlarged portion 129 with the opening 114 causes the second jaw 112 to move distally. In another embodiment, the hypotube (not shown) may be advanced distally to cause a corresponding distal movement of the clips 106, wherein distal advancement of the hypotube causes a corresponding distal advancement of the control wire 104. As the distal-most clip 106 exits the lumen 101, the collapsible member 116 remains in the open configuration so that the first and second portions 111, 113 enclose an angle of approximately 180 degrees. Once the clip 106 has been moved to a desired position (e.g., under visual guidance), target tissue is drawn into the space between the first and second jaws 110, 112 using graspers or any mechanism known in the art. The control wire 104 is then retracted proximally to draw the first enlarged portion 128 proximally to exert a proximally directed force on the first jaw 110, moving the first jaw 110 proximally toward the second jaw 112. As the first jaw 110 moves proximally, the first and second portions 111, 113 bend about the joint 109 so that the angle a begins to approach 0 degrees. Continued retraction of the control wire 104 causes the locking member 118 to penetrate the target tissue and advance toward the opening 108 until the locking arm 121 extends proximally past the wall 144 and locks the first and second jaws 110, 112 in a locked configuration with the target tissue lockingly received between the jaws 110, 112. In this position, contact between the first and second portions 111, 113 of the collapsible member 116 prevents the first jaw 110 from moving further proximally toward the second jaw 112. Furthermore, the increased profile of the bent collapsible member 116 prevents the clip 106 from being retracted back into the insertion member 102. As the control wire 104 is retracted further proximally, a force exerted by the first enlarged portion 128 against the material surrounding opening 114 increases until a threshold level is exceeded. At this point, the first enlarged portion 128 is forced through the opening 114 and drawn proximally away from the first jaw 110. Continued proximal withdrawal of the control wire 104 now exerts an increasing force against the material surrounding the opening 114 of the second jaw 112 to separate the clip 106 from the control wire 104. This process may then be repeated as necessary to deploy any number of clips 106 within the body using the same insertion member 102 and control wire 104. Although the illustrated embodiment shows only two clips 106, it should be understood that any number of clips 106 can be employed including, but not limited to, three, four, five, six, and so forth. In fact, some embodiments only include a single clip 106, even though the above structure lends itself to multiple clips 106.
Since the clipping device 100 is capable of passing multiple clips 106 through the insertion member 102, the clipping device 100 may be suited for treating larger tissue wounds. For example, a distal-most clip 106 may be deployed at a first end of the tissue wound, the first and second jaws 110, 112 grasping tissue along opposing edges of the tissue wound in the open configuration. The first clip 106 may then be moved to the closed configuration to draw the tissue along opposing edges toward one another. Subsequent clips 106 may be deployed along a length of the tissue wound in a similar manner, until the entire tissue wound is closed.
The endoscope 202 may receive one or more clips, such as the clip 206 in its working channel 204. Although not referenced, the endoscope may have multiple working channels each having a similar form and function as that of the working channel 204. In the illustrated embodiment, the clip 206 includes a first jaw 208 and a second jaw 210 coupled to one another via a collapsible member 212. Each of the first and second jaws 208 and 210 defines an opening 216, 217 through which a control wire 220 passes. The control wire 220 includes an enlarged distal end 218 that prevents any inadvertent dislodgement of the clip 206. Whereas the locking arm 121 of the clip 106 extended away from the was bent away from the locking member 118 toward the collapsible member 116, a locking member 214 of the clip 206 includes a locking arm 216 bent toward tips 122, 124, 126. When moved to the locking configuration, the locking member 214 enters the opening 217 and bends away from the edge of the opening until the end thereof passes this edge. That is, the opening 217 is sized to permit insertion of the locking member 214 thereinto without interfering with slidable movement of the control wire 220. At this point, the locking member 214 straightens to its original shape and the locking arm 216 locks the first jaw 208 to the second jaw 210.
