OVERTUBE INTRODUCER FOR USE IN ENDOSCOPIC BARIATRIC SURGERY
This application describes an overtube device that gives diagnostic and/or therapeutic access to body cavities using natural orifices of the body. The overtube includes an elongate flexible body having a distal portion deflectable in response to activation of a control cable. Proximal features of the overtube include an insufflations port and seals for minimizing loss of insufflations pressure around the shafts of instruments passed through the tube. In some embodiments, retractor elements are including on the distal portion of the overtube.
This is application claims priority to U.S. Provisional Application No. 60/950,584, filed Jul. 18, 2007
BACKGROUND OF THE INVENTIONThis application describes an overtube/introducer device that gives access to body cavities using natural orifices of the body (e.g., esophagus, anus, vagina) for a variety of therapeutic and/or diagnostic procedures. In a particular application, the overtube/introducer enables the introduction of devices into the gastrointestinal tract of a patient via the mouth and esophagus. Therapies to be carried out using the introducer can include procedures designed for the treatment of obesity. The disclosed overtube provides in and out access to the targeted procedural site and protects the body tissue during the procedure from trauma.
The disclosed overtube is suitable for use in an exemplary procedure in which the geometry of the stomach is modified and implantable devices are deployed. The procedure is preferably performed entirely through the naturally existing orifice of the mouth, without additional external incisions.
The exemplary procedure is initiated with the introduction of an overtube into the mouth and, at a minimum, past the pharynx of a patient but preferably reaching and sealing against the lower esophageal sphincter (LES). For reference,
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- 1. Body of stomach
- 2. Fundus
- 3. Anterior wall
- 4. Greater curvature
- 5. Lesser curvature
- 6. Lower esophageal sphincter (LES)/gastroesophageal junction
- 9. Pyloric sphincter
- 10. Pyloric antrum
- 11. Pyloric canal
- 12. Angular notch
- 13. Gastric Canal
- 14. Rugal folds
The entire exemplary procedure is preferably performed under direct endoscopic visualization, obtained by inserting a flexible endoscope into the overtube prior to its introduction into the patient, though the procedure (or individual steps of the procedure) may also be performed without direct visualization. In cases where an endoscope is used, the endoscope's distal tip may be inserted into a flexible Bougie that incorporates a central lumen allowing direct line-of-sight for the endoscope's illumination and visualization optics. The endoscope with the installed Bougie may then be inserted into the overtube's central lumen until the Bougie protrudes just past the overtube's distal end. This provides a gentle leading edge that facilitates insertion of the Bougie, overtube and endoscope into the patient's esophagus.
Alternatively the overtube may be inserted over a guide wire; the guidewire inserted under direct visualization using a standard endoscope. A transition member is positioned between the inside diameter of the overtube and the outside diameter of the guidewire providing for a smooth transition. This transition is preferably a long taper, and composed of a soft, flexible material such as silicone.
Once the overtube, endoscope and Bougie have reached the desired position within the esophagus, the endoscope and Bougie are withdrawn from the overtube, and the overtube is left in position. The overtube is now in a position to facilitate the introduction of other tools and devices needed to perform subsequent steps.
With the overtube in the desired position, a special-purpose stapler is inserted which will be used to prepare sites within the stomach wall tissue that will serve as mounting points for implantable devices to be installed in later steps. Staplers suitable for this procedure include those disclosed in the following U.S. Applications:
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- U.S. application Ser. No. 11/542,457, filed Oct. 3, 2006, Attorney Docket BARO-1110;
- U.S. application Ser. No. 11/900,757, filed Sep. 13, 2007, Attorney Docket BARO-1310.
- U.S. application Ser. No. 12/119,329, filed May 12, 2008, Attorney Docket BARO-1610.
- U.S. application Ser. No. 12/050,169, filed Mar. 18, 2008, Attorney Docket BARO-1900.
In one such stapler, the leading distal tip of the stapler mechanism is covered with a compliant, bullet-shaped, Bougie end cap, and incorporates a side-looking window. The smooth Bougie shape of the end cap facilitates introduction of the stapler into the overtube and past the distal end of the overtube into the patient's esophagus or stomach. The side window allows stomach wall tissue to be drawn between the stapler jaws prior to the application of staples. The stapler incorporates a passive flexible length which allows the device to bend freely between the user controls at the proximal end and the stapler mechanism at the distal end. Insertion of the stapler is preferably performed under direct endoscopic visualization, with an endoscope positioned next to the stapler such that its camera optics are located slightly proximal of the stapler's distal end. In this way, the position of the stapler may be visualized at all times, relative to its position within the overtube, esophagus and stomach. However, insertion of the stapler may optionally be performed without using an endoscope for visualization.
