Patent Application
20240000455
The present patent application is generally related to surgical procedures, and is more specifically related to systems, devices and methods for closing wounds and promoting efficient healing of wounds.
During a surgery, a surgical incision is a cut made through the skin and/or soft tissue to facilitate an operation or procedure. In many instances, multiple incisions may be necessary. In general, a surgical incision is made as small and unobtrusive as possible to facilitate safe and timely operating conditions.
At the end of a surgical procedure, the surgical incisions must be closed. Over the years, many different techniques have been developed for closing surgical incisions. One widely used technique involves using sutures having a single knot or a series of knots. In recent years, absorbable sutures and barbed sutures have been used for closing surgical incisions. In addition, surgical tacks have been used for closing surgical incisions, which reduces the amount of time required to close the surgical incisions.
Other system for closing wounds and incisions involve the use of mesh tapes that are adhered to skin. With these systems, skin or tissue parts separated by the incision are approximated or brought into close proximity by forming as narrow a gap as possible in the area of the surgical incision. The approximate incision is then covered by an adhesively attached mesh tape, which holds the skin or tissue in closed apposed arrangement until wound healing occurs after which the tape is removed.
For example, a skin closure system sold under the trademark DERMABOND® PRINEO® Skin Closure System by Ethicon, Inc. of Somerville, New Jersey, includes a mesh having a pressure sensitive adhesive and a polymerization initiator disposed on the mesh. The mesh is applied onto the skin over a wound, and a polymerizable cyanoacrylate-based adhesive is then applied on the mesh and bonds the mesh to the skin.
Another technical advance directed to closing surgical incisions without using sutures or surgical tacks is disclosed in commonly assigned U.S. Pat. No. 8,777,986 to Straehnz et al., the disclosure of which is hereby incorporated by reference herein. The '986 patent discloses an incision guide and wound closure device including a surgical mesh having a top surface and a bottom surface, and first and second incision guides affixed to the top surface of the surgical mesh. The bottom surface of the mesh is adhered to tissue using clear or translucent adhesive. The first and second incision guides have opposing alignment surfaces that are adapted to guide a cutting instrument for making an incision through the mesh and into the tissue. The device has a closing element that is moveable along the length of the respective first and second incision guides for drawing the first and second alignment surfaces toward one another for closing the incision opening in the tissue.
U.S. Patent Application Publication No. 2015/0314114, discloses a device adapted for dressing and treating wounds, skin lesions/ulcers, sores and burns, comprising at least one biocompatible membrane and at least one catheter coupled to the membrane.
U.S. Patent Application Publication No. 2014/0121649 discloses a surgical wound dressing assembly for a surgical tube wound or other device entrance into the body, comprising a cover layer, with adhesive on the outer perimeter of the underside of the cover layer, an absorbent ring secured to the underside of the cover, an interior clear window allowing the nurse or other medical personnel to view the wound site through the window for inspection for infection or bleeding, and a port formed in the window area to allow a tube or other device to pass through the wound dressing.
U.S. Pat. No. 10,993,708 to Quintero et al., assigned to Ethicon, Inc. of Somerville, New Jersey, the disclosure of which is hereby incorporated by reference herein, teaches a skin closure device having interrupted closure. The skin closure device includes a flat porous mesh that is elongated along a longitudinal axis, and that has an upper side, a lower wound facing side, and a central portion in the immediate vicinity of the longitudinal axis. The flat porous mesh has a plurality of pores and windows formed in the flat porous mesh. The windows are substantially larger than the pores and are arranged along the longitudinal axis in the central portion. A cross-linking or polymerization accelerator or initiator is disposed in or on the mesh, and a pressure sensitive adhesive disposed on at least a portion of the lower surface of the mesh.
Due to various comorbidities, some patients may require wound closure systems, some may require negative pressure wound therapy, some may require close monitoring using sensors, and others may require wound drainage, etc.
There is no single solution, however, that allows for surgical wound approximation, closure, controlled removal of exudate, maintenance of closure over the healing period, not requiring dressing changes, and allowing negative pressure to be applied controllably.
Thus, there remains a need for improved wound closure systems that may be used on patients suffering from a broad array of conditions. There also remains a need for a universal, customizable and/or highly versatile wound closure system that can be applied to wounds and accommodate additional modalities (e.g., a negative pressure wound therapy device; a sensor), or no additional modality, if none is required.
Patients with significant comorbidities typically require advanced wound closure approaches including appropriate skin tissue approximation/closure and negative pressure to minimize post-surgical complications and delays during recovery.
In one embodiment, a wound closure system preferably allows for surgical wound approximation, skin closure, exudate removal, maintenance of closure over the healing period, not requiring dressing changes, and/or allowing negative pressure to be applied controllably.
In one embodiment, a wound closure system preferably provides for controlled wound drainage, wound irrigation, wound cleansing, antimicrobial irrigation, pain medication administration, etc.
In one embodiment, a wound closure system preferably includes a mesh (e.g., a porous mesh) having a pressure sensitive adhesive (PSA) applied on both a bottom, skin-facing surface used for wound approximation and a top surface configured for securing one or more therapeutic devices, if desired.
In one embodiment, pressure sensitive adhesive may be applied to both the top and bottom surfaces of the porous mesh.
In one embodiment, the pressure sensitive adhesive is covered by liners (e.g., liner paper) that may be removed and/or peeled away to expose the pressure sensitive adhesive.
In one embodiment, the pressure sensitive adhesive applied to the bottom, skin-facing surface of the porous mesh is stronger or more densely applied than the pressure sensitive adhesive applied to the top surface of the porous mesh.
In one embodiment, a polymerization catalyst or accelerator may be disposed in or on the porous mesh for promoting or enhancing curing of a liquid adhesive.
