AU2137597A – Suture spring device
– Google Patents
AU2137597A – Suture spring device
– Google Patents
Suture spring device
Info
Publication number
AU2137597A
AU2137597A
AU21375/97A
AU2137597A
AU2137597A
AU 2137597 A
AU2137597 A
AU 2137597A
AU 21375/97 A
AU21375/97 A
AU 21375/97A
AU 2137597 A
AU2137597 A
AU 2137597A
AU 2137597 A
AU2137597 A
AU 2137597A
Authority
AU
Australia
Prior art keywords
spring device
guide
suture spring
suture
tissue
Prior art date
1996-03-05
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
AU21375/97A
Other versions
AU719161B2
(en
Inventor
Inbae Yoon
Samuel C. Yoon
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Individual
Original Assignee
Individual
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
1996-03-05
Filing date
1997-03-05
Publication date
1997-09-22
1997-03-05
Application filed by Individual
filed
Critical
Individual
1997-09-22
Publication of AU2137597A
publication
Critical
patent/AU2137597A/en
2000-05-04
Application granted
granted
Critical
2000-05-04
Publication of AU719161B2
publication
Critical
patent/AU719161B2/en
2017-03-05
Anticipated expiration
legal-status
Critical
Status
Ceased
legal-status
Critical
Current
Links
Espacenet
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Discuss
Classifications
A—HUMAN NECESSITIES
A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
A61B17/00—Surgical instruments, devices or methods, e.g. tourniquets
A61B17/064—Surgical staples, i.e. penetrating the tissue
A—HUMAN NECESSITIES
A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
A61B17/00—Surgical instruments, devices or methods, e.g. tourniquets
A61B17/04—Surgical instruments, devices or methods, e.g. tourniquets for suturing wounds; Holders or packages for needles or suture materials
A61B17/06—Needles ; Sutures; Needle-suture combinations; Holders or packages for needles or suture materials
A—HUMAN NECESSITIES
A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
A61B17/00—Surgical instruments, devices or methods, e.g. tourniquets
A61B17/11—Surgical instruments, devices or methods, e.g. tourniquets for performing anastomosis; Buttons for anastomosis
A—HUMAN NECESSITIES
A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
A61B17/00—Surgical instruments, devices or methods, e.g. tourniquets
A61B17/04—Surgical instruments, devices or methods, e.g. tourniquets for suturing wounds; Holders or packages for needles or suture materials
A61B17/06—Needles ; Sutures; Needle-suture combinations; Holders or packages for needles or suture materials
A61B2017/06052—Needle-suture combinations in which a suture is extending inside a hollow tubular needle, e.g. over the entire length of the needle
A—HUMAN NECESSITIES
A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
A61B17/00—Surgical instruments, devices or methods, e.g. tourniquets
A61B17/04—Surgical instruments, devices or methods, e.g. tourniquets for suturing wounds; Holders or packages for needles or suture materials
A61B17/06—Needles ; Sutures; Needle-suture combinations; Holders or packages for needles or suture materials
A61B17/06066—Needles, e.g. needle tip configurations
A61B2017/06076—Needles, e.g. needle tip configurations helically or spirally coiled
A—HUMAN NECESSITIES
A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
A61B17/00—Surgical instruments, devices or methods, e.g. tourniquets
A61B17/064—Surgical staples, i.e. penetrating the tissue
A61B2017/0649—Coils or spirals
Description
Suture Spring Device
BACKGROUND OF THE INVENTION
Field of the Invention:
The present invention relates to surgical devices and procedures and, more particularly, to a suture device of coiled configuration formed of an elastic material and methods of suturing anatomical tissue using such a device.
Discussion of the Prior Art:
Suturing of bodily tissue is a time consuming part of most surgical procedures including both open surgery and endoscopic or minimally invasive surgery. By “open” surgery is meant surgery wherein the surgeon gains access to the surgical site via a relatively large incision, and by “endoscopic” surgery is meant surgery wherein the surgeon gains access to the surgical site via one or more portals through which endoscopes are introduced to view the surgical site and through which various instruments are introduced to the surgical site. There are many common endoscopic surgical procedures, including arthroscopy,
O 97/32526 PC17US97/02978
laparoscopy (pelviscopy), gastroentroscopy and laryngobronchoscopy, for example.
In the past, suturing was accomplished with the use of a sharp suture needle attached to the end of a length of suture material. Depending on the size of the suture needle and the type of surgery being performed, the suture needle was either grasped manually or with a needle holding instrument and moved to cause a sharp tip of the needle to penetrate and pass through anatomical tissue. When the sharp tip of the needle emerged from the tissue, the body of the needle was released so that the distal end of the body adjacent the tip could be grasped to pull the needle and the suture material attached to the needle through the tissue. Once the suture material was pulled through the tissue, the surgeon tied a knot in the suture material and adjusted the tension on the suture material to accommodate the particular tissue being sutured and to control approximation, occlusion, attachment or other conditions of the tissue. However, the process of tissue penetration and knotting of the suture material can be time consuming and tedious work, particularly when performed in connection with microsurgery and endoscopic surgery, and can unduly prolong the duration of surgery and therefore the period in which the patient is under anesthesia. Nevertheless, endoscopic surgery is preferred over open surgery due to the greatly reduced trauma and wound healing time for the patient and due to concomitant cost savings associated with shorter hospital stays and performing surgery in non-hospital or out-patient surgery sites.
Accordingly, there has been much effort spent to develop techniques for facilitating the suturing normally performed by use of a suture needle and a length of suture material. One technique, exemplified by U.S. Patent Nos. 3,545,444 to Green and 4,595,007 to Mericle, employs elongated wire sutures formed of ductile materials that are bent into coiled shapes by a curved tip of a suturing instrument. The wire sutures can be bent around tubular structures or through anatomical tissue and will tend to remain in the bent condition to hold the tissue together; however, once bent, the wire sutures will not compress the tubular structures or tissue so that it is necessary to approximate the tubular structures or tissue prior to or concurrent with bending of the sutures.
The use of stapling instruments has also been proposed, as exemplified by U.S. Patent Nos. 4,979,954 to Gwathmey et al, 5,465,894 to Clark et al, 5,465,895 to Knodel et al, 5,465,896 to Allen et al, 5,467,991 to Tsuruta et al, 5,480,089 to Blewett and 5,486,187 to Schenck; however, stapling instruments typically include separate staple driving and staple forming or anvil portions for positioning on opposite sides of the tissue to be stapled. This requires access to both sides of the tissue and increases the size of the instruments and the portals through which the instruments are passed in endoscopic procedures. Some stapling instruments do not have a separate anvil portion and are thus capable of applying staples from one side of the tissue; however, the staples must still be formed of a ductile material and bent to a final shape by such instruments requiring relatively complex mechanisms which increase the cost of such instruments. Another disadvantage of stapling instruments is that the staples have sharp, tissue penetrating tips which remain in the tissue after the staples have been bent into their final shape.
Other techniques that have been proposed include electrical coagulation, mechanical devices such as clips and damps, and lasers; however, no alternative technique has yet been well accepted by surgeons to produce the results obtained by suturing and tying. Thus, there is a great need for suturing techniques useful in endoscopic surgery that permit surgeons to suture anatomical tissue in a time efficient, consistent and precise manner.
SUMMARY OF THE INVENTION
Accordingly, it is a primary object of the present invention to overcome the above-mentioned disadvantages of the prior art and to provide an improved suture device and method of suturing anatomical tissue.
Another object of the present invention is to use contraction of a coiled suture device to suture anatomical tissue in a time efficient, consistent and precise manner.
A further object of the present invention is to penetrate anatomical tissue with a guide and to use the guide to position a coiled suture device in the anatomical
tissue in an elastically deformed, expanded state so that, when the guide is removed, the coiled suture device will contract to suture the anatomical tissue.
Some of the advantages of the present invention over the prior art are that the process of suturing anatomical tissue can be performed in less time with fewer instruments and with greater consistency in both endoscopic and non-endoscopic procedures, that the suture spring device permits suturing from one side of the anatomical tissue without the need of having to position or reposition instruments on an opposite side of the tissue, that the suture spring device can be made of bioabsorbable and non-bioabsorbable materials, that the suture spring device can be adapted to suture a wide variety of anatomical structures of various shapes and sizes, that the suture spring device can apply a predetermined compressive, approximating force to anatomical tissue in a single direction or multiple directions simultaneously, and that a plurality of suture spring devices can be disposed within a guide and/or carried by a suture device applicator to permit suturing at multiple locations within the body without the need of having to withdraw the guide and/or applicator from the body for reloading.
