Patent Application
20140379026
The present disclosure relates generally to medical devices, and more specifically, to tissue opening or wound treatment devices.
People may suffer from many different types of tissue damage. For example, tissue may be ripped, torn, abnormally formed, or otherwise punctured. Tissue damage may include a single opening in the tissue, which may vary in size, or may include multiple openings in the tissue. A larger tissue opening or wound may be harder to treat than a smaller tissue opening or wound—for example, it may be harder to encourage and protect tissue growth (e.g., from physical damage from outside or within the body, from biological assault, etc.). As an example, inserting sutures into tissue bordering the opening can further damage the tissue, preventing re-growth to fill the openings. Similarly, when a portion of tissue has multiple openings or wounds, each separate opening or wound may create treatment difficulties—for example, the openings or wounds may be spread out from one another and may be too small to treat on their own.
The information included in this Background section of the specification, including any references cited herein and any description or discussion thereof, is included for technical reference purposes only and is not to be regarded as subject matter by which the scope of the invention as defined in the claims is to be bound.
One example of the disclosure may include a healing device for sealing or closing wounds or fistulas and promoting tissue growth. The healing device may be configured to be operably connected or coupled to tissue surrounding a tissue opening, such as a fistula. The healing device may include a first sealing member configured for placement over a first opening of at least one fistula in a first surface of the tissue. The first sealing member may be configured to be operably connected or coupled to the first surface of the tissue near the first opening and to be positioned at least partially over the first opening. The healing device may also include a second sealing member configured for placement over a second opening of the at least one fistula in a second opposing surface of the tissue. The second sealing member may be configured to be operably connected or coupled to the second surface of the tissue, such that an upper surface of the second sealing member is positioned at least partially over the tissue opening. The first and second sealing members may be configured to be operably connected or coupled together. The healing device may further include a growth-enhancing layer operably connected or coupled to, incorporated into, and/or blended into at least one of the first sealing member and the second sealing member (e.g., to at least a portion thereof). The growth-enhancing layer may be configured to be at least partially received within the tissue opening. In some embodiments, the growth-enhancing layer may comprise at least one polymer selected from the group consisting of collagen, polyglycolic acid (PGA), polylactic acid (PLA), poly-L-lactide acid (PLLA), polyglycolic-lactic acid (PGLA), poly-DL lactic acid (PDLLA), or a combination thereof.
In certain embodiments, a device may comprise more than one sealing member that is configured for placement over the at least one fistula in the first surface of tissue, and/or more than one sealing member that is configured for placement over the at least one fistula in a second opposing surface of the tissue. In some embodiments, a device may comprise more than one growth-enhancing layer.
Some embodiments of devices described herein may use one or more securing members, such as sutures, to help narrow a tissue opening, such as a fistula, or to hold internal material or a seal in place within a tissue opening. The securing members may, for example, be positioned within a fistula tract. Certain embodiments of devices described herein may comprise one or more tensioning members, such as one or more sutures (e.g., connected or coupled to one or more sealing members of a device). At least one of the tensioning members may be fixedly or slidably coupled to one or more sealing members of the device.
Certain embodiments of devices described herein may comprise a proximal sealing member and a distal sealing member, and one or more biomaterials coated or otherwise included on a proximal side of the distal sealing member and on a distal side and/or a proximal side of the proximal sealing member. Some embodiments of devices described herein may include at least one sealing member and at least one growth-enhancing layer operably connected or coupled to, incorporated into, and/or blended into a surface of the at least one sealing member.