With the stapler inserted into the stomach, it may then be positioned relative to the stomach wall near the lower esophageal sphincter as desired. In order to achieve the desired position and visualization, it may be necessary to withdraw or further insert the overtube, or to manipulate certain features of the overtube, in such a way that it advantageously alters the geometry of the tissue and/or the overtube's relative position. When the position of the stapler is judged to be correct, suction is applied to draw stomach wall tissue into the stapler end cap's side-looking window. This positions the stomach wall tissue between the jaws of the stapler, which are then approximated via a physician-controlled actuator to clamp the tissue firmly in position. Once the tissue has been securely fixtured, the suction may be released, as it is no longer needed to retain the stomach tissue. Staples are then deployed by means of a second physician-controlled actuator through the plication, or fold, of stomach tissue between the stapler's jaws to create circular rings about a central point. A hole is created in the plication of stomach tissue at the center of the pattern of stapes simultaneous to the application of the staples. The hole and surrounding circular array of staples create a secure and durable mounting point (e.g., for implantable devices), and will be used in later steps of the procedure. Once the staples have been deployed and the mounting point has been created, the physician releases the plication from the stapler's jaws and any remaining suction. The stapler and endoscope are then withdrawn from the overtube.
For staplers that must be re-loaded prior to the creation of the next mounting point, the stapler is withdrawn from the overtube and the distal stapling mechanism is then reloaded. For self-reloading stapler mechanisms, this step is not required. If reloading is required and has been performed, the reloaded device, Bougie end cap and endoscope are reinserted into the overtube. The process of positioning the stapler mechanism within the stomach described above is repeated so that the next mounting point is identified and created. This process is repeated to produce one or more anchor points, but preferably four mounting points are created. These mounting points may be anywhere within the stomach, but they are preferably located at the 3, 6, 9 and 12 o'clock positions, a fixed distance away from the lower esophageal sphincter. If the mounting points are to be used as anchor points for a flow restrictor of the type used to restrict/obstruct passage of food from the esophagus into the stomach, the preferential distance of the mounting points is such that the position of the exit of a restrictor attached at the mounting points will be immediately adjacent the lower esophageal sphincter. Exemplary restrictor devices include but are not limited to those disclosed in U.S. Pat. Nos. 6,675,809, 6,845,776, 7,097,665, and 7,146,984, U.S. application Ser. No. 10/345,666, filed Jan. 16, 2003, Attorney Docket No. BARO-300, and U.S. application Ser. No. ______, Endoscopic Implant System and Method, Attorney Docket BARO-2010, filed Jul. 17, 2008.
Once the desired mounting points have been created with the stapler, the stapler is withdrawn. Next, highly compliant anchors are installed through the hole at the center of each of the mounting points. The anchors have a rivet-like shape with large retaining heads on either end. The anchors are intended to be installed in the holes at the center of the mounting points, remain in position indefinitely or until removed, and be easily removable. The anchors are configured such that they may be grasped and pulled from one end (herein referred to as the “leading end”), and the resulting tension causes the leading end retaining head to change profile so that it may be drawn through the hole in a mounting point. The other end of the anchor (herein referred to as the “following end”) is designed so that tension resulting from drawing it through the mounting hole does not result in a change to its profile, so it cannot be drawn through the mounting hole. Anchors of this type are described in U.S. application Ser. No. ______, Endoscopic Implant System and Method, Attorney Docket BARO-2010, filed Jul. 17, 2008
Anchors are positioned in each of the mounting holes by means of graspers or similar instruments, which pull them, leading end first, through the mounting holes. Once the anchors are installed, the instruments required to insert them are withdrawn from the overtube.
Finally, a restrictor is inserted into the stomach via the overtube. The restrictor is attached to the anchors, and will remain in the stomach after the procedure for an indefinite period of time, such as the point in time when a physician determines the patient has achieved sufficient weight loss. The restrictor is attached to the anchors by drawing the leading end of the anchors through mounting holes in the restrictor using graspers or other instruments, as appropriate.