The present invention is generally characterized in a suture spring device and guide where the suture spring device includes an elastic body of coiled configuration having a relaxed, contracted state and an elastically deformed, expanded state, and the guide is configured to position the suture spring device in anatomical tissue in the elastically deformed, expanded state, the guide being removable from the suture spring device to permit the suture spring device to move resiliency from the expanded state toward the contracted state to apply a compressive, approximating force to anatomical tissue engaged by the coiled body of the device. In one embodiment, the guide includes a hollow, tubular body of coiled configuration defining a plurality of connected coils with a predetermined radius of curvature and a predetermined axial spacing therebetween. The suture spring device includes an elastic body of coiled configuration defining a single ring or a plurality of connected rings having a radius of curvature and/or axial spacing in the relaxed, contracted state which is smaller than the predetermined radius of curvature and/or axial spacing of the guide so that, when the suture spring device is disposed within the guide, it is maintained in an elastically
deformed, radially and/or axially expanded state. The guide can be configured with a slot to receive a knob or handle protruding from the suture spring device or, alternatively, the guide can have a solid tubular configuration and a pusher can be provided which is movable through the guide to maintain the suture spring device in the anatomical tissue as the guide is removed. Yet another aspect of the present invention is generally characterized in a method of suturing anatomical tissue including the steps of positioning a suture spring device of coiled configuration in the anatomical tissue in an elastically deformed, expanded state and allowing the suture spring device to move from the elastically deformed, expanded state toward a relaxed, contracted state within the tissue to apply a compressive, approximating force to the anatomical tissue. In a preferred embodiment, the positioning step includes penetrating the anatomical tissue with a guide and using the guide to position the suture spring device in the anatomical tissue in an expanded state. The guide is then removed to allow the suture spring device to move from the expanded state toward the contracted state. Still another aspect of the present invention is generally characterized in a suture spring device for use with a guide having an elongate, tubular body of coiled configuration terminating distally in a sharp, tissue penetrating tip, the tubular body defining a plurality of connected rings having a predetermined radius of curvature and a predetermined axial spacing therebetween, and the sharp, tissue penetrating tip allowing the guide to penetrate and pass through anatomical tissue when placed against the tissue and rotated about a longitudinal axis of the guide. In accordance with the present invention, the suture spring device includes an elastic body of coiled configuration having an elastically deformed, expanded state with a radius of curvature and axial spacing to fit inside the coiled tubular body of the guide and a relaxed, contracted state where at least one of a radius of curvature and an axial spacing of the elastic body is smaller than the predetermined radius of curvature and axial spacing of the coiled tubular body of the guide so that, when the guide is removed from anatomical tissue after having been used to penetrate the anatomical tissue and position the suture spring device therein, the suture spring device will remain in the tissue and move from
the elastically deformed, expanded state toward the relaxed, contracted state to automatically compress the tissue engaged by the device.
A further aspect of the present invention is generally characterized in a method of suturing anatomical tissue including the steps of penetrating the anatomical tissue with a guide, using the guide to position a suture device in the anatomical tissue in an expanded state, and causing the suture device to move from the expanded state toward a contracted state within the anatomical tissue to apply a predetermined compressive force to the tissue. In a preferred embodiment, the suture device includes an elastic body of coiled configuration in the contracted state and the suture device is caused to move by removing the guide from the suture device to allow the suture device to move resiiiently from the expanded state toward the contracted state to apply a predetermined compressive force to the tissue.
Other objects and advantages of the present invention will become apparent from the following description of the preferred embodiments taken in conjunction with the accompanying drawings, wherein like parts in each of the several figures are identified by the same reference numerals or by reference numerals having the same last two digits.
BRIEF DESCRIPTION OF THE DRAWINGS
Fig. 1 is a perspective view of a suture spring device disposed within a guide in an elastically deformed, expanded state according to the present invention.
Fig. 2 is a perspective view of the suture spring device of Fig. 1 in a relaxed, contracted state.
Fig. 3 is a top plan view of the suture spring device shown in Fig. 2.
Fig. 4 is a detail view, in perspective, of the suture spring device of Fig. 2 in the elastically deformed, expanded state.
Fig. 4A is a fragmentary perspective view of a modified distal end for the suture spring device according to the present invention.
Fig. 5 is a top plan view, partly in section, of the suture spring device and guide shown in Fig. 1.
Figs. 6 – 9 are perspective views, partly in section, illustrating use of the suture spring device and guide of Fig. 1 to suture anatomical tissue according to the present invention.
Fig. 10 is an exploded perspective view of a modification of the suture spring device and guide according to the present invention.
Figs. 11 – 13 are fragmentary perspective views, partly in section, illustrating use of a suture spring device and guide according to the present invention to occlude a tubular anatomical structure.
Fig. 14 is an exploded perspective view of another modification of the suture spring device and guide according to the present invention.
Figs. 15 and 16 are a fragmentary perspective view and a sectional side view, respectively, illustrating a method of performing anastomosis using a suture spring device according to the present invention.
Figs. 17 and 18 are a fragmentary perspective view and a sectional side view, respectively, illustrating another method of performing anastomosis using a suture spring device according to the present invention.
Fig. 19 is an exploded perspective view of yet another modification of the suture spring device and guide according to the present invention.
Fig. 20 is a top plan view of the modified suture spring device shown in Fig. 19.
Fig. 21 is a top plan view of another modified suture spring device according to the present invention.
Fig. 22 is a side view, in elevation, of the suture spring device shown in Fig. 21.
Figs. 23 and 24 are fragmentary side views, partly in section, illustrating a modified suture spring device and guide and a method of suturing using the modified suture spring device and guide. Figs.25 and 26 are a fragmentary perspective view and a sectional side view, partly in section, respectively, illustrating a method of performing anastomosis using the suture spring device of Fig. 23.
Figs. 27 and 28 are fragmentary side views, partly in section, illustrating alternative suture spring device placement when suturing inverted edges of adjacent anatomical structures.
Figs. 29 – 31 are fragmentary side views, partly in section, illustrating alternative suture spring device placement when suturing introverted edges of adjacent anatomical structures.
Figs. 32 – 34 are fragmentary side views, partly in section, illustrating alternative suture spring device placement when suturing abutting edges of adjacent anatomical structures.
Figs. 35 and 36 are side and rear views, respectively, of a modified suture spring device according to the present invention.
Figs. 37 and 38 are side and rear views, respectively, of yet another modified suture spring device according to the present invention.
Fig. 39 is a fragmentary side view, partly in section, illustrating use of the suture spring device of Fig. 1 to suture plural tissue layers.
Fig. 40 is a fragmentary side view, partly in section, illustrating use of the suture spring device of Fig. 10 to suture plural tissue layers while maintaining their axial spacing.
Fig. 41 is a fragmentary perspective view, partly in section, illustrating a modification of the suture spring device and guide according to the present invention.
Fig. 42 is a side view, in elevation, of still another modified suture spring device according to the present invention.
Fig. 43 is a rear view, in elevation, of the suture spring device shown in Fig. 42.
Fig. 44 is a fragmentary rear view, in elevation, illustrating another modification of a suture spring device according to the present invention.
Fig. 45 is a fragmentary side view, partly in section, illustrating a modified guide for use with a suture spring device according to the present invention.
Figs. 46 and 47 are a side view and a perspective view, respectively, illustrating a method of suturing anatomical tissue adjacent an opening using a suture spring device according to the present invention.
Figs. 48 and 49 are fragmentary perspective views illustrating a method of suturing anatomical structures using a suture spring device according to the present invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS While the suture spring device of the present invention is described hereinafter as a device for suturing anatomical tissue, where by “suturing” is meant the practice of approximating, occluding or attaching anatomical tissue by joining opposed tissue surfaces or edges together or by attaching devices such as surgical mesh to the tissue, it will be appreciated that the suture spring device can be used to perform other surgical procedures as well. For example, the suture spring device can be used for ligating anatomical tissue.