Another example of the disclosure may include a closure device for sealing or closing a tissue wound. The device may include a first support surface configured to be operably connected or coupled to a first surface of a tissue near the wound. The first support surface may also be configured to at least partially cover a first region (e.g., opening) of the tissue wound. The device may also include a second support surface configured to be operably connected or coupled to the first support surface and the tissue near the wound. The second support surface may also be configured to at least partially cover a second region (e.g., opening) of the tissue wound. The device may further include a first layer configured to be operably connected or coupled to at least one of the first and second support surfaces. The first layer may comprise allograft and/or at least one polymer selected from the group consisting of collagen, polyglycolic acid, polylactic acid, poly-L-lactide acid, polyglycolic-lactic acid, poly-DL lactic acid, or a combination thereof.
In some embodiments, a wound closure device for sealing or closing a tissue wound may comprise a first sealing member configured for placement over a first region (e.g., opening) of the tissue wound and configured to extend beyond the tissue wound to cover margins of the tissue surrounding the tissue wound, a second sealing member configured for placement over a second region (e.g., opening) of the tissue wound and configured to extend beyond the tissue wound to cover margins of the tissue surrounding the tissue wound, and a first layer coupled to at least one of the first sealing member and the second sealing member, where the first layer comprises at least one polymer selected from the group consisting of collagen, polyglycolic acid (PGA), polylactic acid (PLA), poly-L-lactide acid (PLLA), polyglycolic-lactic acid (PGLA), poly-DL lactic acid (PDLLA), or a combination thereof.
In some embodiments, a wound sealing or closure device may comprise a sealing member, and a plurality of feet extending from a bottom side of the sealing member and comprising one or more bioabsorbable materials. The feet may be configured to be enveloped in and bond with tissue surrounding a wound after the wound sealing device is held over the wound and against the tissue under pressure for an extended period of time. The sealing member may comprise one or more bioabsorbable, biocompatible and/or implant-grade materials, and/or one or more resorbable materials that are capable of being resorbed into the tissue over time. In some cases, one or more bioabsorbable but non-implant-grade materials may be used. In some such cases, the non-implant-grade materials may, for example, be coated with one or more implant-grade materials.
In certain embodiments, a device for closing or sealing a wound or fistula may comprise a sealing member comprising an inner member and an outer member, with a suture configured to arrange the sealing member in a tissue opening, such as a fistula opening. The device may be sutured prior to, during, and/or after its installation.
A further example of the disclosure may include a method of closing or sealing a wound. The method may include sandwiching a tissue surrounding the wound between a first sealing member and a second sealing member. After the tissue is sandwiched between the two sealing members, tension may be provided to hold the tissue, the first sealing member, and the second sealing member together. Once under tension, the tissue, the first sealing member and the second sealing member may be operably connected or coupled together in a tensioned position.
In certain embodiments, a method of closing or sealing a wound may comprise positioning a section of tissue defining a wound between a first sealing member and a second sealing member, providing tension between the first sealing member and the second sealing member across the intermediate tissue, and coupling the first sealing member and the second sealing member together across the tissue to seal the wound and contact the intermediate tissue.
In some embodiments, a method of closing or sealing a wound may comprise positioning a section of tissue defining a wound between a first sealing member and a second sealing member, holding the first sealing member and the second sealing member in place across the intermediate tissue without applying tension to the intermediate tissue, and coupling the first sealing member and the second sealing member together across the tissue to seal the wound and contact the intermediate tissue.
Some embodiments of devices described herein may include sealing members comprising multiple layers and/or may comprise multiple layers of growth-enhancing materials. Certain embodiments of devices described herein may comprise a sealing member including a growth-enhancing material embedded or incorporated therein. In some embodiments, one or more tissue growth-promoting materials may be positioned between two sealing members. The tissue growth-promoting material(s) may be part of the device or may separate components that are later added to the device. In some cases, one or more devices and/or sealing members may be provided in a kit along with one or more tissue growth-promoting materials.
This summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter. A more extensive presentation of features, details, utilities, and advantages of the present invention as defined in the claims is provided in the following written description of various embodiments of the invention and illustrated in the accompanying drawings.
These and other aspects and embodiments will be described in further detail below, in reference to the attached drawing figures.
