The present invention relates generally to the field of systems and methods for performing endoscopic surgery, and specifically to systems and methods for endoscopic plication of tissue within body cavities.
An anatomical view of a human stomach S and associated features is shown in
Stomach S includes a fundus F at its proximal end and an antrum A at its distal end. Antrum A feeds into the pylorus P which attaches to the duodenum D, the proximal region of the small intestine. Within the pylorus P is a sphincter that prevents backflow of food from the duodenum D into the stomach. The middle region of the small intestine, positioned distally of the duodenum D, is the jejunum J.
Several prior applications sharing inventors with the present application, including International Application No. WO 2005/037152 having an international filing date of Oct. 8, 2004 and U.S. application Ser. No. 11/439,461, filed May 23, 2006 (both incorporated herein by reference) describe methods according to which medical implants are coupled to tissue structures formed within the stomach. According to these applications, devices for inducing weight loss (e.g. by restricting and/or obstructing flow of food into the stomach, and/or by occupying a portion of the stomach volume) may be coupled to tissue tunnels or plications P (
For example, U.S. application Ser. No. 11/439,461 (incorporated herein by reference in its entirety), describes a restrictive and/or obstructive implant system for inducing weight loss. In one embodiment, flexible loops 2 (
In other instances, tissue plications may themselves be sufficient to provide the necessary treatment. For example, the plications may be used to reduce stomach volume or form a flow restriction within the stomach.
Other types of implants may be coupled to such plications or other tissue structures for a variety of purposes. These implants include, but are not limited to prosthetic valves for the treatment of gastro-esophageal reflux disease, gastric stimulators, pH monitors and drug eluting devices that release drugs, biologics or cells into the stomach or elsewhere in the GI tract. Such drug eluting devices might include those which release leptin (a hormone which creates feelings of satiety), Ghrelin (a hormone which creates feelings of hunger), octreotide (which reduces Ghrelin levels and thus reduces hunger), Insulin, chemotherapeutic agents, natural biologics (e.g. growth factor, cytokines) which aid in post surgery trauma, ulcers, lacerations etc. Still other implants might be of a type which might provide a platform to which specific cell types can adhere, grow and provide biologically-active gene products to the GI tract, and/or a platform for radiation sources that can provide a local source of radiation for therapeutic purposes, or provide a platform whereby diagnostic ligands are immobilized and used to sample the GI tract for evidence of specific normal or pathological conditions, or provide an anchor point for imaging the GI tract via cameras and other image collecting devices.
The prior applications listed above, address the desirability of forming tissue plications, pockets or tunnels in a way that regions of serosal tissue (i.e. the tissue on the exterior surface of the stomach) are retained in contact with one another. Over time, adhesions formed between the opposed serosal layers create strong bonds that can facilitate retention of the plication/pocket/tissue over extended durations, despite the forces imparted on them by stomach movement and implanted devices. More durable plications can be created by placing any of a number of materials and/or substances (i.e. injectable sclerosing agents) between the serosal surfaces prior to plicating the serosal surfaces together. One example of material suitable for this purpose is polypropolyene mesh, commonly used for hernia repair, which when inserted in the plication fold provides a durable anchoring position within the GI tract.
Regardless of the application for which a plication is being formed, it is highly desirable to form that plication using steps carried out from within the stomach using instruments passed down the esophagus, rather than using more invasive surgical or laparoscopic methods. The present application describes endoscopic plicators which may be passed transorally into the stomach and used to form serosal-to-serosal plications in a stomach wall.
The present application describes endoscopic plicators which may be passed transorally into the stomach and used to plicate stomach tissue by engaging tissue from inside of the stomach and drawing it inwardly. In the disclosed embodiments, the tissue is drawn inwardly into a vacuum chamber, although tissue may be drawn inwardly using other components that do not involve the use of a vacuum. When a portion the stomach wall is drawn inwardly, sections of serosal tissue on the exterior of the stomach are positioned facing one another. The disclosed plicators allow the opposed sections of tissue to be moved into contact with one another, and preferably deliver sutures, staples or other means for maintaining contact between the tissue sections at least until serosal bonds form between them. Each of these steps may be performed wholly from the inside of the stomach and thus can eliminate the need for any surgical or laparoscopic intervention. After one or more plications is formed, medical devices (including, but not limited to any of the types listed above) may be coupled to the plication(s) for retention within the stomach.