A system 20 for suturing anatomical tissue according to the present invention, as illustrated in Fig. 1, includes a suture spring device 22 and a tissue penetrating guide 24 for positioning the suture spring device in anatomical tissue in an elastically deformed, expanded state. Suture spring device 22 is of coiled configuration and, as best seen in Figs. 2 and 3, the device includes an elongate, wire-like spring body 26 defining a series of connected rings or coils 28 of generally circular configuration, the rings being of like diameter and extending between proximal and distal ends 30 and 32 of the spring body concentric with a longitudinal axis of the device. A knob or handle 34 in the form of a ball is carried on an outer peripheral, convex edge or surface of the spring body near proximal end 30 and extends radially or laterally outward relative to the longitudinal axis of the suture spring device. Body 26 of the suture spring device is circular or round in transverse cross-section with a diameter or gage to permit the suture spring device to be deformed from the relaxed, contracted state shown in Fig. 2, where rings 28 are collapsed against one another in abutting relation, to the
expanded state shown in Fig. 4, where the rings are held in axially spaced relation by the guide to define axial, tissue receiving spaces therebetween. The body of the suture spring device is formed of an elastic or resilient material, that is, a material able to recover its original shape or position after having been deformed, so that, when the expanded suture spring device is removed from the guide, the device will relax or tend to move resiliently from the expanded state toward the fully contracted state to compress any anatomical tissue disposed in the axial, tissue receiving spaces between rings. Any medically acceptable bioabsorbable or non-bioabsorbable elastic material can be used for the body of the device including, but not limited to, titanium, nickel-titanium alloys, stainless steel, shape memory alloys such as nitinol and plastics such as nylon. Distal end 32 of the suture spring device is preferably blunt but can be tapered as shown in Fig. 4A to define a sharp, tissue penetrating tip 33 if desired.
Guide 24 includes a tubular body 36 of coiled configuration defining a series of connected rings or coils 38 of generally circular configuration between a proximal end 40 and a distal end 42, the distal end terminating in a sharp, tissue penetrating tip 44. Referring to Figs. 1 – 5, it can be seen that rings 38 of the guide body have a predetermined radius of curvature or diameter A about the same as the diameter B of rings 28 of the suture spring device; however, rings 38 of the guide have a predetermined longitudinal or axial spacing C therebetween greater than the axial spacing D between rings 28 of the suture spring device in the relaxed, contracted state so that the suture spring device will be axially but not radially expanded when it is loaded into the guide. Rings 38 of the guide are also hollow to define a lumen 46 through the body of the guide with a slot 48 along an outer peripheral, convex edge of the body communicating between outer surface 50 of the guide and the lumen, the lumen being of sufficient size to receive and hold the body of suture spring device 22 while slot 48 is preferably V-shaped in transverse cross-section and somewhat narrower in width than the diameter of the spring body to allow knob 34 of the suture spring device to slide along the slot while preventing the body of the suture spring device from slipping therethrough. The guide can be made of any suitable medically acceptable material, such as stainless steel, so long as it is configured to have a stiffness suitable for
maintaining the suture spring device in an elastically deformed, expanded state.
Suture spring device 22 is normally supplied separate from guide 24 in the relaxed, fully contracted state shown in Fig. 2 with rings 28 collapsed against one another in abutting relation. The suture spring device is preferably loaded into the guide and placed in anatomical tissue using a suture spring device applicator, such as the applicator described in my co-pending U.S. Patent Application Serial No. 08/610,735, entitled “Suture Spring Device Applicator,” the disclosure of which is incoφorated herein by reference; however, the suture spring device and guide can be assembled together manually if desired, for example by grasping suture spring device 22 and guide 24, inserting distal end 32 of the suture spring device in open proximal end 40 of the guide and screwing the suture spring device lengthwise into the lumen of the guide in a clockwise direction looking distally. The suture spring device is axially expanded as it is screwed into the guide, that is, rings 28 of the suture spring device are forced away from one another as they are advanced distally through lumen 46 of the guide and are maintained in axially spaced relation within the guide as shown in Figs. 1 and 4 so that the axial spacing D’ between rings 28 of the suture spring device in the elastically deformed, expanded state is about the same as the predetermined axial spacing C between rings 38 of the guide. Knob 34 at the proximal end of the suture spring device is aligned with slot 48 in the guide so that, as the suture spring device is loaded into the guide, the inner portion of the knob immediately adjacent the body of the suture spring device will enter into and slide along the slot while the outer portion of the knob will protrude outwardly of the slot in a radial or lateral direction relative to the longitudinal axis of the guide. In the fully assembled condition, shown in Fig. 1 , proximal end 30 of the suture spring device is disposed adjacent proximal end 40 of the guide and distal end 32 of the suture spring device is proximally spaced from the sharp, tissue penetrating tip 44 at the distal end of the guide. It will be appreciated, however, that the suture spring device can occupy less than the total number of coils or rings of the guide in the elastically deformed, expanded state depending upon the length of
the guide and the thickness of the tissue to be sutured. Also, more than one suture spring device can be disposed within a single guide if desired.
A first method of suturing anatomical tissue using suture spring device 22 according to the present invention is illustrated in Figs. 6 – 9 wherein anatomical tissue to be sutured is shown as a pair of adjacent layers T1 and T2 , it being understood that the layers could be adjacent tissue structures, individual layers of a single tissue structure, opposite sides of a single tubular structure, or a surgical device, such as a mesh, laid upon a tissue structure or another surgical device. It will also be understood that a single layer or more than two layers can be sutured with the suture spring device according to the present invention. Suturing is performed by inserting suture spring device 22 through the layers in the elastically deformed, expanded state using guide 24 to penetrate the layers and by then removing the guide from the suture spring device to permit the suture spring device to return towards its relaxed, contracted state. The suture spring device can be inserted through layers T, and T2 with the guide, as shown in Fig. 6, or the suture spring device can be inserted into the guide after the guide has already penetrated through the layers. In either case, guide 24 is used to penetrate and create a helical path through the layers by orienting the guide at a desired angle relative to proximal layer T, and pressing the tissue penetrating tip 44 of the guide into the proximal layer while rotating the guide about its longitudinal axis in a clockwise direction, looking distally along the longitudinal axis of the guide, to thread the guide through both layers like a cork-screw. When a suitable number of guide rings 38 are disposed on opposite sides of the layers, as shown in Fig. 7, penetration is ceased, and the suture spring device is released from the guide by unscrewing the guide from the tissue or, in other words, by rotating the guide in the opposite, counterclockwise direction, looking distally. At the same time, the suture spring device is prevented from moving proximally by holding the knob 34 at the proximal end of the suture spring device relatively stationary. Slot 48 in the guide facilitates removal of the guide from the suture spring device by allowing the distal end of the guide to slide past the knob as it is unscrewed. As the guide is unscrewed, rings 28 of the suture spring device are no longer axially restrained by the guide and are thus free to move
from their elastically deformed, expanded state toward the relaxed, contracted state as shown in Fig. 9 thereby trapping those portions of layers T, and “ζ disposed between the rings and axially compressing the layers together.
The material and cross-sectional configuration of spring body 26 and the coil diameter and axial spacing of rings 28 in the contracted state are dependent upon the nature of the surgical procedure to be performed, the types of applicator instruments to be used in the procedure and the type of anatomical tissue to be sutured. For example, where a particular suture tension is necessary or desired, the force exerted by the suture spring device when contracting can be controlled by choice of material and by varying the cross-sectional area of the body of the suture spring device. Similarly, the amount of tissue engaged by the suture spring device can be controlled by varying the size of the tissue receiving spaces defined by the suture spring device, that is, by varying the coil diameter and/or the axial spacing between coils in the expanded state.
In the case of a hernia repair, for example, the suture spring device can be used in the manner described above to fasten or tack pieces of surgical mesh to anatomical tissue. When used as a tack, the suture spring device could, for example, include three connected coils or rings formed of spring wire having a cross-sectional diameter or gage of about 0.8 to about 1 mm so that, when the rings are collapsed together in the contracted state, they will have a combined axial length of about 2.5 to about 3 mm. A suitable outer ring diameter B for such a suture spring device could be about 4 to about 4.5 mm, it being understood that the foregoing dimensions are given by way of example only and are not intended to be limiting. In the elastically deformed, expanded state, such a suture spring device could have an axial spacing between rings as much as about 10 times that in the contracted state, or about 10 mm between each ring. Thus, if the combined thickness of the layers being sutured is less than or equal to about 10 mm, for example, the layers will be compressed between a pair of rings with a force approximately equal to the axial spacing between the rings multiplied by the spring constant of the suture spring device. For combined thicknesses greater than the axial spacing between rings, portions of the layers will be compressed between more than one pair of rings of the device.