It should be understood that the components of the clip 206, as discussed above, are similar in form and function to the components of clip 106 of
In an operative configuration, the abutment 328 is positioned distally of the opening 314 in the same manner disclosed above with respect to the device 100. When it is desired to bring the first jaw 310 proximally toward the second jaw 112, the control wire 304 is retracted proximally to cause a corresponding proximal retraction of the first jaw 310 until the locking member 118 (not depicted in
In an operative configuration, the abutment 428 is positioned distally of the opening 414 in the same manner disclosed above with respect to the device 100 such that the abutment is seated within the recessed portion 416. When it is desired to bring the first jaw 410 proximally toward the second jaw 112, the control wire 404 is retracted proximally to cause a corresponding proximal retraction of the first jaw 410 until the locking member 118 (not depicted in
As shown in
In an operative configuration, the device 500 is inserted through an endoscope to a target tissue site in the same manner disclosed above with respect to the device 100. As also disclosed above, a hypotube (not shown) or a control wire 104 is then advanced distally to move clip out of the endoscope. Once properly positioned, the control wire 104 or hypotube is retracted proximally to move the first jaw 510 proximally toward the second jaw 512. As the first jaw 510 slides proximally, the opening 530 ratchets over the first and second protrusions 524, 528 of the ratchet member 516. As those skilled in the art will understand, the ratchet mechanism 516 allows movement of the first jaw 510 in only one direction. Accordingly, once the first jaw 510 has moved proximally of any of the first and second protrusions 524, 528, the first jaw 510 is prevented from returning to a position distal thereof due to engagement of a wall (not shown) of the opening 530 with a wall (not shown) of the first and second protrusions 524, 528. The control wire 104 or hypotube is moved proximally until engagement of the first jaw 510 with the second jaw 512 prevents further proximal movement thereof. In this position, further proximal retraction of the control wire 504 or hypotube causes the abutment 128 to disengage from the opening 114 as disclosed in greater detail earlier.
In another embodiment, the device 500 may be formed so that the ratchet member 516 engages in a ratcheting manner an opening extending through the second jaw 512 instead of the first jaw 510.
As shown in
The cross-bar 630 extends from a distal end 632 permanently attached to the first jaw 610 to a proximal end (not shown) accessible to a physician or other user. In one embodiment, the proximal end (not shown) may be coupled to an actuation mechanism controlling movement of the cross-bar 630 through the endoscope (not shown). It is noted that although the cross-bar 630 is depicted with a rectangular cross-section, other cross-sectional shapes are envisioned within the scope of the disclosure including, but not limited to, circular, oval, oblong, square, etc. The cross-bar 630 includes a break point 634 formed as a reduced diameter portion thereof. In an insertion configuration, the break point 634 is seated between the first and second jaws 610, 612, as shown in
In an operative configuration, the clip 606 is inserted into a working channel of an endoscope (not shown). Walls of the working channel compress the first and second jaws 610, 612 to a reduced profile. This configuration bypasses the need for a larger diameter endoscope while still providing a clips jaws 610, 612 having a length sufficient to ensure that target tissue region is captured therebetween. The clip is advanced out of the endoscope to a desired position.
When properly positioned, the control bar 630 is retracted proximally so the first jaw 610 moves proximally toward the second jaw 610. As the first jaw moves proximally, the rail 617 slides below the first jaw such that the angled protrusion 619 lockingly engages the notch 628. The endoscope (not shown) is then rotated or angled to cause the cross-bar 630 to fracture at the break point 634. Thus, a portion of the cross-bar 630 located distally of the break point 634 remains coupled to the clip 606 while a proximal portion thereof is withdrawn from the body through the endoscope.
In an operative configuration, as clip 706 is slid out of an endoscope 102, the first and second jaws 710, 712 expand to a biased expanded configuration. The device is positioned in a target position relative to target tissue and the control wire 104 is retracted proximally to cause a corresponding proximal retraction of the first jaw 710. The first jaw 710 moves proximally until the angled protrusion 619 lockingly engages the notch 628. Further proximal retraction of the control wire 104 causes the abutment 128 to disengage the opening 114. The cross-bar 730 is then retracted proximally to cause a disengagement thereof from the first jaw 710. The cross-bar 730 is then retracted until the distal end 732 thereof is seated within an opening (not shown) extending through a second clip 706 positioned in the endoscope 102. It is noted that although the method is described with a separate disengagement of the control wire and cross-bar 730 from the first jaw 710, an alternate method may be directed to the simultaneous disengagement thereof. Specifically, once the clip 706 has been moved to the locked configuration, the control wire 104 and cross-bar 730 may be simultaneously retracted proximally to cause a simultaneous disengagement thereof from the clip 706. The exemplary device 700 permits the deployment of multiple clips 706 in a single procedure.