Certain of the disclosed plicators pass a mesh element and/or a quantity of sclerosing agent through the stomach wall such that it is disposed between the opposed regions of serosal tissue thus enhancing serosal bonding. Some embodiments include a feature that forms a hole in a plication using the plication device, so that a portion of a medical implant may be passed through or linked to the hole the plications. Others of the embodiments are configured to couple an anchor to the plication as it is formed, so that a medical implant may later be coupled to the anchor.
While this application describes plication systems and methods with respect to the formation of plications in stomach tissue, the embodiments described herein have equal applicability for forming plications in parts of the body outside the GI system.
Generally speaking, system 10 includes a plicator 12 having a vacuum head 14 and a shaft 16. The system further includes a flexible anchor 18 for attachment to stomach tissue, a tissue penetrating tip element 20 having a cable 22, a mesh element 24, and a sheath 26.
Referring to
Referring once again to
A tubular cannula 50 extends through the shaft 16 as shown in
Anchor 18 includes a distal tab 52 and a proximal tab 54 on opposite ends of a central portion 56. Anchor 18 is a flexible element formed of silicone or other flexible, biocompatible material. Its properties permit it to be deformed into the orientation shown in
As best seen in the cross-section view of
Referring again to
It is appropriate to note that anchor 18 may take many alternate forms without departing from the scope of the invention. For example, in one alternative embodiment shown in
Referring again to
Cable 22 is coupled to the proximal portion of the tip element 20. Cable 22 preferably includes a series of barbs 74, teeth, or other engagement elements. As will be described in connection with
As discussed, the system is preferably designed to pass material between the serosal tissue layers so as to faciliate serosal tissue bonding. The material may be a synthetic or non-synthetic mesh (formed of nitinol or other material), porous or non-porous material, slotted material, or any other material through which adhesions will form or onto which tissue will grow. Examples include, but are not limited to, polypropylene, materials sold under the trade names Goretex or Dacron, or tissue graft material such as the Surgisis material sold by Wilson Cook Medical, Inc. The material may be treated with tissue-ingrowth promoting substances such as biologics.
The delivered material can be constructed into any shape or configuration that will achieve its purpose of promoting strong serosal adhesions. As illustrated in
One method of using the system of
In preparation for use, tip 20, cable 22, mesh element 24, and sheath 26 are assembled for insertion into cannula 50. Specifically, as shown in
Referring to
Next, the assembled plicator 12 is passed into the stomach S via the esophagus as shown in
Referring to
At this point, the tissue is ready for advancement of the tip member 20 through the tissue, as well as deployment of the mesh tube 24 into the pocket 100. Advancement of the tip and deployment of the mesh may be performed in a single step, or they may be formed as a sequence of steps. For simultaneous advancement and deployment, sheath 26 is advanced in a distal direction, thereby driving the tip 20 distally through the tissue walls 102 defining the pocket 100. If the forces of friction between the tubular mesh element 24 and the sheath 26 are sufficiently large, the advancing sheath carries the mesh tube 24 into the pocket. Alternatively, a pushing mandrel 86 (shown in
Many alternative structures useful for separately or simultaneously applying pushing forces to the tip element 20 and the mesh element 24 are readily conceivable and may also be used.
Regardless of the mode of deployment, as the tip member 20 is advanced, its pointed distal end moves into contact with the spring element 66 on the anchor 18, causing tabs 68 (
The cable 22 remains attached to the tip element 20 and thus extends through the walls 102, through catch 58 and spring element 66, and through the cannula 50. The mesh tube 24 remains disposed around the cable 22.