From the above, it will be appreciated that adjacent structures in the body can be sutured or fastened together with a suture spring device of coiled configuration by inserting the suture spring device through the structures in an elastically deformed, axially expanded state and allowing the suture spring device to contract toward a relaxed state in order to apply an axially compressive load to the portions of each structure disposed between coils of the suture spring device. It will also be appreciated, however, that the rings or coils of such a suture spring device define a longitudinal passage or aperture through the device which can be positioned in or around anatomical tissue in an elastically deformed, radially expanded state and allowed to contract toward a relaxed state in order to apply a radially compressive load to the tissue disposed within the passage. For example, in Fig. 10 a modified suturing system 120 is shown with a suture spring device 122 similar to suture spring device 22 and a guide 124 similar to guide 24 but with a ring diameter A greater than the ring diameter B of the suture spring device in the relaxed, contracted state so that, when the suture spring device is loaded into the guide, it is held in an elastically deformed, radially expanded state. Rings 128 of the suture spring device define a central, tissue receiving aperture or passage 129 of generally circular cross-section concentric with a longitudinal axis of the suture spring device, the passage being diametrically expandable with radial deformation of the suture spring device rings in a laterally outward direction relative to the longitudinal axis. Rings 138 of the guide 124 are spaced at regular axial intervals C approximately equal to the axial spacing D between the coils of the suture spring device in the relaxed, contracted state to minimize axial deformation of the suture spring device in the radially expanded state within the guide.
In use, suture spring device 120 can be assembled and inserted through adjacent layers in the body to suture together or fasten the layers in a manner similar to that described above for suture spring device 20, or the suture spring device 120 can be inserted into the wall of a tubular anatomical structure in a concentric manner with a longitudinal axis of the device aligned with a lumen of the tubular anatomical structure to occlude the lumen by compressing the wails of the tubular anatomical structure together as will be described in greater detail
below, ff the guide is inserted through layers in the body, tissue disposed in the central aperture or passage defined by the rings will be placed in compression by radial contraction of the suture spring device as the guide is removed but will not be axially compressed to a significant extent because, in the relaxed state, the ring spacing of the suture spring device is not much different than that of the helical path created in the tissue by the guide.
Use of suture spring device 122 to occlude the lumen L of a tubular anatomical structure T is shown in Figs. 11 – 13. For purposes of illustration, the suture spring device is shown being applied hysteroscopically at the utero-tubal (UT) junction; it will be understood, however, that the suture spring device can be used to occlude the lumen of any tubular anatomical structure in similar fashion. For such use, guide 122 of the suture spring device will preferably have a ring diameter A greater than the diameter of the lumen so that it can be inserted into the wall of the tubular anatomical structure concentric with the lumen as shown in Fig. 11. The guide can be inserted into the wall with the suture spring device disposed therein in an elastically deformed, radially expanded state or the suture spring device can be inserted into the guide after the guide is already placed in the wall. Once inserted, guide 124 establishes a helical path in the wall of the tubular anatomical structure which the suture spring device will occupy when the guide is removed or withdrawn. Withdrawal of the guide is accomplished by unscrewing the guide from the tissue while at the same time holding the suture spring device stationary, for example by grasping the knob 134 at the proximal end of the suture spring device and holding the knob in a relatively stationary position. As the guide is withdrawn, portions of suture spring device 122 no longer radially constrained within the tubular body of the guide will move toward the relaxed, contracted state as shown in Fig. 12 drawing the wall of the tubular anatomical structure radially inward. When the guide is withdrawn completely from the wall, suture spring device 122 will compress the wall of the tubular anatomical structure radially inward over the entire length of the suture spring device thereby occluding the lumen of the tubular anatomical structure. As discussed previously, the amount of force exerted by the suture spring device will depend on the spring constant of the particular suture spring device being used
as well as the extent to which the suture spring device is radially expanded within the guide, it being noted that in the present example, little or no axial force is applied to the structure by the suture spring device since the axial spacing between the rings of the suture spring device is not much different than that between rings of the helical path created by the guide in the wall of the tubular anatomical structure.
Another modification of the suturing system is shown in Fig. 14 wherein the modified system 220 is configured to position a suture spring device 222 in anatomical tissue in an elastically deformed, radially and axially expanded state using a guide 224 similar to guide 24 but with rings 238 having a diameter A greater than the diameter B of the rings 228 of suture spring device 222 in the relaxed, contracted state. Suture spring device 222 is similar to suture spring device 22 but includes an additional ring or coil 228. In the relaxed, contracted state shown in Fig. 14, rings 228 are collapsed against one another in abutting relation so that the axial spacing D from the center of one ring to the next is approximately equal to the wire diameter or gage of the suture spring device body. As mentioned above, rings 238 of guide 224 have a diameter of predetermined dimension greater than the diameter of the rings of the suture spring device in the relaxed, contracted state; and, in addition, the axial spacing C between rings of the guide is greater than the spacing D between rings 228 of the suture spring device in its relaxed, contracted state so that, when the suture spring device is disposed within the guide, rings 228 of the suture spring device are held in an axially and radially expanded state.
Like the suture spring devices described above, suture spring device 222 can be inserted through adjacent layers in the body to suture together or fasten the layers, or the suture spring device can be inserted into the wall of a tubular anatomical structure in a concentric manner with a longitudinal axis of the device aligned with the lumen defined by the tubular anatomical structure to occlude the lumen of the structure. Once guide 224 has penetrated through the layers or into the wall of the tubular anatomical structure, rings 238 of the guide will have established a helical path through the tissue layers or structure which the suture spring device will occupy when the guide is removed. The path created by the
guide is initially about the same size as the guide, that is, with a coil diameter and axial spacing greater than that of the suture spring device in a relaxed, contracted state. If the guide was inserted through layers in the body, tissue disposed in the center of the coils will be axially and radially compressed by axial and radial contraction of the suture spring device as the guide is removed; or, if the suture spring device is inserted concentrically into the wall of a tubular anatomical structure such as, for example, a U-T junction, axial and radial contraction of the suture spring device within the path defined in the wall by the guide will tend to draw the wall of the tubular anatomical structure radially inward while axially shortening the structure thereby occluding the lumen defined by the structure. As with the other suture spring devices described herein, the amount of force exerted by the suture spring device as it contracts will depend on the spring constant of the particular suture spring device being used as well as the extent to which the suture spring device is expanded within the guide.
A method of using a suture spring device according to the present invention for performing anastomosis, that is, to connect separate or severed tubular anatomical structures to form a substantially continuous lumen, is illustrated in Figs. 15 and 16 wherein the tubular anatomical structures T, and ” to be connected have abutting, inverted ends E and E2, respectively. To connect the tubular anatomical structures, a plurality of suture spring devices, for example suture spring devices 222, are placed in the inverted ends E1 and E? in radial orientation relative to a longitudinal axis of the tubular anatomical structures at a respective plurality of angularly spaced locations. In order to place the suture spring devices 222, guide 224 is oriented radially or substantially perpendicular to the longitudinal axis of the tubular anatomical structure and distal tip 244 of the guide is moved to penetrate through the inverted ends E1 and E2 The guide is then rotated to cause the penetrating tip of the guide to alternatingly pass through each abutting end as it travels radially inward to create a helical path through the inverted ends which the suture spring device will occupy when the guide is withdrawn. The path created by the guide is initially about the same size as the guide, that is, with a coil diameter and spacing greater than that of the suture spring device in a relaxed, contracted state so that, when the guide is unscrewed
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from the suture spring device, axial and radial contraction of the suture spring device within the path defined in the tissue by the guide will tend to compress the inverted ends of the tubular organs together thereby connecting the organs. If the ring diameter of the guide is greater than the combined thickness of the inverted ends, diametrically opposed portions of the suture spring device will protrude from opposite sides of the inverted ends as shown. It will be appreciated, however, that the suture spring devices can be completely embedded within the inverted ends by use of a guide having a ring diameter less than the combined thickness of the inverted ends.
Another method of performing anastomosis using a suture spring device according to the present invention is illustrated in Figs. 17 and 18 wherein a plurality of suture spring devices, for example suture spring devices 222, are placed lengthwise along the peripheral edges of inverted ends E^ and E2 of the organs in substantially tangential orientation relative to the circumference or periphery of the inverted ends at a respective plurality of circumferentially spaced locations about the periphery of the ends. Suture spring devices 222 are placed in the inverted ends E1 and E2 by orienting guide 224 tangentially relative to a circumference of the ends and moving the tip of the guide to penetrate into and through the ends to create a helical path partly within the inverted tissue and partly around the inverted tissue. It will be appreciated, however, that guide 224 can be oriented at any angle relative to the longitudinal axis of the anatomical tubular structures to place suture spring devices 222 in the inverted ends.