Some embodiments described herein comprise a device for covering and assisting in closing one or more tissue openings. Such a healing device may be used to cover tissue openings or tears and may be particularly effective for patching or closing relatively large wounds (e.g., wounds larger than 2 centimeters in diameter), as well as multiple wounds or small openings dispersed across a larger area. In one exemplary implementation, the healing device may include a first sealing member or first support surface and a second sealing member or second support surface. The first and second sealing members may be tensioned together via a tensioning member (e.g., a tensioning cord) operably connected to each sealing member. For example, the two sealing members may be positioned so that the first sealing member is located substantially over the second sealing member, with the damaged tissue at least partially positioned between the two sealing members. The tensioning member may then be pulled or otherwise tensioned, pulling the first and second sealing members together. Other components that may be pulled or otherwise tensioned may alternatively or additionally be used to bring the first and second sealing members toward each other.
The two sealing members may be secured in place in the tensioned position via securing members (e.g., sutures), which may be connected to the first and second sealing members through a portion of the tissue. The securing members holding the two sealing members together may be tensioned against the sealing members and not the tissue. In this way, the securing members may not pull or tug on the tissue, although a tensioning force is being exerted by the securing members through the tissue. This configuration may allow the healing device to cover the opening or wound without causing substantial damage to the tissue surrounding the opening. In other embodiments, the two sealing members may be secured together in correlative tension over a wound via a fastening or securing device. For example, the first sealing member may include a ball and stem, which may be inserted in a snap-fit configuration into a receiving cavity in the second sealing member. In some embodiments, sealing members may be held in place without the application of tension on the tissue therebetween. In certain embodiments in which tension is applied to sealing members, the tension may lessen over time (e.g., going to zero). This may happen, for example, if the tissue between the two members remodels and moves away from a location in which the tissue is under compression as a result of the tension.
In some embodiments, the tensioning wire may be used to press an interior sealing member against the tissue in order to hold the interior sealing member in place while it is connected to an exterior sealing member. In these embodiments, the tensioning wire (or wires) may comprise a resilient member having a hook shape on one end. The tensioning wire may be inserted into an opening within the tissue and an insertion aperture within each sealing member. The tensioning wire may be restrained in a generally straight configuration (e.g., through an introducer) as it is inserted through the tissue opening and the apertures in the sealing members. After the tensioning wire exits a bottom of the insertion aperture, the resilient member may return to a preformed hook shape to be positioned against a bottom surface of the second, interior sealing member. The tensioning wire may then be tensioned (e.g., by being pulled proximally by a surgeon), such that the hook is pressed against the bottom surface of the second, interior sealing member, thereby holding the interior sealing member in place against an interior wall of the tissue. The two sealing members may then be operably connected together (e.g., via sutures, stitches, etc.). The tensioning wires may hold the sealing members in a tensioned configuration around the tissue so that the sealing members can be connected together, but may be removed after the sealing members are secured in place.
The two sealing members may each include one or more layers of collagen and/or other tissue growth enhancers. The collagen and/or growth-enhancing layers may promote tissue growth on the two sealing members, thereby helping to fill or otherwise heal the opening. Additionally, the two sealing members may be positioned to cover or protect the opening to promote the healing and re-growth process. Further, in embodiments utilizing the tensioning wire, the collagen may be inserted as a plug into the insertion apertures, so that the openings in the tissue may be substantially filled.
In other embodiments, a single sealing member may be operably connected to tissue around a tissue opening. The sealing member may include bioabsorbable securing feet spaced intermittently around a bottom surface of the sealing member. The sealing member may then be positioned substantially over the opening, such that the securing feet may be positioned above non-damaged tissue (i.e., solid tissue). Once the sealing member is in position, the sealing member may be secured to the tissue (e.g., via tape, gauze, etc.). The feet may be configured to exert point pressure upon the skin or tissue of the user. As the feet press into the skin or tissue, the feet may be integrated with or enveloped into the skin. Thus, the sealing member may be substantially even with a first surface of the tissue as the feet “sink” into the tissue. In some embodiments, the sealing member and/or feet may be bioabsorbable so that they may eventually be absorbed into the skin or other tissue of the user as part of the healing process. The sealing member may further be coated with an environmentally resistant coating to aid in protecting the wound.