The next series of steps are geared towards drawing the distal and proximal tabs 52, 54 of the anchor 18 towards one another, so as to enclose the mesh element 24 within the pocket 100. Referring to
The opposed forces between cable 22 and vacuum head 14 result in compression of the anchor 18 and the mesh tube 24 into the illustrated positions. As the cable 22 tightened, the spring element 66 of the anchor sequentially engages barbs on the cable 22. Once tension on cable 22 is released, the spring element 66 remains engaged with the adjacent barb on the cable so as to retain the anchor in the compressed position. Finally, the cable 22 is clipped, and the plicator 12 is withdrawn from the body, leaving the anchor 18 and mesh positioned as shown in
It should be noted with reference to
One alternative system illustrated in
In another alternative system shown in
Paddle 110 includes an elongate tube 112 that extends through the esophagus and is connectable to a vacuum source 114 positioned outside the body. Paddle 110 is formed of silicone or other flexible material suitable for long term implantation. Loop 2 is integrally coupled to the paddle. An elongate spine 116 is positionable against the paddle 110, and may include elements for temporarily engaging the paddle 110. Spine 116 includes pull wires or other features that may be manipulated from outside the body to deflect it and the adjacent paddle 110 into nested curved positions as shown in
An alternative system illustrated in
A flexible anchor 18f is seated within vacuum head 14f prior to use, similar to the positioning of the anchor 18 of the first embodiment shown in
Prior to use, the leg 22f is positioned within the lumen 48f of shaft 16f. During implantation of the anchor 18f, serosal tissue is drawn into the vacuum head 14f as shown in
Although the method of implanting the anchor 18f may end with the anchor 18f positioned as shown in
The jaws are clamped as shown in
In alternate plication methods, one or more sclerosing agents may be used in conjunction with or in lieu of the mesh element 24. Examples of sclerosing agents include but are not limited to Sodium Tetradecyl Sulfate (STS), Poliodocanol, Chromated Glycerin, Hypertonic saline, Sodium Morrhuate, Sclerodex (hypertonic saline in combination with Dextrose). Other substances that may be positioned with or in place of the mesh element 24 include methylmethacrylate, glues, adhesives, and biorubbers. These may be injected at the time of mesh placement or loaded into the mesh itself and eluded out over a period of time.
Once the agent is administered, steps similar to those described above may be performed to form the plication and to attach anchor 18a to the plication. Tip 20a (
In certain instances, it might be desirable to completely close the serosal pocket 100 to avoid leakage of injected agents into the peritoneal cavity. The pocket 100 may be sealed using an elongate clamp 90 endoscopically introduced into the stomach and clamped over the tissue pocket to press the serosal surfaces into contact with one another as shown in
An alternative method for forming plications using sclerosing agents to accelerate scar formation is illustrated in
As with previous methods, a pocket 100 or depression is formed on the serosal surface by drawing a portion of the stomach wall inwardly using a vacuum head 14f or other device introduced transorally into the stomach. A delivery member 130 is next introduced into the stomach. The delivery member 130 is an elongate tubular device having a lumen through which a sclerosing agent may be delivered, as well as a delivery means for delivering a place holding element 132 into the pocket 100. The delivery member 130 preferably includes a sharpened distal tip capable of penetrating the stomach wall.
As shown in
In one embodiment, the place holding element 132 may be delivered by pushing it through the lumen of the delivery member using a pushing mandrel. The place holding element might be a section of material that has a compact size and shape for delivery by the delivery member 130, but that expands upon delivery into the pocket 100. To give a few examples, the element may be formed of a structure having mechanical properties (e.g. sponge or nitinol mesh) that cause it to self-expand when released from the delivery member, or it may be an inflatable balloon tethered to an inflation lumen in the delivery member, or it may be a swellable hydrogel that will increase in volume once exposed to fluid within the pocket (e.g. the sclerosing agent or other fluid injected into the body, and/or fluids present in the peritoneal cavity). In alternate embodiments the place holding element might be delivered directly to the outside of the stomach using laparoscopic methods.
The element may be formed of a permanent or semi-permanent material (such as the examples described in connection with mesh element 24 above), that will reinforce the plication and/or work together with the sclerosing agent to promote scar formation. Alternatively, the element may be one that is biodegradable or bioabsorbable over a period of time.