In one embodiment, a wound closure system (also referred to herein as a skin closure system) preferably includes a porous mesh that is coated on both sides with a pressure sensitive adhesive. The pressure sensitive adhesive applied to the bottom, skin-facing surface is used to approximate or close wound edges (also referred to herein as skin edges), while the pressure sensitive adhesive applied to the top surface of the porous mesh provides a sticky surface (due to the PSA) that allows for the placement (with opportunity to reposition) one or more therapeutic devices on top of the porous mesh, such as drainage tubes that may be connected to negative pressure pumps for draining wound exudate. The therapeutic devices may also allow for the post-operative introduction of medications, or allow sensors to be placed on the porous mesh for monitoring the wound. Once the one or more therapeutic devices are in place and the wound is approximated, a rapidly polymerizable or cross-linkable liquid adhesive may be applied over the deployed porous mesh and the one or more therapeutic devices secured atop the porous mesh.
When cured, the liquid adhesive preferably forms an air-tight or waterproof seal around the approximated wound or incision.
In one embodiment, a method of using a wound closure system may include removing the first liner from the skin-facing side of the mesh, and positioning the mesh with the skin-facing side on a wound for approximating the wound.
In one embodiment, a method may include removing the second liner from the opposite, top surface of the mesh, and positioning a therapeutic device (e.g., a negative pressure wound therapy device; a sensor; a medical device; an accessory, etc.) over the top surface of the mesh.
In one embodiment, after initial placement atop the mesh, the therapeutic device may be pulled away from the mesh and repositioned one or more times over the top surface of the mesh. It may be necessary to reposition a therapeutic device to achieve an optimal or better therapeutic benefit.
In one embodiment, a rapidly polymerizable adhesive may be applied on top of the mesh and on top of at least a portion of the therapeutic device.
In one embodiment, the adhesive is allowed to polymerize for binding the porous mesh to skin and/or the wound, and to further bind the therapeutic device to the porous mesh.
In one embodiment, a wound closure system preferably includes an adhesive mesh that is placed on an incision to close the incision. In one embodiment, both sides of the adhesive mesh have a pressure sensitive adhesive applied thereto. One side of the adhesive mesh is in intimate contact with the skin and is used to approximate wound edges, and the other side of the adhesive mesh has pressure sensitive adhesive used to precisely place tubing and other accessories (e.g., a sensor; a negative pressure wound therapy device) at the incision line.
In one embodiment, a drain tube having holes and/or slits may be placed in contact with the top surf ace of the mesh for adhering to the pressure sensitive adhesive applied to the top surface of the mesh. In one embodiment, the drain tube may have two ends, a first end coupled with a vacuum for draining exudate, and a second end including an inlet port for injecting fluids, saline, or medication, which may be infused over the approximated wound or incision. A primary function of the drain tube is to drain exudate from the incision.
The above-described wound closure system is highly customizable, whereby medical personnel may adjust the length of the drain tube, as necessary, and may choose which types of therapeutic devices should be secured to the top surface of the mesh (e.g., choose which type of sensors are required to monitor the approximated incision).
In one embodiment, a topical skin adhesive may be applied over the top of a therapeutic device (e.g., an elongated tube) that is secured to the top surface of the mesh. The tubing and therapeutic devices (e.g., sensors) may be aligned with the incision line. Once cured, the adhesive preferably forms a strong, air-tight seal around the incision. The adhesive may also form a waterproof and/or antimicrobial barrier, and may further enable medical personnel to monitor the wound healing process. The topical skin adhesive may be any rapidly polymerizable or cross-linkable, biocompatible adhesive known to those skilled in the art. In one embodiment, the topical skin adhesive may be a cyanoacrylate-based adhesive, such as the 2-Octyl cyanoacrylate adhesive sold under the trademark DERMABOND® Skin Adhesive—Topical Skin Glue by Ethicon, Inc. of Somerville, New Jersey. Alternatively, the adhesive system may be sold under the trademark DERMABOND® PRINEO®— Skin Closure System, by Ethicon, Inc. of Somerville, New Jersey. In certain embodiments, some cyanoacrylate-based adhesives may work in concert with an accelerator or a catalyst of polymerization that is disposed on the mesh. Alternatively, the topical skin adhesive may be, for example, a two-part silicone-based skin or tissue adhesive, such as those disclosed in US 2021/0371658 and US 2021/0369639, assigned to Ethicon, Inc. of Somerville, New Jersey, the disclosures of which are hereby incorporated by reference herein. Other silicone-based adhesive systems are disclosed, for example, in U.S. Pat. Nos. 10,533,074 and 11,161,937, assigned to Ethicon, Inc. of Somerville, New Jersey, the disclosures of which are hereby incorporated by reference herein. In one embodiment, a silicone adhesive may include a composition comprising a cross-linkable silicone polymer having reactive functionalities; a silica-containing composition; a silicone cross-linking agent; and a catalyst. In one embodiment, the catalyst comprises a platinum tetramethyldivinyl disiloxane diethyl maleate complex. The cross-linkable silicone polymer can be selected from the group consisting of vinyl terminated polydialkylsiloxane, vinyl terminated polydimethylsiloxane, vinyl terminated polydiphenylsilane-dimethylsiloxane copolymer, vinyl terminated polyphenylmethylsiloxane, vinyl terminated polyfluoropropylmethyl-dimethylsiloxane copolymer, vinyl terminated polydiethylsiloxane, and SiH terminated polydimethyldisiloxane. In one embodiment, the silica-containing composition may include a trimethyl silyl surface treated silica filler. The silicone cross-linking agent may be selected from the group consisting of polymethylhydrosiloxane, polymethylhydro-co-polydimethylsiloxane, polyethyhydrosiloxane, polymethylhydrosiloxane-co-octylmethylsiloxane, and polymethylhydrosiloxane-co-methylphenylsiloxane.