When the restrictor is attached to the anchors, the procedure is complete and the overtube may be withdrawn from the patient, along with any tools remaining in the lumen it defines (e.g., endoscope, graspers, etc.).
Upon completion of the procedure, the overtube has enabled the deployment of a restrictor, which is attached to anchors that have been implanted into stapled plications in the stomach wall. The passage of food into the stomach from the esophagus has been restricted, altering the patient's feelings of satiety and eating habits.
The present invention comprises an overtube intended to be inserted trough the mouth into the esophagus of a patient, and extend at least past the pharynx, but preferably far enough for the distal end to seal against the lower esophageal sphincter (LES) at the junction between the stomach and the esophagus. The overtube incorporates features that enable it to facilitate the procedure described in the Background section above though is not restricted to that single procedure. The primary purpose of the present invention is to create and maintain a patent lumen that provides access from the mouth of a patient to the stomach. The outer diameter of the overtube's insertable length allows it to fit within, and be insertable into, a patient's gastrointestinal tract from the mouth to the stomach. The outer surface of the insertable length of the overtube is sufficiently lubricious to allow for its introduction into the esophagus and subsequent manipulations (e.g., further insertion or withdrawal, rotation), and/or is compatible with lubricants commonly used for such procedures. The inner diameter of the overtube's insertable length is sufficiently large to accommodate the insertion of the instruments described in the Background section (e.g., stapler, endoscope, graspers, etc.). Alternatively, the Overtube may be composed of multiple lumens allowing multiple tools to be inserted without interfering with each other. The inner surfaces of the overtube's insertable length are sufficiently lubricious to allow the insertion of instruments and devices, and/or are compatible with lubricants commonly used for such purposes. The overtube conforms to the patient's anatomy and protects anatomical features (e.g., the pharynx, esophagus, lower esophageal sphincter, etc.) from injury that may result from the insertion and manipulation of instruments during the procedure. Further, the overtube provides a means to control the position relative to the LES along the axis of insertion. The position of the distal end of the overtube may be controlled by means of insertion and withdrawal of the instrument (the “Z-level”), by means of rotation of (torquing) the insertable length of the overtube, and by optionally incorporating an articulatable, steerable, lockable section somewhere within the insertable length. The overtube assembly may also incorporate expandable elements at or near the distal tip that assist in creating a volume within the stomach, reshaping the walls to facilitate visualization and access. The overtube possesses sufficient tensile, compressive and hoop strength to resist excessive deformation (e.g., extension, compression, collapse, kinking) during use. Materials suitable for short-term mucosal tissue contact are preferable for use in the overtube, e.g., stainless steel, nitinol, silicone, urethanes, PEEK, PVC, etc.
Overview and System LayoutOne embodiment of the present invention's insertable length 101 (
The tube 110 may also incorporate a thin woven mesh, encapsulated within the compliant material as described above, either in conjunction with the springform wire 112 or in lieu of such a wire. The woven mesh may be made of stainless steel, for instance, or aluminum, or any of a variety of polymeric materials. The purpose of embedding mesh within the tube is to substantially increase its torquability while having a minimal effect on its resistance to bending or its minimum radius of curvature.
The outer surface of the insertable length of the overtube should be sufficiently lubricious to allow for its introduction into the esophagus and subsequent manipulations (further insertion or withdrawal, rotation), and/or be compatible with lubricants commonly used in such procedures. The inner surfaces of the overtube's insertable length should also be sufficiently lubricious to accommodate the insertion of instruments and devices, and/or be compatible with lubricants typically used in such applications. In order to achieve sufficient lubricity, inherently lubricious materials may be selected (e.g., PTFE), or coatings may be applied to base materials (e.g., hydrophilic or hydrophobic coatings). Features that prevent locking or binding between components may also be incorporated, such as serrations or surface features similar to those seen on knives designed for slicing meat. Such features facilitate sliding, rather than binding, when elements are moved relative to one another.