In another embodiment, as shown in
As shown in
The clip 806, however, comprises a locking mechanism 818 including a pair of arms 819 extending from the first jaw 810 toward the second jaw 812, on opposing sides of the opening 814 extending therethrough. Each of the arms 819 extends from a first end 856 connected to a lateral surface of the first jaw 810 to a second end 858 extending proximally toward the second jaw 812. The second end 858 includes a tab 821 extending radially inward to engage a corresponding notch 844 of the second jaw 812. The second jaw 812 includes corresponding receiving notches 844 extending along lateral sides thereof so that, when the clip 806 is moved from the open configuration to the closed configuration, the tab 821 of each of the arms 819 engages a corresponding one of the notches 844. The receiving notches 844 extend longitudinally along lateral surfaces 845 thereof. A position of the receiving notches 844 along the lateral surfaces corresponds to a position of the arms 819 so that, when the collapsible member 816 is closed with the first and second jaws 810, 812 adjacent to one another, the tab 821 of each of the arms 819 engages a corresponding one of the receiving notches 844. The receiving notches 844 may include a chamfered surface 860 so that, when the tab 821 slides therealong, the pair of arms 819 engages the chamfered surface to be deflected radially outwardly. Once the tab 821 has passed proximally beyond the chamfered surface 860, a biasing force causes each of the arms 819 to deflect radially inward toward its original configuration. In this position, the tab 821 of each of the arms 819 engages a proximal wall of the second jaw 812, locking the first and second jaws 810, 812 in the closed configuration.
The first jaw 810 may also include a pair of distal notches 862 in a distal face 864 thereof, on opposing sides of the opening 814 so that when the locking mechanism 818 is moved toward the closed configuration, the tabs 821 of the arms 819 are received within the distal notches 862 of an immediately proximal clip 806, as shown in
Although the clip 806 is described as having arms 819 extending proximally from the first jaw 810 to engage receiving notches 844 of the second jaw 812, in another embodiment, arms may similarly extend distally from the second jaw 812 to engage receiving notches formed in the first jaw 810. It will be understood that distal notches would not be required in this embodiment.
The clip 806 may be deployed from the insertion member 802 in a manner substantially similar to the device 100. In another embodiment, however, the control wire 804 includes a single enlarged portion 828 at a distal end thereof. The enlarged portion 828 engages the opening 814 of the first jaw 810 of a distal-most clip 806. The control wire 804 may also include a bend along a portion of a length thereof positioned along the control wire 804 so that, when the distal-most clip 806a is moved distally beyond a distal end 803 of the insertion member 802, the distal-most clip 806 is slightly angled with respect to the immediately proximal-clip 806b, as shown in
As shown in
In another embodiment, rather than flexing to permit the enlarged portion 828 to be passed therebetween, releasing the enlarged portion 828 from the distal-most clip 806a, the panels 868 may be designed to snap off or crush under a predetermined threshold force. Substantially similarly to the embodiment described above, this predetermined threshold force is selected to be greater than the force required to move the first jaw 810 toward the second jaw 812 and lock the clip 806 in the closed configuration. Once the distal-most clip 806a has been locked in the closed configuration, the control wire 804 may be moved further proximally, exerting an additional proximal force on the panels 868 until the panels 868 are broken or crushed, deploying the distal-most clip 806a and permitting the enlarged portion 828 to engage the panels 868 of the immediately proximal clip 806b.
In a further embodiment, as shown in
As shown in
The tubular rod 919 includes a pair of longitudinal slots 923 extending therealong and diametrically opposing one another separating the tubular rod 919 into first and second portions 960, 962 that are deflectable toward one another to be received through the opening 914 of the second jaw 912. An exterior surface 964 of the tubular rod 919 may include a ridge 921 protruding therefrom to engage a proximal wall of the second jaw 912 upon being passed proximally through the opening 914 thereof. In another exemplary embodiment, the tubular rod 919 includes a plurality of ridges 921, which may be evenly spaced relative to one another, to allow different levels of closure of the clip 806, depending one the amount of tissue gripped between the first and second jaws 910, 912. The ridges 921 may be shaped so that the tubular rod 919 is slidable through the opening 914 of the second jaw 912 in a proximal direction but, once one of the ridges 921 is moved proximally therebeyond to engage a proximal wall of the second jaw 912, the tubular member 919 is prevented from moving distally relative to the second jaw 912. The opening 914 extending through the second jaw 912 are specifically sized and shaped to accommodate the tubular rod 919. For example, the opening 914 may include a pair of diametrically opposed grooves extending therealong for receiving the ridges first and second portions 960, 962 along with the control wire.