In one embodiment, a wound closure system preferably includes a porous mesh having a top surface and a bottom surface, a first pressure sensitive adhesive applied to the top surface of the porous mesh, a removable first liner covering the first pressure sensitive adhesive, a second pressure sensitive adhesive applied to the bottom surface of the porous mesh, and a removable second liner covering the second pressure sensitive adhesive.
In one embodiment, the second pressure sensitive adhesive is stronger or denser than the first pressure sensitive adhesive. In one embodiment, the second pressure sensitive adhesive has greater bonding strength than the first pressure sensitive adhesive. In one embodiment, the first and second pressure sensitive adhesives may have the same bonding strength, however, a greater mass or volume of the second pressure sensitive adhesive is applied to the bottom surface of the porous mesh relative to the mass/volume of the first pressure sensitive adhesive applied to the top surface of the porous mesh.
In one embodiment, a cross-linking or polymerization accelerator or catalyst is preferably disposed in or on the porous mesh.
In one embodiment, the porous mesh is flat, elongated along a longitudinal axis, and has a plurality of openings (e.g., pores) extending between the top and bottom surfaces thereof.
In one embodiment, the removable first liner is configured to be peeled away from the top surface of the porous mesh for exposing the first pressure sensitive adhesive.
In one embodiment, the removable second liner is configured to be peeled away from the bottom surface of the porous mesh for exposing the second pressure sensitive adhesive.
In one embodiment, a method of using the wound closure system disclosed herein may include peeling the removable second liner away from the bottom surface of the porous mesh to expose the second pressure sensitive adhesive applied to the bottom surface of the porous mesh, and pressing the second pressure sensitive adhesive applied to the bottom surface of the porous mesh against skin of a patient to approximate opposing edges of a wound.
In one embodiment, the method may include peeling the removable first liner away from the top surface of the porous mesh to expose the first pressure sensitive adhesive applied to the top surface of the porous mesh, and pressing a therapeutic device against the first pressure sensitive adhesive to secure the therapeutic device over the top surface of the porous mesh.
In one embodiment, the method may include applying a liquid adhesive over the top surface of the porous mesh and at least a portion of the therapeutic device, and allowing the liquid adhesive to cure for binding the porous mesh to the skin and binding the therapeutic device to the porous mesh.
In one embodiment, the liquid adhesive preferably includes a rapidly polymerizable or cross-linkable liquid adhesive.
In one embodiment, the therapeutic device is aligned with the wound prior to being pressed against the top surface of the porous mesh. In one embodiment, if the therapeutic device is not properly aligned with the wound, it may be lifted away from the top surface of the porous mesh and repositioned one or more times until the therapeutic device is in alignment with the wound.
In one embodiment, the therapeutic device may be utilized for draining exudate from the wound or infusing saline or medication into the wound.
The therapeutic device may be a medical device including but not limited to negative pressure wound therapy devices, negative pressure pumps, fluid suction devices, elongated tubes including drainage tubes and infusion tubes, elongated tubes having first and second mesh wings extending along lateral sides thereof, cannulas, wound monitoring sensors, cameras, and combinations thereof.
In one embodiment, a kit for treating wounds may include a wound closure system having a porous mesh with a top surface and a bottom surface, a first pressure sensitive adhesive applied to the top surface of the porous mesh, a removable first liner covering the first pressure sensitive adhesive, a second pressure sensitive adhesive applied to the bottom surface of the porous mesh, and a removable second liner covering the second pressure sensitive adhesive, the second pressure sensitive adhesive being stronger or denser than the first pressure sensitive adhesive.
In one embodiment, the kit preferably includes a rapidly polymerizable liquid adhesive disposed within a dispenser container.
In one embodiment, the kit may include one or more therapeutic devices configured to be secured over the top surface of the porous mesh. The one or more therapeutic devices may include negative pressure wound therapy devices, negative pressure pumps, fluid suction devices, elongated tubes including drainage tubes and infusion tubes, elongated tubes having first and second mesh wings extending along lateral sides thereof, cannulas, and wound monitoring sensors.
In one embodiment, a cross-linking or polymerization accelerator or catalyst may be disposed in or on the porous mesh for interacting with the rapidly polymerizable liquid adhesive disposed within a dispenser container.
In one embodiment, a wound closure system desirably includes a porous mesh having a top surface and a bottom surface, the bottom surface of the porous mesh being adhered to skin for approximating opposing edges of a wound, and a therapeutic device including an elongated tube secured to the top surface of the porous mesh and overlying the wound, the elongated tube being configured for draining exudate from the wound.
In one embodiment, the wound closure system preferably includes a liquid adhesive covering the top surface of the porous mesh and at least a portion of the elongated tube.
In one embodiment, the therapeutic device my include first and second mesh wings secured to the elongated tube and extending along respective lateral sides of the elongated tube.
In one embodiment, the liquid adhesive preferably covers the first and second mesh wings for securing the therapeutic device to the top surface of the porous mesh.
In one embodiment, the elongated tube may include a first elongated conduit that is coupled with a vacuum or negative pressure pump for draining the exudate from the wound.
In one embodiment, the elongated tube may include a second elongated conduit that is coupled with a positive pressure pump, which is configured to force saline or medication into the elongated tube for infusing the wound with the saline or the medication.
In one embodiment, the liquid adhesive may be a topical skin adhesive or a rapidly polymerizable adhesive that forms an air-tight seal around the wound.
In one embodiment, the air-tight seal formed by the liquid adhesive may be waterproof or may include an antimicrobial barrier.
In one embodiment, a cross-linking or polymerization accelerator or catalyst may be disposed in or on the porous mesh. The cross-linking or polymerization accelerator or catalyst preferably interacts with the liquid adhesive applied to the mesh for rapidly curing the adhesive.