Once the place holding element 132 has been positioned, the vacuum head 14f or a separate clamping device is utilized to clamp and seal the pocket 100 as shown in
Sealing forces continue to be applied to the pocket 100 until ample scar tissue has formed within the pocket to maintain the P. Once adequate scar tissue has been formed, sealing forces may be released and the vacuum head removed from the stomach. If the balloon of
It should be noted with reference to
In many instances it may be desirable to form serosal tissue plications of the type shown in
When a cutout plication is formed, it may be beneficial to form a seal around the cutout C using staples, sutures or adhesives etc so as to prevent food material and/or gastric juices from passing between the opposed layers of serosal tissue where they can potentially cause infection between the tissue layers or within the extra gastric space. In the
A second preferred embodiment of a plication system 10g, shown in cross-section
In general, system 10g includes a plicator 12g comprising a vacuum head 14g having a vacuum chamber 28g and a shaft 16g defining a lumen 48g. A port 49 is fluidly coupled to the vacuum chamber 28g and is connectable to an extracorporeal source of suction (e.g. a syringe or a vacuum pump).
An elongate staple driver 150 is longitudinally moveable within the lumen 48g. Staple driver may take the form of an elongate tube having a broadened annular head 152 positioned within the vacuum head 14g. A plurality of staples 154 is arranged adjacent to the staple head, preferably in a circular arrangement, but alternative arrangements are equally suitable. A circular anvil 156 is positioned within the vacuum head 14g opposite the staples. Staple driver head 152 is moveable in a distal direction to advance the staples across the vacuum chamber and into contact with the anvil 156.
The system includes a tubular cannula 50g for forming the cutout C in the tissue. Cannula 50g extends through the lumen of the staple driver 150, with its tissue-penetrating distal end oriented towards the vacuum chamber 28g. Cannula 50g may be advanced in a distal direction to extend through the vacuum chamber 28g and into a tubular channel 158 formed in the distalmost section of the vacuum head.
An elongate rod 160 having a pointed distal barb or tip 20g extends through the lumen of the cannula 50g. Tubular mesh element 24g surrounds a portion of the exterior surface of rod 160, with its distal end adjacent to the proximal end of tip 20g. Mesh element 24g is preferably a self-expandable tubular element of the type described in connection with
System 10g further includes a proximal handle (not shown) that remains outside the body during use of the system. The handle includes actuators, pull wires, push rods, or equivalent components that facilitate longitudinal advancement and withdrawal of the tip 20g, cannula 50g, retention sleeve 162, and staple driver 150, as well as deflection or articulation of the components, as needed to carry out the method for using the system described in the following section.
A method for using the system of the second embodiment will next be described. First, the vacuum head 14g is introduced into a stomach and endoscopically positioned with the vacuum chamber facing the interior surface of the stomach wall. This step is similar to the step illustrated in
Suction is applied to the vacuum head 14g via port 49 to draw a portion of the stomach wall into the chamber as shown in
Next, the rod 160 is advanced to drive tip 20g through the sections S1, S2. Tip 20g is captured within the channel 158 adjacent to anvil 156. The mesh element 24g is carried by the rod 160 into position between the stomach wall sections S1, S2. The retention sleeve 162 is retracted, allowing the mesh element 24g to expand to the position shown in
After the mesh element 24g is deployed, the tissue is compressed to the position shown in
The cannula 50g and tip 20g are withdrawn into shaft 16f, and the vacuum head 14g is separated from the tissue, leaving the cutout reinforced plication as shown in
A third embodiment of a plicator 200 is shown in
Plication head 202 includes a tapered, atraumatic, distal tip 210 and a proximal portion 212 coupled to one another by one, two or more hinge member 214. In the
Referring to
Each of the proximal hinge plates 216b includes an inwardly-extending camming surface 238. The hinge plates include proximal pivots 240 such that distally-oriented pressure against camming surfaces 238 causes the hinge plates 216b to pivot about the pivots 240 into the position shown in
Proximal portion 212 of the plication head 202 includes a staple cartridge 242 containing staples arranged in an annular arrangement (not visible in the drawing), and a staple driver 244 positioned to drive staples from the distal end of the cartridge 242 when it is advanced in a distal direction into contact with the staples. Staple driver 244 may include a tissue penetrating element 248 (
An anvil 246 on the distal tip 210 is positioned to receive the prongs of staples driven by staple driver 242 and to fold the prongs into a closed position. Staple cartridge and anvil arrangements are well known in the surgical and endoscopic stapling art and need not be discussed in further detail. The staples (and sutures) described for use herein may be permanent or bioerodible/biodegradable.