The tube 110 may include a single or large central lumen 114a as shown in
The construction of the overtube may also be such that it may be expanded as necessary after it has been placed within a patient's anatomy. In the event that large instruments or devices are to be inserted through the overtube into the stomach, it may be beneficial to allow the overtube to expand to accommodate such large components that may otherwise fit too tightly or not at all, and to then return to its unexpanded diameter following passage of the large device. This is illustrated in
One means of manufacturing the insertable length of the overtube assembly as described (with reinforcing elements encapsulated within a matrix) is to start with a wire 112 which is coated with a thermopolymer 113. This wire may be coiled around a mandrel 118 having the desired outer diameter or profile (the mandrel's outer diameter need not be consistent). This is depicted in
Another means of manufacturing the insertable length of the overtube is to wrap at least one layer of a thin rolled sheet 120a around a mandrel 118, and then fuse the layers together using heat, adhesives or chemical means. This is shown in
The distal tip may maintain the same outer diameter (herinafter “OD”), inner diameter (hereinafter “ID”) and wall thickness as the rest of the tube, or it may taper slightly to form a gentle curve. When an optional taper is incorporated into the distal tip, this serves to facilitate introduction into a patient's gastrointestinal tract, as well as helping to prevent tissue from being drawn into, and potentially pinched between, the overtube and any loose fitting components inserted into its inner lumen. As illustrated in the embodiments of
Alternatively the overtube may be inserted over a guide wire 128 (
An alternate means of achieving a gently curved leading edge is by means of a protective, thin walled umbrella-like cap 132 positioned at the distal end of the overtube. During insertion, the umbrella is positioned so that it fits snugly over the distal opening of the overtube, maintaining a dome shape and creating the gently curved bullet shape that facilitates insertion and prevents damage to tissue (
An additional embodiment of spreadable fingers is shown in
Another embodiment of a mechanism that may be used to control the degree of expansion of such spreadable fingers employs a Bowden cable attached at the distal end to each finger in order to determine its position. When tension is applied to each Bowden cable, either separately or simultaneously, the corresponding finger moves radially outward, creating a larger working space.
In cases where an array of spreadable fingers are used to create the expandable element, such as that shown in
In addition to facilitating introduction of the overtube and enabling users to increase the working volume and reshape the stomach during a procedure, the expandable elements, such as the fingers described above and in
One embodiment of a mechanism that may be used to control the degree of spread of such expandable fingers, or any other embodiment that may be effectively controlled by means of Bowden cables 148, is shown in
When retraction of the expandable elements is desired, it may be advantageous or required, depending on the construction, to incorporate components within the mechanism of the expanders to ensure that they reliably retract. For instance, in cases where Bowden cables are used to actuate an expandable element, friction between the control cable and the compressive housing may prevent the expandable element from returning to a retracted position. For the embodiment shown in
An alternate embodiment of an expandable element located at the distal end of the overtube or on a separate elongate member passed through the overtube, is shown in
At least one articulatable, lockable section may optionally be incorporated within the insertable length of the overtube.
Steering control of the articulatable section may be achieved by a variety of methods. The preferred method is to control articulation with at least one pull cable, such as a Bowden cable, acting within a coil tube compression housing. A single such control cable can be used to control the shape of the articulatable section in one direction (e.g., to the right), or a single cable can be used in combination with an opposing spring element to cause articulation in two directions (e.g., the spring pulls to the left and the cable pulls to the right). Alternately, two control cables can be used to control articulation in two directions (e.g., left and right). Extending this further, three control cables can be used in combination to allow for articulation in all directions (e.g., left, right, up and down), or four control cables can be used, each directly controlling bending of the articulatable section in each direction. The use of four control cables is the preferred method, as the resulting control is simple and intuitive for the user.
The control cables may be used to steer, or determine the curvature of, the articulating section of the overtube.
The length of each of the Bowden cables is critical to their correct performance, and for this reason elements that facilitate their adjustment are helpful. Even in cases where they have been cut to the exact length required and perfectly installed, cables typically stretch over time and use, and will require periodic adjustment. For this reason, the control knob assemblies may incorporate a number of means of cable adjustment. One useful characteristic of a control knob is to incorporate a means to deal individually with each control cable that terminates there. For instance, if the control knob determines the shape of the articulatable section in the left-right direction, the cable controlling bending to the left can be managed and kept separate and adjusted independently of the cable controlling bending to the right. This may be accomplished by incorporating two completely separate sections 170a, 170b of the control knob, one for each terminating control cable, as illustrated in
Control of an articulating section may also be achieved by means other than Bowden cables. Any appropriate alternate actuation method and energy source may be used, such as hydraulic or pneumatic actuators, which could be used to create the motion and forces needed to bend the articulatable section.