In one embodiment, a wound closure system may be affixed over a wound and remain in place for about 7-14 days
In one embodiment, during treatment of a wound, a therapeutic device, after being adhered atop a mesh, may be removed from the mesh.
In one embodiment, during treatment of a wound, a first therapeutic device may be removed from being secured atop the mesh and replaced with a second therapeutic device that is secured atop the mesh. The first and second therapeutic devices may have different functions and/or capabilities.
In one embodiment, a wound closure system may include one or more drain tubes having different lengths, whereby the one or more drain tubes may be customized for tailoring the length of a drain tube to a length of a wound or incision.
In one embodiment, a drain tube may be clear or partially transparent for enabling medical personnel to view the wound or incision located below the drain tube, which may assist medical personnel in aligning the drain tube with the wound or incision.
In one embodiment, the drain tube may be made of silicone.
In one embodiment, pressure sensitive adhesive may be applied directly to a therapeutic device (e.g., an elongated tube, a drain tube, a negative pressure wound therapy device, a sensor, etc.) so that the therapeutic device may be adhered to a mesh or skin adjacent approximated wound edges or approximated skin edges.
In one embodiment, a liquid adhesive or topical skin adhesive applied over a therapeutic device may have anti-microbial properties, anti-clotting properties, anti-fouling properties and/or anti-clogging properties.
In one embodiment, a wound closure system may include a first layer of a porous dressing (e.g., a first mesh; a bottom mesh) having a top surface and a bottom surface. In one embodiment, the top surface and/or the bottom surface of the first layer of the porous dressing may be tacky and/or have an adhesive (e.g., a pressure sensitive adhesive) disposed thereon.
In one embodiment, the first layer of the porous dressing may include a bottom surface that is tacky or that has an adhesive (e.g., a pressure sensitive adhesive) applied thereto for securing (e.g., adhering) the first layer of the porous dressing to tissue (e.g., skin).
In one embodiment, a therapeutic device (e.g., a drain; a suction device; a sensor) may be positioned over the top surface of the first layer of the porous dressing. In one embodiment, the therapeutic device may have a surface that is tacky or that has an adhesive applied thereto for attaching the therapeutic device to the top surface of the first layer of the porous dressing.
In one embodiment, the therapeutic device may have an elongated channel that is configured for draining a wound or incision. In one embodiment, the bottom surface of the therapeutic device may have one or more fenestrations formed therein that are in communication with the elongated channel and that are positioned against the top surface of the first layer of the porous dressing. In one embodiment, the therapeutic device has a bottom surface that is tacky and/or has an adhesive provided thereon for securing the bottom surface of the therapeutic device to the top surface of the first layer of the porous dressing.
In one embodiment, a wound closure system may include a second layer of a porous dressing (e.g., a second mesh; a top mesh) having a top surface and a bottom surface. In one embodiment, the bottom surface of the second layer of the porous dressing is positioned over the therapeutic device (e.g., a drain; a suction device; a sensor) and the top surface of the first layer of the porous dressing. The second layer of the porous dressing may be flexible for conforming to the shape of the therapeutic device. In one embodiment, a bottom surface of the second layer of the porous dressing may be tacky and/or include an adhesive for securing the second layer of the porous mesh to one or more surfaces of the therapeutic device and/or the first layer of the porous dressing.
In one embodiment, one or more surfaces of the therapeutic device may be tacky and/or have an adhesive applied thereto for attaching the second layer of the porous dressing to the therapeutic device.
In one embodiment, with the second layer of the porous dressing positioned over the first layer of the porous dressing, and with the therapeutic device disposed therebetween, a flowable adhesive may be applied over the second layer of the porous dressing, the first layer of the porous dressing, and the therapeutic device that is disposed between the second layer of the porous dressing and the first layer of the porous dressing.
In one embodiment, the therapeutic device may be a suction device that is placed on top of a wound or incision and held in place by one or more layers of porous dressings and a topical skin adhesive. In one embodiment, the therapeutic device has one or more connection ports where fluid may be infused into and/or drained from a wound or incision. The one or more connection ports may be on a top or a side of the therapeutic device. In one embodiment, a first connection port may be attached to a vacuum via tubing for applying negative pressure to a wound or incision. In one embodiment, a second connection port may be attached to tubing that is configured for infusing a therapeutic solution (e.g., saline; medication) into a wound or incision.
In one embodiment, the therapeutic device may be transparent for enabling medical personnel to monitor the wound or incision during healing.
In one embodiment, the therapeutic device may be cut to a length that matches the length of the wound or incision.
In one embodiment, the therapeutic device may be attached to a pump or a drain.
In one embodiment, the therapeutic device may have a low profile to minimize the distance that the therapeutic device projects above a skin surface.
In one embodiment, the therapeutic device may be made of silicone.
The wound closure systems disclosed herein may be used on patients having significant comorbidities that require advanced wound closure approaches including providing appropriate skin tissue approximation/closure and negative pressure wound therapy to minimize post-surgical complications and delays during recovery.
The wound closure systems disclosed herein preferably enable medical personnel to achieve surgical wound approximation, wound closure, controlled removal of exudates, maintenance of closure over a healing period, not requiring dressing changes, and to apply negative pressure wound therapy in a controlled manner.
The wound closure systems disclosed may be used for wound drainage, wound irrigation, wound cleansing, antimicrobial irrigation, pain medication administration, etc.
In one embodiment, the wound closure system may be placed on top of a wound or incision and held in place by a topical skin adhesive. In one embodiment, the therapeutic device has one or more connection ports where fluid may be infused into and/or withdrawn from the wound or incision. The connection ports may be located on top or on the sides of the therapeutic device. One connection port may be attached to a vacuum via tubing for applying negative pressure to a wound or incision. One connection port may be attached to tubing for infusing saline or medication into a wound or incision.