Yet another modified suturing system 320, shown in Fig. 19, includes a suture spring device 322 of planar spiral configuration and a generally conical guide 324 formed of a hollow tubular body 336 of coiled configuration. As best seen in Fig. 20, suture spring device 322 includes an elastic body 326 formed of coils or rings 328 having diameters increasing as they approach an outer, distal end 332 of the suture spring device and a knob or handle 334 in the form of a ball carried or formed near a central, proximal end 330 of the suture spring device along an outer peripheral, convex surface of the spring body. Rings 328 of the suture spring device are generally coplanar and, in the relaxed, contracted state shown,
the coils are radially collapsed together in abutting relation with the outermost coil of the suture spring device having a diameter B.
Guide 324 includes a plurality of connected coils or rings 338 of increasing diameter in a distal direction, the rings being axially spaced between proximal and distal ends 340 and 342 of the body with a slot 348 formed along an outer peripheral, convex surface of the tubular body to receive the knob of the suture spring device as the suture spring device is loaded into the guide. Distal end 342 of the guide terminates in a sharp, tissue penetrating tip 344. The ring at the proximal end of the guide is of about the same diameter as the outermost ring of the suture spring device, with successive rings of the guide being of progressively larger diameter to radially expand the suture spring device as it is loaded into the guide. One or more of the rings at the distal end of the guide have a predetermined diameter A greater than the diameter B of the outermost coil of the suture spring device in the relaxed, contracted state.
In use, suture spring device 322 is either placed in anatomical tissue with guide 324 or inserted into the guide after the guide has been placed in the tissue. To load the suture spring device into the guide, distal end 332 of the suture spring device is inserted into proximal end 340 of the guide and the suture spring device is rotated relative to the guide, for example, by pushing on knob 334 at the proximal end of the suture spring device. As the suture spring device is advanced distally through the guide, the rings of the suture spring device are elastically deformed by the tubular body of the guide into a radially and axially expanded state where rings of the suture spring device have a radius of curvature and axial spacing similar to that of the guide. Penetration of the tissue with the guide proceeds essentially as described above, with the sharp, tissue penetrating tip 344 ofthe guide being moved to penetrate the tissue and the guide being rotated to create a path through the tissue for occupation by the suture spring device when the guide is removed. Upon removal of the guide 324 from the tissue, the suture spring device 322 will contract radially and axially toward its relaxed, planar spiral configuration thereby compressing or drawing any tissue disposed within the rings 328 radially inward. For example, if the ring of the guide were inserted into the wall of a tubular anatomical structure concentric with the lumen
of the tubular structure, the lumen could be occluded by contraction of the suture spring device toward its relaxed, contracted state.
A modified suture spring device 422, shown in Figs. 21 and 22, is similar to suture spring device 322 but with a proximal end 430 disposed at the end of the outermost coil or ring and a distal end 432 disposed out of the plane of rings 428 at the center of the spiral. Knob 434 of the suture spring device is carried or formed along an outer peripheral, convex surface of the outermost coil near proximal end 430. In use, suture spring device 422 is loaded into a guide by inserting distal end 432 at the center of the spiral into the opening at the proximal end of the guide and rotating the suture spring device relative to the guide to advance the remainder of the suture spring device through the guide. While providing distal end 432 out of the plane of the coils facilitates insertion, it will be appreciated that the distal end can be arranged coplanar with the coils in the relaxed, contracted state and can then be pushed out of the plane of the coils (e.g., by a force perpendicular to the plane) prior to or during insertion.
Another modified suturing system 520 according to the present invention, as illustrated in Fig. 23, includes a suture spring device 522 in an elastically deformed, expanded state disposed within a guide 524 of partly coiled, curved configuration. Suture spring device 522 is similar to the suture spring devices previously described but with proximal and distal ends 530 and 532 overiapping, abutting or engaging one another in a relaxed, contracted state to form a single loop, coil or ring of generally circular configuration, as shown in Fig. 24. A knob or handle 534 in the form of a ball is carried or formed on an outer peripheral, convex edge or surface of the body of the suture spring device near proximal end 530.
Guide 524 includes a tubular body 536 with a partly coiled or curved shape similar to a standard suture needle but defining a lumen 546 therethrough in communication with a slot 548 extending along an outer, convex edge or surface of the guide between proximal and distal ends 540 and 542, the distal end terminating in a sharp, tissue penetrating tip 544.
In use, guide 524 can be used like a suture needle to penetrate through anatomical tissue, preferably with suture spring device 522 disposed in the guide
in the elastically deformed, radially expanded state shown in Fig. 23. For example, when used to suture a pair of anatomical tissue structures together, the sharp, distal tip 544 ofthe guide is moved to penetrate and pass through the first tissue structure T, into the second tissue structure T2. The guide is then advanced distally through the second tissue structure until the sharp, tissue penetrating tip 544 of the guide emerges from the second tissue structure, after which the suture spring device 522 is positioned in the tissue and penetration with the guide is discontinued. Guide 524 may then be withdrawn from suture spring device 522 by holding knob 534 of the suture spring device and either retracting the guide in a proximal direction or grasping the distal end of the guide with an instrument such as a needle holder and pulling the guide completely through the tissue in a distal direction as in conventional suturing. Once the guide is removed, suture spring device 522 will no longer be restrained, and proximal and distal ends 530 and 532 of the suture spring device will move toward the relaxed, contracted state shown in Fig. 24 drawing tissue structures T, and T2 together.
Suture spring device 522 can also be configured as shown by broken lines in Figs. 23 and 24 to form a partial loop, ring or coil with proximal and distal ends 530′ and 532′ circumferentially spaced from one another in the relaxed, contracted state so as not to abut, overlap or engage one another.
Use of suture spring device 522 to perform anastomosis of tubular anatomical structures T, and T2 is illustrated in Figs. 25 and 26 wherein inverted, abutting ends E, and Ej of the tubular structures are held together in compression by suture spring devices 522 in the manner described above at a plurality of angularly spaced locations about the periphery of the ends.
In Figs. 23 – 26 the point of penetration or entry for guide 524 is chosen to create a shallow path through anatomical structures T, and T2 less than a ring diameter from an edge of the tissue such that only a portion of the suture spring device 522 is embedded in the tissue when the guide is removed. As a result, when suture spring device 522 moves from the elastically deformed, radially expanded state shown in Fig. 23 toward the relaxed, radially contracted state shown in Fig. 24, proximal and distal ends 530 and 532 of the suture spring device are spaced above the connected edges of the tissue with a gap or
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clearance therebetween. It will be appreciated, however, that the point of penetration for the guide can be varied to increase or decrease the depth of penetration of the suture spring device. For example, in the case of anatomical tissue structures T, and T2 shown in Fig. 27, the point of penetration for the guide is spaced inwardly of the connected tissue edges E, and E2 a distance approximately equal to the ring diameter B of suture spring device 522 to position proximal and distal ends 530 and 532 of the suture spring device immediately adjacent the connected edges of the tissue. This maximizes the depth of penetration of the suture spring device while preventing tissue from becoming trapped or wedged between proximal and distal ends of the suture spring device as the device returns toward the relaxed, contracted state. In Fig. 28, the point of penetration for the guide is spaced from the connected edges E, and E2 of the anatomical structures T, and T2 a distance greater than the ring diameter B so that, when the guide is removed, proximal and distal ends 530 and 532 of the suture spring device will be disposed on opposite sides of the tissue. If proximal and distal ends 530 and 532 have sharp, tissue penetrating tips 531 and 533 as shown, the tips can penetrate into the tissue and overlap, abut or engage one another to form a substantially complete loop, ring or coil in the tissue.
Figs. 29, 30 and 31 illustrate use of the suture spring device 522 to approximate adjacent anatomical tissue structures T, and witn abutting, introverted ends E1 and E2, where by “introverted” is meant being turned outside- in or away from the surgeon. Such a situation can occur, for example, when performing end-to-end anastomosis of separate or severed hollow tubular structures. In Fig. 29, the point of penetration for the guide is chosen to establish a shallow path P through the tissue at the junction of the introverted ends so that proximal and distal ends 530 and 532 of suture spring device 522 will, in the contracted state, protrude outwardly of the tissue to overlap, abut or connect with each other above the junction of the introverted ends with a clearance therebetween. In Fig. 30, the path P established by the guide is somewhat deeper so that proximal and distal ends 530 and 532 of the suture spring device will overlap, abut or connect with each other immediately adjacent the junction of the introverted ends with little or no clearance. The path P established by the
guide in Fig. 31 is sufficiently deep to pass completely through the tissue structure T, on one side of the tissue junction and through introverted ends E, and E2 so that proximal and distal ends 530 and 532 of the suture spring device will close on opposite sides of ends E, and ^ and, if provided with sharp, tissue penetrating tips as shown, the ends of the suture spring device will penetrate into the introverted ends of the tissue to overlap, abut or connect with each another forming a substantially complete loop, ring or coil in the tissue.