Articulatable Section ConstructionThe articulatable sections may be constructed using a variety of techniques. One simple embodiment consists of a single coil spring element 112 capable of bending as desired, and is shown in
An alternative means of constructing an articulatable section is to create it by stringing together on cables 194 a succession of rings shaped in such a way that they are allowed to rock relative to one another. The rocking motion can again be controlled through the use of Bowden cables. This construction technique is illustrated in
The arrangement of the rings relative to each other in the assembly determines whether bending in two directions results (e.g., left and right) or whether bending in four directions (e.g., left, right, up and down) is allowed.
These stacked ring embodiments of the articulatable section may also be used to construct unarticulatable sections. Such sections are flexible, but their articulation is not selectable or controllable by a user. When this approach is used, the entire length of the overtube may be constructed using a continuous assembly of rings, oriented in at least one of the ways described above. The shape of at least one region of the assembly may be controllable (e.g., articulatable or steerable) via Bowden cables, as described, while the remaining regions of the assembly which are not controllable have no Bowden cables determining their shape.
Another embodiment of an articulatable section is shown in
Regardless of the construction of the articulatable section, it may have either a continuous outer sheath 202 or surface, a continuous inner sheath 204 or surface, or both (e.g., sheaths positioned over the inner and outer surfaces of the articulating rings, coil or other articulating features, or an encapsulation/positioning of such articulating features within the walls of a sheath). This is shown in
Components may be added to or incorporated within the overtube to provide tactile feedback to users when instruments within the overtube's inner lumen are moved. For example, elements may be used that provide the sensation of indexing, such as a ratcheting feel of engagement and disengagement, when an instrument is inserted into the overtube to specific depth intervals, or rotated relative to the overtube 100 at angular intervals. One embodiment of such a feature makes use of magnetic interactions. If at least one magnet 206 or magnetically attractive element is incorporated into the overtube, and a corresponding magnet 208 or magnetically attractive element is incorporated into an instrument 210 that moves relative to the overtube, the elements will attract or repel each other as they move into and out of proximity. This is illustrated in
The proximal end of the overtube may incorporate graduated markings indicating depth and radial angle (
The angular markings at the proximal end of the overtube may be further identified by means of color coding (
The steering controls that determine the angle and direction of the articulatable section may also be marked to correspond to the markings on components at the distal end of the overtube. If, for instance, the spreadable finger located at the top of the overtube (at the 12 o'clock position) is red, the control knob that determines the up-down position of the articulatable section will have a red marking on it indicating which direction it should be turned to cause the articulatable section to bend in the up direction. Similarly, if the spreadable finger located at the bottom of the overtube (at the 6 o'clock position) is blue, then markings on the same knob will incorporate an indication of which direction it should be turned to cause the articulatable section to bend down. This may be done, for example, by marking the knobs with different color arrows.
In addition to indicating which direction to turn each knob to achieve the desired bend angle with the articulatable section, each knob may be marked with an indication of when the articulatable section is approximately straight. A marking indicating the “neutral” position of the articulatable section allows a user to straighten the articulatable section with high confidence, rather than relying on “feel” or for the articulatable section to return to a straight configuration if tension is released on the controlling Bowden cables.
A positive retention force and tactile feedback may also be provided in the steering control knobs by incorporating ball detent components and a sequence of mating indentations. When a user turns a steering control knob, the ball detents can prevent the knob from turning freely, thus preventing the articulatable section from unintentionally returning to its relaxed neutral position. The indexing that occurs as the ball detent moves through the succession of indentations may also provide useful tactile feedback to the user, indicating increments of rotation of a knob and/or certain positions of the articulatable section, such as straight or neutral.
Terminating End RingThe proximal end of the overtube incorporates a terminating end ring (
Over the terminating end ring, a fixturing ring 220 (
An overtube may be packaged alone or as a system in combination with related components such as staplers and implants of the type referenced in the application, as well as any combination of the following: Bougies, transition members, guidewires, endoscopes etc. The system might further include instructions for use instructing a user to employ the system in accordance with the methods disclosed herein.
As is apparent from the forgoing disclosure, in some embodiments described above, the overtube comprises an articulating section, an actuator for effecting articulation of the articulating section, and an optional locking mechanism allowing the articulating section to be locked in a desired position. In other embodiments described above, the overtube comprises an elongate tube having one or more retraction elements on its distal end, allowing the overtube to create working space within the body (e.g., stomach) while giving access to instruments passed through its lumen.