In one embodiment, a method of closing a wound may include approximating the edges of a wound or incision using a first layer of a porous dressing and positioning a therapeutic device (e.g., a drain; a suction device; a sensor) over the top surface of the first layer of the porous dressing.
In one embodiment, the method preferably includes securing the therapeutic device over the top surface of the first layer of the porous dressing so that an elongated channel of the therapeutic device is positioned over the top surface of the first layer of the porous dressing with the elongated channel positioned adjacent the wound or incision.
In one embodiment, the method preferably includes applying a second layer of a porous dressing over both the first layer of the porous dressing and the therapeutic device to secure the elongated channel of the therapeutic device to the top surface of the first porous dressing.
In one embodiment, the method includes applying a flowable adhesive over the first layer of the porous dressing, the second layer of the porous dressing and the therapeutic device. The flowable adhesive may be cured for forming an air-tight seal around the wound or incision.
In one embodiment, the method preferably includes attaching a tube to the therapeutic device for draining fluid (e.g., exudate) from the elongated channel of the therapeutic device or for infusing fluid into the elongated channel of the therapeutic device. In one embodiment, the tube may be attached to a vacuum for applying negative pressure to the wound for draining the wound. In one embodiment, the tube may be attached to a source of a therapeutic solution (e.g., saline; medication; an antibiotic solution) for infusing the therapeutic solution into the wound or incision.
In one embodiment, the elongated channel of the therapeutic device (e.g., a drain; a suction device) desirably has two connection ports where fluid may be infused into and/or withdrawn from the wound or incision.
In one embodiment, the connection ports may be on top or on one or more sides of the therapeutic device.
In one embodiment, a connection port may be attached to a vacuum via tubing, which is configured to apply negative pressure to a wound or incision.
In one embodiment, a connection port may be attached to an infusing tube for infusing a therapeutic solution (e.g., saline; medication; antibiotic) into a wound or incision.
In one embodiment, the elongated channel of a therapeutic device may have a T-shaped cross-sectional shape.
In one embodiment, the flowable adhesive cures to a transparent covering for enabling medical personnel to view the wound or incision during healing.
In one embodiment, the flowable adhesive is a silicone material.
In one embodiment, the therapeutic device preferably has a low profile with tapered edges (e.g., a speed bump shape).
In one embodiment, the therapeutic device has an elongated channel that is open at the bottom surface of the therapeutic device for providing suction that is directly in contact with the wound or incision.
These and other preferred embodiments of the present patent application will be described in more detail herein.
Referring to
The porous mesh 102 may be woven, non-woven, extruded, punched, perforated, molded, etc. In one embodiment, the porous mesh may be similar to a mesh patch sold under the federally registered trademark PRINEO® by Ethicon, Inc. of Somerville, New Jersey. In one embodiment, the porous mesh 102 may be coated and/or impregnated with an initiator or accelerator of polymerization.
The porous mesh 102 may be of any shape that is necessary to cover a wound or incision, such as elliptical, circular, rectangular, square, etc. The porous mesh may have a length to width ratio of about 2:1 to 20:1. In one embodiment, the length of the porous mesh 102 may be about 10-50 cm. In one embodiment, the width of the porous mesh 102 may be about 2-10 cm.
In one embodiment, the openings 108 of the porous mesh 102 may be of any shape, including round, rectangular, triangular, elliptical, etc. The openings 108 may have diameters of about 0.2-2 mm. In one embodiment, the areas of the individual openings 108 may be from about 0.04 mm2 to about 4 mm2.
In one embodiment, the wound closure system 100 preferably includes a first pressure sensitive adhesive 110 that overlies the top surface 104 of the porous mesh 102. In one embodiment, a removable top liner 112 desirably covers the first pressure sensitive adhesive 110 and the top surface 104 of the porous mesh 102. In one embodiment, the removable top liner may be peeled away from the top surface 104 of the porous mesh 102 for exposing the first pressure sensitive adhesive 110 that overlies the top surface of the porous mesh. The first pressure sensitive adhesive 110 that overlies the top surface 104 of the porous mesh 102 may be utilized for securing a therapeutic device, such as a negative pressure wound therapy (NPWT) device, over the top surface of the porous mesh.
In one embodiment, the wound closure system 100 preferably includes second pressure sensitive adhesive 114 that overlies the bottom surface 106 of the porous mesh 102. In one embodiment, a removable bottom liner 116 desirably covers the second pressure sensitive adhesive 114 and the bottom surface 106 of the porous mesh 102. The removable bottom liner may be peeled away from the bottom surface 106 of the porous mesh 102 for exposing the second pressure sensitive adhesive 114 that overlies the bottom surface of the porous mesh. The second pressure sensitive adhesive 114 that overlies the bottom surface 106 of the porous mesh 102 may be utilized for securing the porous mesh to skin of a patient for approximating the opposing edges of a wound or incision.
In one embodiment, the releasable top and bottom liners 112, 116 may be made of synthetic or natural polymers that are easily peelable from the respective first and second pressure sensitive adhesives 110, 114.
Referring to
Referring to
Referring to
The first pressure sensitive adhesive traces 110A-110M may be in a form of linear segments of pressure sensitive adhesive (as shown in
Referring to
The second pressure sensitive adhesive traces 114A-114Y may be in a form of linear segments of pressure sensitive adhesive (as shown in
Referring to
In one embodiment, the first and second pressure sensitive adhesives may comprise water soluble pressure sensitive adhesives including hydrocolloids; homo-polymer emulsion (PVA); water-based acrylic adhesives; polyurethane dispersions (PUDs); polyethylene glycol; dextrin/starch-based adhesives; N-vinyl pyrrolidone copolymers; polyvinyl alcohol; cellulose ethers; methylcellulose; carboxymethylcellulose; polyvinylpyrrolidone; polyvinyl acetates, or water insoluble pressure sensitive adhesives including acrylic adhesives; cyanoacrylate adhesives; epoxy; silicone based adhesives; and urethane.