As shown in
With continued reference to
The first and second sealing members 114, 116 may comprise one or more bioabsorbable materials and/or may comprise a substantially fluid-impermeable coating on an outer surface. The bioabsorbable material or materials may allow the sealing members 114, 116 to eventually be absorbed by the body of the person 100, so that the sealing members 114, 116 may not have to be removed. The impermeability of an outer surface of the sealing members 114, 116 may allow the sealing members 114, 116 to act as a seal for the large-opening fistula 106, so that bacteria, fluids, and other potentially harmful substances may be substantially prevented from entering or exiting the fistula 106. In this manner, the sealing members 114, 116 may function as a protective cover for the fistula 106.
As shown in
A growth-enhancing layer 118 may be positioned on a least a portion of a surface of either or both of the first and second sealing members 114, 116. The growth-enhancing layer 118 may comprise collagen and/or one or more other tissue-like materials that provide a framework allowing the tissue to grow around and through the material. The growth-enhancing layer 118 may be positioned on each respective sealing member 114, 116 so that it may fill the fistula 106 when the healing device 110 is operably connected to the tissue 112.
As can be seen best in
To secure the two sealing members 114, 116 together, a tensioning cord 124 may be operably connected to the first sealing member 114 and fixed to the second sealing member 116 (see, e.g.,
Referring again to
Once the second sealing member 116 is positioned over the distal opening of the large-opening fistula 106, the tensioning cord 124 (which may already be operably connected to the second sealing member 116) may be inserted or pulled through the large-opening fistula 106. The tensioning cord 124 may be threaded through the cord aperture 128 in the first sealing member 114. The first sealing member 114 may then be positioned over the proximal opening of the large-opening fistula 106 and may extend over the margins of the surrounding tissue 112. As with the second sealing member 116, the growth-enhancing layer 118 may be positioned within the large-opening fistula 106. In other words, the first sealing member 114 may be positioned over the large-opening fistula 106 in a way that substantially aligns the growth-enhancing layer 118 within the large-opening fistula 106. A surgeon may then pull the tensioning cord 124 to pull the interior or distal sealing member 116 flush and tight against the inner wall 122 of the tissue 112.
Once the first and second sealing members 114, 116 are positioned over the large-opening fistula 106, the surgeon may provide an upward force on the tensioning cord 124, pulling it against the tissue between the first and second sealing members 114, 116. The surgeon may provide simultaneous downward pressure on the first sealing member 114 as well (e.g., by using his fingers). As the second sealing member 116 is displaced upwards, the tissue 112 may be compressed between the two sealing members 114, 116. Securing members 132 (e.g., sutures) may be inserted through the first sealing member 114, the tissue 112, and the second sealing member 116 to operably connect all three elements together in the tensioned or compressed position. The securing members 132 may be inserted through the securing apertures 130 on each the first sealing member 114. Alternatively, the surgeon may simply suture the first sealing member 114 to the second sealing member 116 about their perimeters. In this way, the sutures will pass through the margins of the tissue 112 and thereby hold the first and second sealing numbers 114, 116 in place. In some embodiments, at least some (e.g., all) securing members 132 that are used to hold the first and second sealing members 114, 116 in place may not pass through the tissue 112 at all when positioned at the target site. Rather, they may pass through the fistula 106. This may, for example, limit the likelihood of inadvertently forming new fistulas or causing other tissue damage by forming new holes in the tissue 112.