As with the previously discussed methods, a method of using the plication system 200 of the third embodiment is carried out under visualization using an endoscope advanced via the esophagus into the stomach.
In preparation for use, the plication head is positioned with the hinge members 214 in the streamlined position shown in
Next, as shown in
Once tissue is drawn in to the vacuum chamber 217, additional fluid is directed into the hydraulic chamber 220 to advance the outer piston 226 until the hinge members 214 are in the fully expanded position shown in
The staples fold against the anvil 246. After stapling, the hinge members are moved to the collapsed position shown in
In the illustrated embodiment, the staple pusher 244 is driven by the injection of hydraulic fluid into the cylindrical piston 226. The fluid drives plunger 236 distally into contact with the staple pusher 244, which in turns drives through the cartridge 242 to advance the staples.
Reinforcements of various types may be implanted in or on plications formed using the plication system. Such reinforcements may function to reinforce the staple array, help to more evenly distribute the forces applied to the tissue by the staples, and/or facilitate bonding between the opposed serosal layers. Suitable reinforcements include ones positionable on or between the serosal tissue layers (“serosal side reinforcements”), as well as those delivered on the side of the mucosal tissue (“mucosal side reinforcements”).
Serosal side reinforcements have been discussed in connection with the first and second embodiments. A reinforcement similar to mesh element 24 described in connection with
In an alternative embodiment of a serosal side reinforcement shown in
Mucosal side reinforcements may take the form of reinforcements that are positioned on or adjacent to one or both of the mucosal surfaces lining the “pinch” of tissue that will form the plication. These reinforcements may be features of the staples or staple arrays, or they may be separate components engaged by staples as the staples are advanced through the tissue.
Referring to
In alternative embodiments, staples are linked together by reinforcing members formed of metallic or polymeric materials, such as nitinol, titanium, stainless steel PEEK, or other biocompatible materials including those that are bioerodible/biodegradable. According to these embodiments, the reinforcing members are positioned on one or both of the mucosal sides of the “pinch” of tissue engaged by the plication system such that they are captured by staples being driven through the tissue. In a preferred embodiment, the staples capture a cartridge side reinforcing ring 278 (
The reinforcing rings are preferably provided separate from the staples although they instead may be integral with the staples. In the illustrated embodiment, ring 280 is positioned against the staple anvil 246 as shown in
Rings 278, 280 are shown as generally circular, although alternative reinforcements of different shapes and patterns may also be used, including those shaped to accommodate linear, oval and other staple patterns.
A first application shown in
In the method shown in
In either embodiment, if the implant 4, 4a is to be removed or replaced with an implant of different dimensions (e.g. so as to slow the rate of weight loss following a period of significant weight loss, or to increase the rate of weight loss), endoscopic instruments may be used to withdraw the implant from the cutouts C and to remove the implant from the stomach.
In another embodiment shown in
As is evident from above, the disclosed endoscopic systems function to draw a tissue into the stomach to form a depression on the exterior surface of the stomach, and staple (or suture, or fasten or adhere etc) the opposed stomach wall sections lining the depression together another to form a plication. The system may additionally place material of a type that will promote strong tissue adhesion within the depression (on the exterior of the stomach) and retain the material between the serosal surfaces to enhance. Additionally or alternatively, mucosal reinforcements such as structures that interconnect the staples may be implanted. While these systems provide convenient embodiments for carrying out this function, there are many other widely varying instruments or systems may alternatively be used within the scope of the present invention. Moreover, the disclosed embodiments may be combined with one another in varying ways to produce additional embodiments. Thus, the embodiments described herein should be treated as representative examples of systems useful for forming endoscopic tissue plications, and should not be used to limit the scope of the claimed invention.
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.
This application claims the benefit of U.S. Provisional Application No. 60/723,160, filed Oct. 3, 2005; U.S. Provisional Application No. 60/754,417, filed Dec. 28, 2005; and U.S. Provisional Application No. 60/825,534, filed Sep. 13, 2006.
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