Referring to
The porous mesh 102 is used to approximate and hold in apposition or close approximation the edges of the wound, using the second pressure sensitive adhesive traces 114A-114Y (
In one embodiment, after the porous mesh 102 has been secured to the skin for approximating the skin edges of the wound, the removable top liner 112 (
In one embodiment, a therapeutic device 126, such as a negative pressure wound therapy (NPWT) device, may be pressed onto the first pressure sensitive adhesive 110 that overlies the top surface 104 of the porous mesh 102 for securing the therapeutic device 126 over the top surface 104 of the porous mesh 102. The therapeutic device may be activated for generating negative pressure and/or a vacuum for draining bodily fluids from the wound. In one embodiment, the wound closure system 100 preferably includes a cannula 128 that may be coupled with the therapeutic device 126 for draining fluids (e.g., wound exudate) that are suctioned by the therapeutic device 126.
Referring to
In one embodiment, the longitudinal axis of the porous mesh 102 is aligned with and superimposed over the wound. The positioning of porous mesh over the wound is performed so that the longitudinal axis is aligned with the wound and overlaps the ends of the wound (i.e., the longitudinal axis of the porous mesh is in registration the wound or surgical incision).
Referring to
The liquid adhesive 130 may be a polymerizable or cross-linkable adhesive that is applied over the porous mesh 102 and the therapeutic device 126. The liquid adhesive 130 may be expressed from a container having a porous tip impregnated with a polymerization or cross-linking accelerator or initiator.
In one embodiment, the liquid adhesive does not contain a polymerization or cross-linking accelerator or initiator, rather the polymerization or cross-linking accelerator or activator/initiator may be present on or in the porous mesh 102 in a releasable or reactive form (i.e., available for rapid reaction when contacted by the liquid adhesive 130).
In one embodiment, after being applied over the porous mesh 102 and the therapeutic device 126, the liquid adhesive 130 preferably polymerizes and/or cross-links and solidifies, establishing a secure bond with the skin, the porous mesh 102, and the therapeutic device 126.
In one embodiment, the liquid adhesive 130 is polymerized or is crosslinked polymerized or is cross-linked after coming in contact with initiators and/or accelerators of adhesive polymerization and/or cross-linking, including naturally found initiators on the tissue, such as moisture, traces of proteins, etc. Such initiators and/or accelerators may be coated or disposed non-releasably, i.e., immobilized in or on the porous mesh 102 while retaining activity to initiate or accelerate polymerization and/or cross-linking. In one embodiment, initiators and/or accelerators are disposed releasably, i.e., they can be at least partially released into and mix with the liquid adhesive 130.
In one embodiment, the liquid adhesive 130 is polymerized or is cross-linked after coming in contact with initiators and/or accelerators releasably disposed in or on the porous mesh 102. Rapid polymerization and/or crosslinking of the liquid adhesive 130 results in bonding the porous mesh 102 to tissue (e.g., skin).
The liquid adhesive 130 may be any type of biocompatible and rapidly cross-linkable and/or polymerizable compound or mixture of compounds. As used herein, the terms rapidly cross-linkable and/or polymerizable mean that after initiators or accelerators are added, or after the adhesive is formed from two or more components, it is capable of curing, i.e., cross-linking and/or polymerizing within 0.2 minutes to about 20 minutes, and more preferably within 0.5-10 minutes. In one embodiment, the liquid adhesive may cure in about one minute.
In one embodiment, the liquid adhesive 130 may be formed prior to application onto the porous mesh 102, for instance by mixing two components contained in separate barrels or a two-barrel syringe, and passing the two components through a mixing tip. In this embodiment, there may be no crosslinking initiator or accelerator disposed inside of porous mesh 20. In one embodiment, the liquid adhesive 130 may be formed by mixing fibrinogen and thrombin together.
In one embodiment, the liquid adhesive 130 may comprise fibrinogen, and a crosslinking initiator or accelerator that is disposed inside the porous mesh 102 comprises thrombin.
Many other adhesive formulations may be used and are known to a skilled artisan. For example, mixtures containing PEG succinimidyl glutarate may be used as a liquid adhesive.
In certain embodiments, initiators and/or accelerators or rate modifiers of adhesive polymerization or cross-linking may be releasably disposed on the porous mesh 102 or releasably incorporated into the porous mesh. For example, one or more chemical substances may be dispersed in or on the porous mesh such as being chemically bound, physically bound, coated, absorbed, or adsorbed to the porous mesh.
For example, a polymerization initiator or accelerator or rate modifier may be loaded in or on the porous mesh so that the initiator or rate modifier provides the desired initiation or rate modification effect to a subsequently applied polymerizable adhesive composition. The polymerization initiator or rate modifier may be immobilized in or on porous mesh so that the initiator or rate modifier does not become detached from the porous mesh and its residues are dispersed in the resultant polymeric material. Alternatively, for example, the polymerization initiator or rate modifier may be initially attached to the porous mesh, but only in such a manner that it becomes mobilized or solubilized by a subsequently applied polymerizable adhesive composition and dispersed in the resultant polymeric material.
If desired, a combination of chemical substances may also be provided in or on porous mesh, to provide multiple effects. For example, a first chemical species (such as a polymerization initiator or rate modifier) may be immobilized in or on the mesh, while a second, different chemical species (such as a bioactive material) may be detachably attached to the mesh.