The securing members 132 (e.g., sutures and/or stitches) hold the first and second sealing members 114, 116 in place. The securing members 132 may be positioned so that the tensioning force exerted by each securing member 132 is exerted on the sealing members 114, 116, rather than the tissue 112. This may help prevent the securing members 132 from further damaging the tissue 112. Additionally, the use of multiple securing members 132 may distribute the tension force over a relatively large area, rather than the single, pinpoint location of just the tensioning cord 124. Further, the securing members 132 may be spaced apart from the fistula 106, where the tissue 112 may be torn or otherwise damaged. The healing device 110 thus offers a compelling alternative to other wound healing devices or methods that require suturing the wound closed. Such suturing may place significant tension and sheer forces on the margins of the tissue 112 around a wound, which may lead to further tearing of the tissue 112 (especially delicate tissues) and may further prevent or hinder tissue re-growth.
As the securing member 132 operably connects the first and second sealing members 114, 116 together in a tensioned configuration, the healing device 110 seals the large-opening fistula 106. This can be important in the context of enteroatmospheric fistulas, as negative pressure may help to promote healing of the abdominal wound 102. Without sealing the enteric fistula 106, negative pressure on the abdominal wound 102 would draw fluid and material out of the intestine or bowel through the fistula, thus contaminating the abdomen, which can lead to sepsis or other infection. Additionally, positioning the growth-enhancing layers 118 within the large-opening fistula 106 causes the growth-enhancing layers 118 to partially or fully plug the large-opening fistula 106 and to potentially promote growth of the tissue 112 within and across the large-opening fistula 106. For example, the growth-enhancing layers 118 may provide a structure for supporting and encouraging tissue growth within the large-opening fistula 106.
In another example, the healing device may be used to provide a tissue growth framework and protective layer for a tissue area with a large opening or multiple openings. For example,
The healing device 310 may be positioned over the tissue 312 and one or more tensioning wires 324 (
Once the sealing members 314, 316 are aligned, an insertion shaft 334 may be inserted through the plug aperture 330 in each sealing member 314, 316 and through an opening in the tissue 312, such as a fistula wound opening or an opening created for the purpose of operably connecting the healing device 310 (e.g., via a needle, punch, or scalpel). The insertion shaft 334 may be a generally hollow cylindrical shaft that is configured to approximately the same diameter as the plug aperture 330. Other embodiments of insertion shafts having different sizes and/or configurations may also be used, as appropriate.
After the insertion shaft 334 has been inserted, the tensioning wires 324 may be inserted therein.
Once the tensioning members 324 are in place adjacent the interior sealing member 316, a tensioning force F may be provided to the tensioning members 324. For example, a surgeon may pull the tensioning members 324 proximally, creating the tensioning force F. The tensioning force F may pull each tensioning member 324 upward toward the first sealing member 314 and as, the tensioning members 324 are curved upward, they may pull the second sealing member 316 toward the first sealing member 314. Multiple securing members 332 may then be used to secure the first sealing member 314, through the tissue 312, to the second sealing member 316. For example, the surgeon may suture the two sealing members 314, 316 together. The tensioning members 324 allow the sealing members 314, 316 to be secured in a tensioned position against the tissue 312 so that the healing device 310 may seal the fistulas 306a-306c.
The securing members 332 may be sutures, staples, or other connection devices that are passed through the sealing members 314, 316 and the tissue 312. While not shown here, in some cases a securing member 332 may couple a sealing member to tissue without also coupling the sealing member to another sealing member. In some embodiments, the securing members 332 may be positioned away from the margins of the damaged tissue 312 (i.e., away from the fistulas 306a-306c). The sealing members 314, 316 cover and seal the fistulas 306a-306c and may be held in place using only minimal sutures or other securing members 332, thus reducing the additional punctures to the tissue. As discussed above with respect to the healing device 110 illustrated in
The first sealing member 214 may be a disk or semi-circular shape and is configured to be positioned over the fistula 106 so as to substantially cover the fistula 106. The first sealing member 214 may also have a diameter larger than a diameter of the fistula 106, so that it extends over the tissue margins surrounding the fistula 106. Additionally, the first sealing member 214 may comprise one or more bioabsorbable materials and may have an impermeable coating, so that fluids, bacteria, or other materials may be substantially prevented from ingress and egress into and out of the fistula 106 when the healing device 210 is operably connected to the tissue 112.