According to an exemplary method using the clip 906, once the clip 906 is located so that a desired portion of tissue is positioned between the first and second jaws 910, 912, the clip 906 is moved to the closed configuration via the control wire. As the first and second jaws 910, 912 are moved toward one another, a proximal end 958 of the tubular rod 919 enters the opening 914 of the second jaw 912, the first and second portions 960, 962 portions deflecting radially inward as the ridges 921 are received within the opening 914. Once a desired one of the ridges 921 extends proximally past the opening 914, the first and second portions 960, 962 revert to their original biased configuration relative to one another so that the desired one of the ridges extends proximally beyond the opening 914 to engage the proximal wall of the second jaw 912. Although the tubular rod 919 is shown and described as extending proximally from the first jaw 910 to be received within the second jaw 912, it will be understood by those of skill in the art that the tubular rod 919 may similarly extend distally from the second jaw 912 to be distally received within an opening of the first jaw 910.
As shown in
As shown in
As shown in
The locking rod 1219 includes a plurality of notches 1021 along a length thereof. Similarly to the clip 1006, the opening 1214 of the second jaw 1212 includes a flexible member biased radially inward to engage the notches 1221 as the locking rod 1219 is slid proximally through the opening 1214. The notches 1221 are shaped (e.g., angled) so that the locking rod 1219 is permitted to be slid proximally through the opening 1214, but prevented from being moved distally therethrough.
Although the locking rods 919-1219 of the clips 906-1206 are described and shown as extending proximally from the first jaws 910-1210 to be received within openings 914-1214 of second jaws 912-1212, it will be understood by those of skill in the art that the locking rods 919-1219 may similarly extend distally from the second jaws 912-1212 to be received within openings of the first jaws 910-1210.
As shown in
The control wire 1304 in this embodiment is not required to be cylindrical. The control wire 1304 may, for example, be substantially rectangular with a rounded underside for engaging the hemispherical shape of the locking member 1319. The control wire 1304, however, may take any of a variety of shapes and sizes so long as the opening 1314 and the locking member 1319 are correspondingly sized and shaped.
Although the locking member 1319 is shown and described as extending distally from the second jaw 1312 to be received within the opening 1314 of the first jaw 1310, it will be understood by those of skill in the art that the locking member 1319 may similarly extend proximally from the first jaw 1310 to be proximally received within the opening of the second jaw 1312.
As shown in
In one embodiment, the ring 1419 moves along the first and second portions 1411, 1413 toward the locked configuration via, e.g., the pull of gravity. Where the natural force of gravity is not utilized, the ring 1419 may include a feature that simulates the force of gravity. For example, a line under tension may be attached to the ring 1419 at two or more points, e.g., opposing sides of the ring 1419, attaching to one of the first and second jaws 1410. In one example, one or more lines are attached to the first jaw 1410, while one or more lines are attached to the second jaw 1412. Thus, as the first and second jaws 1410, 1412 are moved toward one another, the lines under tension draw the ring 1419 along the length of the first and second portions 1411, 1413 of the collapsible member 1419 toward the first and second jaws 1410, 1412 and into the thinned out portions of the first and second bending points 1450, 1452.
As shown in
As shown in
In the open configuration, a length of the ratchet strips 1619 extend substantially parallel to the collapsible member 1616, with the proximal ends 1658 bent laterally to extend out of the lateral openings 1644. The proximal ends 1658 extend out of these lateral openings 1644 so that the ratchet strips 1619 do not interfere with an immediately proximal clip in an insertion member of a device (e.g., device 100, 800) through which this clip 1606 is inserted. As the clip 1606 is moved to the closed configuration, the proximal ends 1658 of the ratchet strips 1619 are drawn proximally so that ratchet teeth 1621 of the ratchet strips are slid proximally along the corresponding ratchet teeth 1654 of the opening 1614. The ratchet teeth 1621, 1654 are configured to permit the ratchet strips 1619 to be slid proximally through the opening 1614 but prevented from distally relative thereto.
It should be understood that this disclosure is, in many respects, only illustrative. Changes may be made in details, particularly in matters of shape, size, and arrangement of steps without exceeding the scope of the disclosure. This may include, to the extent that it is appropriate, the use of any of the features of one example embodiment being used in other embodiments. The disclosure's scope is, of course, defined in the language in which the appended claims are expressed.
The present invention claims priority to U.S. Provisional Patent Application Ser. No. 61/953,312 filed Mar. 14, 2014; the disclosure of which is incorporated herewith by reference.
Number | Date | Country | |
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61953312 | Mar 2014 | US |