It should be recognized that a number of variations of the above-identified embodiments will be obvious to one of ordinary skill in the art in view of the foregoing description. Accordingly, the invention is not to be limited by those specific embodiments and methods of the present invention shown and described herein. The applications and methods listed are not limited to the treatment of diseases or procedures listed. Modifications of the above described methods and tools and variations of this invention that are obvious to those of skill in the art are intended to be within the scope of this disclosure. Moreover, the disclosed embodiments may be combined with one another in varying ways to produce additional embodiments.
Any and all patents, patent applications and printed publications referred to above, including those relied upon for purposes of priority, are incorporated herein by reference.
Claims
1. An endogastric overtube for use in a stomach of a patient, comprising:
- a flexible elongate tube having a proximal end and a distal end, the tube proportioned such that when the distal end is in the stomach, the proximal end is positioned outside the patient, the tube including at least one lumen extending from the proximal end to the distal end, the tube having a maximum outer diameter of at least approximately 10 mm; and
- a control cable extending through a wall of the tube, the control cable coupled to a distal portion of the tube such that engagement of the control cable causes deflection of the distal portion.
2. The endogastric overtube of claim 1, wherein the tube further includes a reinforcement on a distal portion of the tube.
3. The endogastric overtube of claim 2, wherein the tube is a formed of polymeric material and wherein the reinforcement is embedded within the polymeric material.
4. The endogastric overtube of claim 2, wherein the tube is a formed of polymeric material and wherein the reinforcement is positioned on an inner surface of the lumen or an outer surface of the tube.
5. The endogastric overtube of claim 2, wherein the reinforcement is a resilient coil.
6. The endogastric overtube of claim 2, wherein the reinforcement is at least one resilient ring.
7. The endogastric overtube of claim 2, wherein the reinforcement is at least one partial ring.
8. The endogastric overtube of claim 6, wherein the resilient ring is circular.
9. The endogastric overtube of claim 6, wherein the resilient ring is elliptical.
10. The endogastric overtube of claim 2, wherein the reinforcement includes a mesh element.
11. The endogastric overtube of claim 2, wherein the lumen has a diameter, and wherein the tube is expandable from a first position to a second position in response to introduction of an instrument having a diameter exceeding the lumen diameter into the lumen, and wherein the reinforcement is configured to restore the tube to the first position upon removal of the instrument from the lumen.
12. The endogastric tube of claim 1, further including a removable atraumatic tip on the distal end.
13. The endogastric tube of claim 12, wherein the atraumatic tip is positioned on an elongate member extending through the lumen.
14. The endogastric tube of claim 12, wherein the atraumatic tip is a cap at least partially covering the distal end of the tip.
15. The endogastric tube of claim 12, wherein the elongate element is retractable in a proximal direction to invert the cap into the lumen.
16. The endogastric tube of claim 12, wherein the elongate element is advanceable in a distal direction to collapse the cap into a collapsed position, and wherein the elongate element is retractactable to withdraw the cap in the collapsed position through the lumen.
17. The endogastric tube of claim 5, wherein the control cable is coupled to the spring element.
18. The endogastric tube of claim 1, further including a retractor element on the distal end of the tube, the retractor element moveable from a first position to a second position in which the retractor element extends laterally from the tube.
19. The endogastric tube of claim 18, wherein the retractor element extends longitudinally when in the first position.
20. The endogastric tube of claim 18, wherein the retractor element includes a first portion coupled to a first ring and a second portion coupled to a second ring, and wherein relative movement of the second ring towards the first ring moves the retractor element from the first position to the second position.
21. The endogastric tube of claim 20, wherein the retractor element includes a hinge, and wherein the first portion and the second portion are on opposite sides of the hinge.
22. The endogastric tube of claim 20, wherein the first portion is an elongate member, and wherein the second portion is a pivot element pivotably coupled between the elongate member and the second ring.
23. The endogastric tube of claim 18 wherein the retractor element includes a mount for receiving an implant to be implanted in the stomach.
24. The endogastric tube of claim 1, further including a retractor element on the distal end of the tube, the retractor element including a plurality of segments and a cable extending between the segments, the retractor having a first, flexible, position and a second, more rigid, position, the cable retractable to move the retractor from the first to the second position.