When present in or on the porous mesh, the chemical substances (i.e., polymerization initiator, rate modifier, and/or bioactive materials, or other additives), may be incorporated in or on the porous mesh in any suitable manner. For example, the chemical substance may be added to the porous mesh by contacting the mesh with a solution, mixture, or the like including the chemical substances. The chemical substance may be added to the mesh, for example, by dipping, spraying, roll coating, gravure coating, brushing, vapor deposition, or the like. Alternatively, the chemical substance may be incorporated into or onto the porous mesh during manufacture of the mesh, such as during molding.
The polymerization initiator or rate modifier loaded in or on the porous mesh may provide a number of advantages (e.g., to provide shorter polymerization time). The concentration of the polymerization initiator or rate modifier may be increased to provide even shorter (i.e., faster) polymerization time. Because the polymerization initiator or rate modifier is loaded directly in or on the porous mesh, it is not necessary to mix the polymerizable adhesive composition with a polymerization initiator or rate modifier prior to application. This may allow a longer working time, where the polymerizable monomer composition may be more precisely and carefully applied over a longer period of time. Such suitable initiators are known in the art and are described, for example, in U.S. Pat. Nos. 5,928,611 and 6,620,846 and U.S. Patent Application Publication No. 2002/0037310, the disclosures of which are hereby incorporated by reference herein.
In one embodiment, the therapeutic device 126 is a negative pressure wound therapy (NPWT) device that is configured for generating negative pressure for draining exudate from the wound. The wound exudate drawn into the negative pressure wound therapy device 126 may be directed into the cannula 128 for draining the wound exudate away from the patient.
Use of Wound Closure Systems. In one embodiment, application of a wound closure system may be performed in one or more of the steps disclosed below.
In one embodiment, standard surgical practices are utilized for preparing the wound including thorough wound cleansing before application of the porous mesh 102 (
In one embodiment, a sterile gauze may be used to dry the wound, such as patting the wound with the sterile gauze. Drying the wound will ensure direct tissue contact for adherence of the second pressure sensitive adhesive 114 and the porous mesh 102 (
In one embodiment, the wound closure system including the porous mesh, the therapeutic device, and the liquid adhesive are preferably aseptically transferred into a sterile field.
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In one embodiment, a surgeon will hold the mesh 102 by the corners of the peripheral sections 124A, 1248 of the bottom liner 116 (
In one embodiment, the porous mesh is positioned so that ½ of the mesh is on either side of the wound or incision, ensuring approximately 1 cm of the mesh extends beyond the ends of the wound or incision. In one embodiment, a surgeon gently presses on the porous mesh to ensure intimate contact of the bottom surface of the porous mesh to a selected side of the wound. In one embodiment, the porous mesh may be gently pulled perpendicularly over the wound while adjusting the porous mesh with fingers or forceps to achieve skin edge approximation and affix the remainder of the porous mesh to the other side of the wound. If there are areas where the porous mesh is loose, a surgeon may gently pass a gloved finger or instrument over the affected area of the porous mesh to ensure complete adherence of the mesh to the skin.
In one embodiment, after the skin edges have been approximated and the porous mesh is deemed to be properly affixed to the skin, the first and second peripheral sections 124A, 1248 of the removable bottom liner 116 may be peeled away from the bottom surface of the porous mesh for adhering peripheral sections of the porous mesh to the skin.
In one embodiment, a sterile cutting tool may be utilized to trim the ends of the porous mesh, if necessary, to ensure that about one (1) cm of porous mesh material extends beyond the ends of the wound or incision.
In one embodiment, the first and second peripheral sections of the removable top liner 112 (
In one embodiment, the therapeutic device 126 may be pressed against the first pressure sensitive adhesive 110 applied to the top surface 104 of the porous mesh 102 to secure the therapeutic device in place atop the porous mesh.
In one embodiment, after medical personnel ensure that the porous mesh is in intimate contact with the skin and after the therapeutic device is secured atop the porous mesh, the liquid adhesive may be applied.
In one embodiment, immediately after the therapeutic device has been placed atop the porous mesh, the liquid adhesive 130 is preferably applied over the porous mesh and at least a portion of the therapeutic device 126. In one embodiment, immediately prior to applying and spreading the liquid adhesive, in the event of bodily fluid seepage, medical personnel may use a sterile gauze to dry the deployed porous mesh.
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Once the liquid adhesive is applied to over the porous mesh and the therapeutic device, after about 1 minute, medical personnel may check that polymerization is complete by gently dabbing along the length of the porous mesh with a gloved finger, checking for tackiness. When no liquid or tackiness is apparent, the polymerization process is complete. Once the liquid adhesive is polymerized, the therapeutic device may be operated for performing various therapeutic activities including but not limited to draining bodily fluids from the wound, infusing the wound with saline or medications, and/or monitoring the wound using a sensor.
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In one embodiment, the first and second mesh wings 238A, 238B are preferably utilized for positioning the elongated tube 232 over the incision. In one embodiment, the elongated tube 232 and the first and second mesh wings 238A, 238B may be cut to the length of the incision.
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In one embodiment, the elongated tube 232 may have holes and/or slits that are used for draining fluid from a wound/incision or infusing saline or a medication onto the wound/incision. In one embodiment, the elongated tube 232 may be placed on top of a porous mesh and may be adhered to the porous mesh by using a pressure sensitive adhesive.
In one embodiment, the elongated tube 232 may have two ends, with one end of the elongated tube being attached to a vacuum for draining fluids (e.g., wound exudate) from the wound/incision and one end of tubing being attached to an inlet port for infusing/injecting fluids, saline irrigation, or medication over the wound/incision. The elongated tube is customizable. The length of the elongated tube may be adjusted, and different therapeutic devices may be used with the elongated tube to monitor the incision, etc. The elongated tube may also be flexed (e.g., bent into a curved configuration) for conforming to the shape of the wound/incision.