Figs. 32, 33 and 34 illustrate use of the suture spring device 522 for approximating anatomical tissue structures T1 and T2 with abutting, non-inverted ends E1 and E2 such as when suturing adjacent anatomical tissue structures or performing real end-to-end anastomosis of severed or separate hollow, tubular anatomical structures with abutting, straight or non-inverted ends. In Fig. 32, the guide is used to make a shallow path P less than a ring diameter below the surface of the tissue so that proximal ends 530 and 532 of suture spring device 522 will, in the contracted state, protrude outwardly of the tissue to overlap, abut or connect with each other above the tissue surface with a clearance. In Fig. 33, the path P established by the guide is about a ring diameter deep so that proximal ends 530 and 532 of the suture spring device 522 overlap, abut or connect with each other immediately adjacent the outer surface of the tissue adjacent the tissue junction. The path P established by the guide in Fig. 34 is more than a ring diameter deep to allow suture spring device 522 to form a loop or ring just beneath the surface of the tissue with proximal and distal ends of the suture spring device being circumferentially spaced from one another in the case of the proximal and distal ends being non-tissue penetrating or overlapping, abutting or connecting with each other in the case of the proximal and distal ends being tissue penetrating as shown.
Another modified suture spring device 622 according to the present invention, shown in a relaxed, contracted state in Figs. 35 and 36, includes a plurality of connected coils or rings 628 of decreasing diameter in a distal direction and a knob or handle 634 in the form of a ball disposed at the proximal end 630 of the suture spring device on an outer, convex surface of a ring. Rings 628 define a generally conical outer surface in the contracted state tapering radially inward
from an open base defined by the proximal coil to an open or closed apex defined by the distal coil. Suture spring device 622 is elastically deformable from the relaxed, contracted state shown to a radially and/or axially expanded state using any of the guides shown or described herein. When in the expanded state, the suture spring device 622 can be used to approximate anatomical tissue in any of the ways described above with the apex open or closed.
Suture spring device 622 can also be axially reversed as indicated by broken lines in Figs. 35 and 36 so that end 630 adjacent the base of the conical suture spring device defines the distal end of the device and end 632 adjacent the apex of the conical suture spring device defines the proximal end of the device. Knob 634′ of the reversed suture spring device is mounted adjacent end 632 near the apex of the suture spring device. When placed in anatomical tissue, it will be appreciated that either embodiment of the suture spring device 622 will be less prone to becoming unscrewed because of the variation in coil diameter.
The modified suture spring device 722 shown in a relaxed, contracted state in Figs. 37 and 38 includes an elastic body 736 of coiled configuration defining a plurality of connected coils or rings 728 that taper radially outward from axially opposed ends to a medial portion or ring of increased diameter. Rings 728 define a generally spherical outer surface in the relaxed, contracted state with one or both of the opposite axial ends of the device being open or closed dependent upon the procedure to be performed. Suture spring device 722 is elastically deformable from the relaxed, contracted state shown to a radially and/or axially expanded state using any of the guides described herein.
As mentioned previously, the suture spring device 22 can be used to approximate any number of layers. For example, in Fig. 39 the suture spring device 22 is used to connect three layers of anatomical tissue and/or surgical devices such as mesh wherein the layers T1t T2 and T3 are compressed along the longitudinal axis of the suture spring device into substantially abutting relation. In Fig. 40, use of the suture spring device 122 to join adjacent layers T1f T2 and T3 in an anatomical body is shown wherein the layers are naturally spaced or dissected to be spaced and it is desired to maintain the spacing between the layers. Suture spring device 122 is inserted through the layers substantially
perpendicular to the layers in order to align the axial spaces between the rings of the device with the spaces between layers. The initial spacing between the layers is thus substantially maintained by permitting only radial contraction of the suture spring device when suturing the spaced layers.
A further modification of the suturing system according to the present invention is shown in Fig. 41 wherein the modified system 820 includes a suture spring device 822 similar to any of the suture spring devices described herein but without a knob and a tubular guide 824 similar to any of the guides described herein but without a slot. The system 820 further includes a pusher 852 including a flexible rod or finger having a configuration to fit conformably within the lumen of the guide. In use, the suture spring device is inserted into the guide with or without use of the pusher and is held substantially stationary within anatomical tissue by the pusher while the guide is removed by sliding along the pusher in a proximal direction.
Yet another modified suture spring device 922 according to the present invention, as shown in Figs. 42 and 43, includes an elastic body 936 of coiled configuration defining a plurality of oval or elliptical coils or rings 928 with a major dimension or length E greater than a minor dimension or width F. Suture spring device 922 can be elastically deformed from the relaxed, contracted state shown to a radially and/or axially expanded state using any of the guides described herein.
Any of the suture spring devices described herein can be modified as shown in Fig. 44 to include surface features such as tissue engaging teeth 1054 on an inner, concave surface of the rings or on any other part of the exterior surface of the rings. Teeth 1054 can be sharp or rounded or have any configuration to engage anatomical tissue and lock the suture spring device in place relative to the tissue when applied. A suture spring device 1022 provided with surface features such as tissue engaging teeth can be smoothly inserted into anatomical tissue using one of the guides described herein and will be less likely to slip or move relative to the anatomical tissue once applied.
A method of suturing anatomical tissue T adjacent an opening O using a suture spring device according to the present invention is illustrated in Figs. 46
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and 47 wherein tissue edges adjacent the opening are inverted as shown by the broken lines in Fig. 46, for example using a tissue grasping instrument as shown and described in my aforementioned co-pending application entitled “Suture Spring Device Applicator,” to permit guide 124 to penetrate through the inverted tissue on opposite sides of the opening and to coil around the inverted edges thereafter with a suture spring device 122 disposed therein in an elastically deformed, radially expanded state. When guide 124 is removed, suture spring device 122 is no longer restrained and will contract radially toward a relaxed, contracted state around the inverted edges as shown in Fig. 47. At least one of the rings 128 of a suture spring device 122 passes through opposed edges of the tissue on opposite sides of the opening to prevent the suture spring device from slipping relative to the inverted tissue.
Another modified guide 1124, illustrated in Fig. 45, includes a straight shank 1136 extending from a proximal end of the guide to a curved or partly coiled end 1138 terminating distally at a sharp, tissue penetrating tip 1144. Guide 1124 is tubular and hollow to define a lumen 1146 therethrough for passage of a suture spring device and pusher as described above in connection with the suturing system 820 shown in Fig. 41.
A method of suturing plural anatomical tissue structures T1t T2 and T3 is shown in Figs. 48 and 49 wherein a hollow tubular guide 224′ is passed through the structures in succession using the sharp tissue penetrating tip 224′ of the guide to penetrate through the tissue structures. The guide is then removed to allow a suture spring device 222′ similar to suture spring device 222 but without a knob to contract axially and radially toward a relaxed, unexpanded state to approximate the anatomical tissue structures as shown in Fig. 49.
From the above, it will be appreciated that adjacent structures in the body can be sutured together with a suture spring device of coiled configuration by inserting the suture spring device through the structures in an elastically deformed, expanded state and causing the suture spring device to move toward a relaxed, contracted state in order to apply a predetermined compressive force to the structures. An axially compressive force can be applied by positioning the structures in the axial space between rings of the suture spring device when the
device is in an axially expanded state and by allowing the device to axially contract toward the relaxed state. A radially compressive force can be applied by positioning structures concentrically within the central passage or aperture defined by the rings of the suture spring device when the device is radially expanded and by allowing the coils to contract radially toward the relaxed state around the structures. Also, the suture spring device can be oriented at an oblique angle relative to anatomical tissue to hold the tissue (or surgical devices such as mesh attached to the tissue) in tension.