Fastening or securing members 234 may extend from a bottom surface of the first sealing member 214. The fastening members 234 may include a stem 230 and a head 232 formed at a bottom end of the stem 230. The stem 230 may be a substantially cylindrical member and the head 232 may be a ball or semi-spherical shape. Other appropriate stem or head shapes and configurations may also be used. For example, a sliding tapered rod or other releasable locking member may be used (not illustrated), such that, when removed, it allows 232 to shrink in diameter. When moved forward, the sliding tapered rod like member may expand 232 to lock it into the receiving cavities 225.
The stem 230 may have a length approximately the same as a thickness of the tissue 112 so that the stem 230 extends through the tissue 112 and operably connects to the second sealing member 216. The head 232 is configured to be received within a corresponding cavity in the second sealing member 216. The head 232 may function as a keyed structure that fits within a corresponding shape of the opposing cavity within the second sealing member 216. While not shown here, in some cases, the second sealing member 216 may alternatively or additionally comprise one or more structures that fit within one or more corresponding cavities in the first sealing member 214.
The second sealing member 216 may have a disk or semi-circular shape that may be similar to or substantially the same as the first sealing member 214. Receiving cavities 225 are defined within an upper surface of the second sealing member 216. The receiving cavities 225 are configured to receive the heads 232 of the fastening members 234 in a snap-fit arrangement. For example, the receiving cavities 225 may be generally semi-spherically shaped to cradle and contain the ball-shaped heads 232 of the fastening members 234. Other suitable shapes may also be used.
The second sealing member 216 may be rotated, angled, compressed, or otherwise deformed and then may be inserted into the fistula 106 to be placed on the interior (distal) side of the tissue 212 (e.g., within an enteric cavity). The second sealing member 216 may then be positioned such that the receiving cavities 225 may be substantially aligned with and face the interior opening of the fistula 106. Additionally, at least a portion of the second sealing member 216 may be configured to extend over the tissue 112 surrounding the fistula 106. Once the second sealing member 216 is positioned adjacent the tissue 112, the growth-enhancing layer 218 may be positioned within the fistula 106 between the receiving cavities 225 on the second sealing member 216. The first and second sealing members 214, 216 may be press-fit together by applying pressure to each of their outer surfaces, or may be coupled to each other using any other suitable method. For example, in some embodiments, the second sealing member 216 may have a pulling member coupled thereto, and the pulling member may be pulled upon (e.g., while the first sealing member 216 is pushed upon) to bring the first and second sealing members together. The first sealing member 214 may thus be operably connected to the second sealing member 216 by inserting the head 232 of each stem 230 into a corresponding receiving cavity 225. The heads 232 and the receiving cavities 225 may operably couple together via a snap-fit or other appropriate fastening mechanism. In the embodiments described above, the snap-fit connections are also releasable, so that the sealing members 214, 216 may be released from one another.