25. The endogastric tube of claim 24, wherein the segments are positioned on a cable loop and wherein the retractor element in the second position forms a retractor hoop.
26. The endogastric tube of claim 25, further including a second retractor element including a plurality of second segments and a second cable extending between the segments, the second cable retractable to move the second retractor from a flexible position to a more rigid position.
27. The endogastric tube of claim 26, wherein the second retractor in the second position forms a retractor hoop.
28. The endogastric tube of claim 1, wherein the tube includes a seal positioned to seal against an instrument inserted into the lumen.
29. The endogastric tube of claim 1, wherein the proximal portion of the tube includes a port positionable in fluid communication with a source of insufflation gas.
30. The endogastric tube of claim 1, wherein the tube has a maximum outer diameter of between approximately 10 mm-20 mm.
31. The endogastric tube of claim 30, wherein the tube has a maximum out diameter of between approximately 15 mm-20 mm.
32. The endogastric tube of claim 30, wherein the tube has a maximum outer diameter of approximately 20 mm.
33. The endogastric tube of claim 1, wherein the tube has a maximum outer diameter of approximately 18-22 mm.
34. The endogastric tube of claim 1, wherein the tube has a maximum wall thickness of 0.1-0.2 mm.
35. An endogastric overtube for use in a stomach of a patient, comprising:
- a flexible elongate tube having a proximal end and a distal end, the tube proportioned such that when the distal end is in the stomach, the proximal end is positioned outside the patient, the tube including at least one lumen extending from the proximal end to the distal end, the tube having a maximum outer diameter of at least approximately 10 mm; and
- a retractor element on the distal end of the tube, the retractor element moveable from a first position to a second position in which the retractor element extends laterally from the tube.
36. The endogastric tube of claim 35, wherein the retractor element extends longitudinally when in the first position.
37. The endogastric tube of claim 35, wherein the retractor element includes a first portion coupled to a first ring and a second portion coupled to a second ring, and wherein relative movement of the second ring towards the first ring moves the retractor element from the first position to the second position.
38. The endogastric tube of claim 37, wherein the retractor element includes a hinge, and wherein the first portion and the second portion are on opposite sides of the hinge.
39. The endogastric tube of claim 37, wherein the first portion is an elongate member, and wherein the second portion is a pivot element pivotably coupled between the elongate member and the second ring.
40. The endogastric tube of claim 37, wherein the retractor element includes a mount for receiving an implant to be implanted in the stomach.
41. The endogastric tube of claim 35, further including a retractor element on the distal end of the tube, the retractor element including a plurality of segments and a cable extending between the segments, the retractor having a first, flexible, position and a second, more rigid, position, the cable retractable to move the retractor from the first to the second position.
42. The endogastric tube of claim 41, wherein the segments are positioned on a cable loop and wherein the retractor element in the second position forms a retractor hoop.
43. The endogastric tube of claim 42, further including a second retractor element including a plurality of second segments and a second cable extending between the segments, the second cable retractable to move the second retractor from a flexible position to a more rigid position.
44. The endogastric tube of claim 43, wherein the second retractor in the second position forms a retractor hoop.
45. The endogastric tube of claim 35, wherein the tube includes a seal positioned to seal against an instrument inserted into the lumen.
46. The endogastric tube of claim 35, wherein the proximal portion of the tube includes a port positionable in fluid communication with a source of insufflation gas.
47. The endogastric tube of claim 35, wherein the tube has a maximum outer diameter of between approximately 10 mm-20 mm.
48. The endogastric tube of claim 47, wherein the tube has a maximum out diameter of between approximately 15 mm-20 mm.
49. The endogastric tube of claim 35, wherein the tube has a maximum outer diameter of approximately 20 mm.
50. The endogastric tube of claim 35, wherein the tube has a maximum outer diameter of approximately 18-22 mm.
51. The endogastric tube of claim 35, wherein the tube has a maximum wall thickness of 0.1-0.2 mm.
Type: Application
Filed: Jul 17, 2008
Publication Date: Jan 29, 2009
Inventors: David Cole (San Mateo, CA), Melanie L. Harris (Mountain View, CA), Carlos E. Castro (San Jose, CA), Jason S. Stewart (Redwood City, CA), Samuel T. Crews (Woodside, CA), Daniel J. Balbierz (Redwood City, CA)
Application Number: 12/175,274
International Classification: A61B 1/32 (20060101);