The suture spring device is preferably positioned in anatomical tissue using a guide having a configuration to hold the suture spring device in the elastically deformed, expanded state. The guide can have a tissue penetrating tip as shown, can be blunt, or the distal end of the suture spring device can be used as a tissue penetrating tip either alone or in combination with the distal end of the guide. The guide can be used to position any type of suture device in or in relation to anatomical tissue by creating a path in or in relation to the tissue which the suture device will occupy when the guide is removed. Hence, in addition to applying suture devices having an elastic body of coiled configuration, the guide can, for example, be used to apply rigid suture devices having substantially the same shape and size as the guide, lengths of filamentary suture material, suture devices formed of shape memory alloys such as nitinol and soft materials that are hardened by application of energy (for example using light provided by fiber optics), and suture devices formed of ductile materials, where by “ductile” is meant having a tendency, once bent, to remain in the bent condition. The guide can also be used like a probe to penetrate and dissect anatomical tissue and to supply energy to tissue or devices as required; and, when the guide is used as a probe, instruments such as the grasping instrument shown in my aforementioned U.S. Patent Application Serial No. 08/610,735 entitled “Suture Spring Device Applicator” can be used to bring the tissue or device to the probe.
The suture spring device is preferably formed of an elastic body of coiled configuration, where by “elastic” is meant having an ability to recover an original shape or position after having been deformed, and by “coiled” is meant defining a single coil or ring, a portion of a coil or ring or a series of connected coils or
rings. Any number of rings or coils can be connected to make up a suture spring device according to the present invention. The rings can be circular, elliptical, polygonal or have any other curved or angular configuration in longitudinal cross- section and, when a device has more than one ring, adjacent rings can be of the same size and shape or of different size and shape depending on the desired tissue engaging shape ofthe device. For example, the rings can form conical, bi- conical, cylindrical, spherical or pyramidal surfaces when viewed in elevation from the side. The body of the suture spring device can be solid or hollow and can have any configuration in transverse cross-section including, but not limited to, circular, rectangular, elliptical and polygonal configurations. If the body of the suture spring device is hollow, the guide can be disposed within the body to maintain the suture spring device in the elastically deformed, expanded state. In addition, the exterior surface of the body of the suture spring device can be smooth as shown or provided with means for locking the suture device in tissue to prevent forward and/or rearward movement, such as the locking means shown and described in U.S. Patent No. 5,053,047 to Yoon, the disclosure of which is incorporated herein by reference. When the suture spring device takes the form of a single ring in the relaxed, contracted state, proximal and distal ends of the device can be configured to mate with one another. For example, one end of the suture spring device could be hollow and the other end configured to fit within the hollow end when in the relaxed, contracted state.
The suture spring device can be made of any suitable, medical grade material but is preferably made of an elastic or resilient material, that is, a material able to recover its original position or shape after having been deformed. Furthermore, the spring material can be bioabsorbable or non-bioabsorbable depending on the length of time the tissue is required to be held together. Generally, suitable bioabsorbable materials include thermoplastic polymers such as absorbable polymers and copolymers of poly-dioxane, lactide, glycolide and the like. Polyglycolic acid is disclosed in U.S. Patent Nos. 3,463,158; 3,739,773; and 3,772,420. Suitable polylactic acids are disclosed in U.S. Patent No. 3,636,956. Examples of absorbable polyesters are shown in U.S. Patent Nos. 3,225,766 and 3,883,901. Absorbable cellulose glycolic acid ethers are shown in U.S. Patent
No. 2,764,159. Examples of suitable esters of aipha-cyanoacrylic acid are found in U.S. Patent Nos. 3,527,841 ; 3,564,078 and 3,759,264.
Once the suture spring device is positioned in or with respect to the tissue, the return of the suture spring device toward the rest position can be enhanced, dependent upon the material from which the suture spring device is constructed, by temperature change and/or by the application of electricity, light or other energy to alter the characteristics of the material.
When the suture spring device is provided with a knob or handle, it can be formed separately from the body of the device and connected thereto by any suitable method, such as by welding, or the knob can be formed integrally with the body as a one-piece unit. The knob can have any shape to protrude from the guide including, but not limited to, the spherical shape shown as well as cylindrical, rectangular, elliptical and conical shapes. Furthermore, the knob can be formed by the body of the device itself by turning the proximal end of the body inwardly or outwardly relative to a longitudinal axis of the device. It will also be appreciated that the handle or knob can be placed anywhere on the spring although it is preferred that the knob be placed near the proximal end of the device so as not to interfere with the penetration of the device through anatomical tissue.
The guide can be made of any suitable medically acceptable material, such as stainless steel, so long as it is configured to have a stiffness suitable for maintaining the suture spring device in the expanded state in anatomical tissue. The guide is preferably of coiled configuration as shown but can also be of straight or angled configuration if desired. When the guide is of coiled configuration, the rings of the guide can be circular, elliptical, polygonal or have any other curved or angular configuration and, when a guide has more than one ring, adjacent rings can be of the same size and shape or of different sizes and shapes depending upon the type of procedure to be performed. The guide preferably includes a tubular body which can have any configuration in transverse cross-section including, but not limited to, circular, elliptical, polygonal and open configurations. Also, the shape of the lumen in transverse cross-section can be different than the shape of the outer surface of the guide in transverse cross-
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section so that, for example, the outer surface may be circular and the inner surface polygonal or vice versa. Depending upon the manner in which the suture spring device is moved relative to the guide, the guide can be formed with or without a slot. When formed with a slot, the slot will preferably extend from a proximal end of the guide to a distal end of the guide and will communicate between an exterior surface of the guide and an interior lumen or passage. The slot can have tapered or V-shaped sides to accommodate a ball-shaped handle as shown, or the sides of the slot can be straight. Furthermore, although the slot is shown on the outer, convex side of the guide, it can be formed on the inner, concave side or anywhere inbetween or the slot can be made to spiral around the coiled body of the guide.
Any type of force can be used to move the suture spring device relative to the guide including, but not limited to, mechanical forces provided by springs, magnetic forces and/or hydraulic or pneumatic forces. The suture spring device and guide can be held and manipulated using standard needle-holding instruments and forceps, can be grasped directly by hand, or can be provided as part of an applicator instrument specifically designed to apply suture spring devices of the type described herein. For example, the suture spring device could be applied using the applicator shown and described in my aforementioned co- pending U.S. Patent Application Serial No. 08/610,835, entitled “Suture Spring Device Applicator.”
The features of the various embodiments described above can be combined in any manner desired dependent upon the operational requirements of the procedure to be performed and the complexity of the particular design. The material specifications and dimensions of the suture spring device and guide according to the present invention will vary dependent upon the intended use and, as such, it will appreciated that the particular materials and dimensions listed herein are merely exemplary and not meant to be limiting.
Inasmuch as the present invention is subject to many variations, modifications and changes in detail, it is intended that all subject matter discussed above or shown in the accompanying drawings be interpreted as illustrative only and not be taken in a limiting sense.
Claims (38)
What Is Claimed Is:
1. In combination, a suture spring device comprising an elastic body of coiled configuration having a relaxed, contracted state and an elastically deformed, expanded state; and a guide for positioning said suture spring device in anatomical tissue in said elastically deformed, expanded state, said guide being removable from said suture spring device to permit said suture spring device to move resiliently from said expanded state toward said contracted state to apply a predetermined compressive force to the anatomical tissue.
2. A combination as recited in claim 1 wherein said guide includes a hollow tubular body with proximal and distal ends and said suture spring device is disposed within said hollow tubular body in said elastically deformed, expanded state for positioning in anatomical tissue.
3. A combination as recited in claim 2 wherein said distal end of said guide includes a tissue penetrating tip.
4. A combination as recited in claim 3 wherein said hollow tubular body is formed with a slot extending between said proximal and distal ends and communicating between interior and exterior surfaces of said hollow tubular body.
5. A combination as recited in claim 4 wherein said slot has a width to prevent said suture spring device from passing therethrough when disposed within said hollow tubular body.
6. A combination as recited in claim 5 wherein said suture spring device includes a knob that extends laterally through said slot when said suture spring device is disposed within said guide.
7. A combination as recited in claim 6 wherein said knob includes a ball disposed adjacent said proximal end of said suture spring device.
8. A combination as recited in claim 4 wherein said hollow, tubular body of said guide has a predetermined radius of curvature and said slot is formed on a convex side of said hollow, tubular body.
9. A combination as recited in claim 2 wherein said hollow, tubular body of said guide is of coiled configuration.
10. A combination as recited in claim 9 wherein said coiled tubular body of said guide has a predetermined radius of curvature greater than a radius of curvature of said suture spring device in said relaxed, contracted state.