As can be seen in
The sealing member 414 may be relatively thin and may have any suitable shape. In some embodiments, the sealing member 414 may be formed of one or more bioabsorbable materials. In certain embodiments, an outer surface of the sealing member 414 may be coated with an impermeable coating layer 420. The sealing member 414 is configured to be positioned over, and to substantially cover, a tissue or wound opening 102. For example, as shown in
The support feet 418 may comprise one or more bioabsorbable materials, and are configured to support the sealing member 414 on the tissue 112. The support feet 418 provide multiple pressure points on the tissue 112. As the healing device 410 is continuously held against the tissue 112 under pressure (via the attachment member), the pressure points exerted by the feet 418 may cause the tissue 112 to re-configure and envelope a portion, if not all, of the feet 418. This may cause the feet 418 to “sink” into the tissue. For example, when the healing device 410 is first coupled to the tissue 112, the sealing member 414 may be positioned substantially over the wound opening 102, with the perimeter of the healing device 410 extending over the margins of a first surface 120 of the tissue 112. Then, after the feet 418 have been substantially received within the tissue 112, the sealing member 414 may be substantially aligned with or rest on a portion of the first surface 120 of the tissue 112. The bioabsorbable material of the feet 418 may promote tissue bonding at small points in the tissue 112 surrounding the wound 102 and may act as sutures or other securing members. Further, the bioabsorbable material of the sealing member 414 is provided to promote new tissue growth across the wound opening 102. In some implementations, additional collagen or other tissue growth frameworks may be placed in the wound 102 under the healing device 410, in order to further promote new tissue growth over the wound 102. Additionally, the impermeable coating layer 420 may prevent the healing device from degrading or decomposing too quickly due to exposure to outside agents, such as soap and water, dust, dirt, chemicals, etc.
The foregoing description has broad application. For example, while embodiments disclosed herein may focus on closing larger fistulas or multiple fistulas in a condensed area, the concepts disclosed herein may equally apply to closing other type of wounds and openings. Similarly, although the tissue openings and applications may be discussed with respect to humans, the devices and techniques disclosed herein are equally applicable to other animals. Accordingly, the discussion of any embodiment is meant only to be exemplary and is not intended to suggest that the scope of the disclosure, including the claims, is limited to these examples.
All directional references (e.g., proximal, distal, upper, lower, upward, downward, left, right, lateral, longitudinal, front, back, top, bottom, above, below, vertical, horizontal, radial, axial, clockwise, and counterclockwise) are only used for identification purposes to aid the reader's understanding of the present disclosure, and do not create limitations, particularly as to the position, orientation, or use of this disclosure. Connection references (e.g., attached, coupled, connected, and joined) are to be construed broadly and may include intermediate members between a collection of elements and relative movement between elements unless otherwise indicated. As such, connection references do not necessarily infer that two elements are directly connected and in fixed relation to each other. The exemplary drawings are for purposes of illustration only and the dimensions, positions, order and relative sizes reflected in the drawings attached hereto may vary.
The above specification, examples and data provide a complete description of the structure and use of exemplary embodiments of the invention as defined in the claims. Although various embodiments of the claimed invention have been described above with a certain degree of particularity, or with reference to one or more individual embodiments, those skilled in the art could make numerous alterations to the disclosed embodiments without departing from the spirit or scope of the claimed invention. For example, features disclosed with respect to one embodiment may be used in other embodiments, as appropriate. Other embodiments are therefore contemplated. For example, in some embodiments, an integral, one-piece or unitary device may be used to treat tissue openings or wounds. The device may be placed in a tissue opening in an elongated configuration, and may then be converted into a configuration in which it is no longer elongated and instead forms a double-lipped seal. In certain embodiments, a device described herein may comprise one or more shape-memory and/or super-elastic materials, such as Nitinol. This may allow the device to be inserted into a target site in one configuration (e.g., straight), and to later convert into a shape in which the device comprises two sealing members that are held together. It is intended that all matter contained in the above description and shown in the accompanying drawings shall be interpreted as illustrative only of particular embodiments and not limiting. Changes in detail or structure may be made without departing from the basic elements of the invention as defined in the following claims.
The present application claims priority to U.S. Provisional Patent Application No. 61/837,598, entitled “Devices and Methods for Treating Wounds,” filed on Jun. 20, 2013. The full disclosure of the above-listed patent application is hereby incorporated by reference herein.
| Number | Date | Country | |
|---|---|---|---|
| 61837598 | Jun 2013 | US |