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In one embodiment, the top surface of the porous mesh 302 is covered by one or more removable top liners. In
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In one embodiment, the liquid adhesive is configured to secure the therapeutic device 326 and the porous mesh over the incision and form a strong seal around the incision. The liquid adhesive may also form a microbial barrier, be waterproof, and/or allow medical personnel to monitor the wound healing process. The liquid adhesive may be any biocompatible adhesive known in the art, for example, a cyanoacrylate-based adhesive, a silicone-based adhesive, etc. as described above.
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In one embodiment, the top surface of the porous mesh 402 is preferably covered by one or more removable top liners. In
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In one embodiment, the therapeutic device 626 may be made of a biocompatible material such as a polymer, silicone, or stainless steel. In one embodiment, the therapeutic device may be transparent.
In one embodiment, the therapeutic device 626 preferably has a top surface 650, a bottom surface 652, and side walls 654A, 654B that slope outwardly between the top and bottom surfaces 652, 654. In one embodiment, the top and bottom surfaces 650, 652 of the therapeutic device may be parallel to one another. In one embodiment, the therapeutic device 626 may have a low profile and may resemble the shape of a speed bump.
In one embodiment, the therapeutic device 626 may have a first elongated channel 656A that extends along the length of the therapeutic device. In one embodiment, the therapeutic device 626 preferably includes a first fenestration 658A (e.g., an opening) that is formed in the bottom surface 652 of the therapeutic device, which is in fluid communication with the first elongated channel 656A. In one embodiment, the first fenestration 658A may be positioned over a wound for placing the first elongated channel 656A in fluid communication with the wound. In one embodiment, a vacuum may be coupled with the first elongated channel 656A for draining fluid (e.g., exudate) from the wound. The fluid that is drained from the wound preferably passes through the first fenestration 658A and into the first elongated channel 656A for being removed from the wound. In one embodiment, the therapeutic device may include a first port that is in fluid communication with the first elongated channel 656A for coupling a drain tube with the first elongated channel 656A.
In one embodiment, the first elongated channel 656A and the first fenestration 658A may be used for infusing a therapeutic solution into the wound.
In one embodiment, the therapeutic device 626 may have a second elongated channel 656B that extends along the length of the therapeutic device and a second fenestration 658B formed in the bottom surface 652 of the therapeutic device that is in fluid communication with the second elongated channel 656B.
In one embodiment, the second elongated channel 656B and the second fenestration 658B may be used for draining fluid from a wound and/or for infusing the wound with a therapeutic solution. In one embodiment, the therapeutic device may include a second port that is in fluid communication with the second elongated channel 656B for coupling the second elongated channel with a drainage tube or an infusion tube.
In one embodiment, the therapeutic device 626 may have a third elongated channel 656C that extends along the length of the therapeutic device and a third fenestration 658C formed in the bottom surface 652 of the therapeutic device that is in fluid communication with the third elongated channel 656C.
In one embodiment, the third elongated channel 656C and the third fenestration 658C may be used for draining fluid from a wound and/or for infusing a therapeutic solution into the wound. In one embodiment, the therapeutic device may include a third port that is in fluid communication with the third elongated channel 656C for coupling the third elongated channel with a drainage tube or an infusion tube.
In one embodiment, the therapeutic device 626 may be secured over a top surface of a first layer of a porous dressing so that the first elongated channel 656A of the therapeutic device is positioned over the top surface of the first layer of the porous dressing with the first elongated channel positioned adjacent the wound.
In one embodiment, a second layer of a porous dressing may be applied over both the first layer of the porous dressing and over the top of the therapeutic device 626 to secure the therapeutic device to the top surface of the first layer of the porous dressing. The second layer of the porous dressing may contact the top surface 650 and the side surfaces 654A, 654B of the therapeutic device 626.
In one embodiment, a flowable adhesive may be applied over the first layer of the porous dressing, the second layer of the porous dressing and the therapeutic device 626. The flowable adhesive may be cured for forming an air-tight seal around the wound.
In one embodiment, a tube may be attached to the therapeutic device 626 for draining fluid (e.g., exudate) from the first elongated channel 656A of the therapeutic device. In one embodiment, the tube may be attached to a vacuum for applying negative pressure to the wound for draining fluid from the wound. In one embodiment, the tube may be attached to a therapeutic solution (e.g., saline; medication; an antibiotic solution) for infusing the therapeutic solution into the first elongated channel 656A. The therapeutic solution preferably passes through the first fenestration 658A for infusing the wound with the therapeutic solution.
In one embodiment, the elongated channel of the therapeutic device 656 desirably has two or more connection ports where fluid may be infused into and/or withdrawn from the wound.
In one embodiment, the connection ports may be located on the top surface 650 or on one or more of the side surfaces 654A, 654B of the therapeutic device 626. In one embodiment, a connection port may be attached to a vacuum via tubing, which is configured to apply negative pressure to a wound or incision. In one embodiment, a connection port may be attached to an infusing tube for infusing a therapeutic solution (e.g., saline; medication; antibiotic) into a wound or incision.
In one embodiment, the therapeutic device 626 may be transparent for enabling medical personnel to view the wound or incision during healing. In one embodiment, the flowable adhesive cures to a transparent covering for enabling medical personnel to view the wound or incision during healing. In one embodiment, the flowable adhesive is a silicone material.
While the foregoing is directed to embodiments of the present invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, which is only limited by the scope of the claims that follow. For example, the present invention contemplates that any of the features shown in any of the embodiments described herein, or incorporated by reference herein, may be incorporated with any of the features shown in any of the other embodiments described herein, or incorporated by reference herein, and still fall within the scope of the present invention.