11. A combination as recited in claim 9 wherein said coiled tubular body of said guide includes a plurality of connected rings having a predetermined axial spacing therebetween and said suture spring device includes a plurality of rings having an axial spacing therebetween in said relaxed, contracted state which is less than said predetermined axial spacing between rings of said guide.
12. A combination as recited in claim 9 wherein said coiled tubular body of said guide includes a plurality of connected rings having a predetermined radius of curvature and a predetermined axial spacing therebetween and said suture spring device includes a plurality of rings having a radius of curvature and an axial spacing in said relaxed, contracted state which are less than said predetermined radius of curvature and said axial spacing of said guide rings.
13. A combination as recited in claim 1 wherein said suture spring device includes a plurality of connected rings of decreasing diameter in an axial direction in said relaxed, contracted state.
14. A combination as recited in claim 1 wherein said suture spring device includes a plurality of connected rings which decrease in diameter from a maximum diameter at a medial portion of said device to a minimum diameter at opposite axial ends of said device when said device is in said relaxed, contracted state.
15. A combination as recited in claim 1 wherein said suture spring device includes a plurality of connected, substantially coplanar rings of diminishing diameter in a radial direction in said relaxed, contracted state.
16. A combination as recited in claim 15 wherein a distal end of said suture spring device is disposed at a center of said rings and bent out of the plane of said rings to facilitate insertion into said guide.
17. A combination as recited in claim 1 wherein said suture spring device includes a ring of generally circular configuration with abutting proximal and distal ends in said relaxed, contracted state.
18. A combination as recited in claim 1 wherein said suture spring device includes a proximal end and a distal end and at least one of said proximal and distal ends of said suture spring device includes a tissue penetrating tip.
19. A combination as recited in claim 2 and further comprising a pusher having a flexible finger movable within said hollow, tubular guide body to control the position of said suture spring device relative to said guide.
20. A method of suturing anatomical tissue comprising the steps of positioning a suture spring device of coiled configuration in the anatomical tissue in an elastically deformed, expanded state; and causing the suture spring device to move from the elastically deformed, expanded state toward a relaxed, contracted state within the anatomical tissue to apply a predetermined compressive force to the tissue.
21. A method of suturing anatomical tissue as recited in claim 20 wherein said positioning step includes penetrating the anatomical tissue with a guide and using the guide to hold the suture spring device in the expanded state.
22. A method of suturing anatomical tissue as recited in claim 21 wherein said causing step includes removing the guide from the suture spring device to allow the suture spring device to move resiliently from the elastically deformed, expanded state toward the relaxed, contracted state in the anatomical tissue.
23. A method of suturing anatomical tissue as recited in claim 22 wherein said causing step further includes holding the suture spring device substantially stationary as the guide is removed.
24. A method of suturing anatomical tissue as recited in claim 23 wherein said holding step includes holding a knob extending laterally outward from the suture spring device through a slot in the guide and said removing step includes sliding the guide past the knob in a proximal direction.
25. A method of suturing anatomical tissue as recited in claim 23 wherein said holding step includes advancing a pusher through the guide to abut the suture spring device and said removing step includes sliding the guide over the pusher in a proximal direction.
26. A method of suturing anatomical tissue as recited in claim 20 wherein said positioning step includes placing the elastically deformed, expanded suture spring device in the wall of a tubular anatomical structure concentric with a longitudinal axis of the structure.
27. A method of suturing anatomical tissue as recited in claim 20 wherein said positioning step includes expanding the suture spring device by O 97/3252
increasing an axial spacing between rings of the suture spring device and placing the expanded suture spring device in anatomical tissue.
28. A method of suturing anatomical tissue as recited in claim 20 wherein said positioning step includes expanding the suture spring device by increasing a radius of curvature of the suture spring device and placing the expanded suture spring device in anatomical tissue.
29. A method of suturing anatomical tissue as recited in claim 20 wherein said positioning step includes expanding the suture spring device by increasing a radius of curvature and an axial spacing between rings of the suture spring device and placing the expanded suture spring device in anatomical tissue.
30. A suture spring device for use with a guide having an elongate, tubular body of coiled configuration terminating distally in a sharp, tissue penetrating tip, the tubular body defining a plurality of connected rings having a predetermined radius of curvature and a predetermined axial spacing therebetween, the sharp, tissue penetrating tip allowing the guide to penetrate and pass through anatomical tissue when the guide is placed against the tissue and rotated about a longitudinal axis of the guide, said suture spring device comprising an elastic body of coiled configuration having an elastically deformed, expanded state with a radius of curvature and axial spacing to fit inside the coiled tubular body of the guide and a relaxed, contracted state where at least one of a radius of curvature and an axial spacing of said elastic body is smaller than the predetermined radius of curvature and axial spacing of the coiled tubular body of the guide so that, when the guide is removed from anatomical tissue after having been used to penetrate the anatomical tissue and position said suture spring device therein, said suture spring device will remain in the tissue and move from said elastically deformed, expanded state toward said relaxed, contracted state to automatically compress the tissue engaged by the device.
31. A suture spring device as recited in claim 30 and further comprising a knob extending laterally outward from said elastic body.
32. A suture spring device as recited in claim 31 wherein said knob is mounted near a proximal end of said elastic body.
33. A suture spring device as recited in claim 30 wherein said elastic body has a radius of curvature about the same as the predetermined radius of curvature of the guide and an axial spacing smaller than the predetermined axial spacing of the guide.
34. A suture spring device as recited in claim 30 wherein said elastic body has a radius of curvature smaller than the predetermined radius of curvature of the guide and an axial spacing about the same as the predetermined axial spacing of the guide.
35. A suture spring device as recited in claim 30 wherein said elastic body has a radius of curvature smaller than the predetermined radius of curvature of the guide and an axial spacing smaller than the predetermined axial spacing of the guide.
36. A suture spring device as recited in claim 30 wherein said elastic body defines a plurality of inwardly spiraled, coplanar rings of diminishing diameter in a radial direction and an end of said elastic body at a center of said rings is angled out of plane relative to said inwardly spiraled rings to facilitate threading of said suture spring device into a hollow guide.
37. A method of suturing anatomical tissue comprising the steps of penetrating the anatomical tissue with a guide; using the guide to position a suture device in the anatomical tissue in an expanded state; and O 97/32526
causing the suture device to move from the expanded state toward a contracted state within the anatomical tissue to apply a predetermined compressive force to the tissue.
38. A method of suturing anatomical tissue as recited in claim 37 wherein the suture device includes an elastic body of coiled configuration in the contracted state and said causing step includes removing the guide from the suture device to allow the suture device to move resiliently from the expanded state toward the contracted state within the anatomical tissue.
AU21375/97A
1996-03-05
1997-03-05
Suture spring device
Ceased
AU719161B2
(en)
Applications Claiming Priority (3)
Application Number
Priority Date
Filing Date
Title
US08/610951
1996-03-05
US08/610,951
US5810851A
(en)
1996-03-05
1996-03-05
Suture spring device
PCT/US1997/002978
WO1997032526A1
(en)
1996-03-05
1997-03-05
Suture spring device
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AU2137597A
true
AU2137597A
(en)
1997-09-22
AU719161B2
AU719161B2
(en)
2000-05-04
Family
ID=24447053
Family Applications (1)
Application Number
Title
Priority Date
Filing Date
AU21375/97A
Ceased
AU719161B2
(en)
1996-03-05
1997-03-05
Suture spring device
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US
(1)
US5810851A
(en)
EP
(1)
EP0955897A1
(en)
AU
(1)
AU719161B2
(en)
CA
(1)
CA2248122A1
(en)
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(en)
Families Citing this family (347)
* Cited by examiner, † Cited by third party
Publication number
Priority date
Publication date
Assignee
Title
US5976159A
(en)
1995-02-24
1999-11-02
Heartport, Inc.
Surgical clips and methods for tissue approximation
US6984241B2
(en)
*
1996-09-13
2006-01-10
Tendon Technology, Ltd.
Apparatus and methods for tendon or ligament repair
US5957879A
(en)
*
1997-01-24
1999-09-28
Heartport, Inc.
Methods and devices for maintaining cardiopulmonary bypass and arresting a patient’s heart
US6071292A
(en)
*
1997-06-28
2000-06-06
Transvascular, Inc.
Transluminal methods and devices for closing, forming attachments to, and/or forming anastomotic junctions in, luminal anatomical structures
US6740098B2
(en)
1998-05-11
2004-05-25
Surgical Connections, Inc.
Surgical stabilizer devices and methods
US20050021085A1
(en)
*
1998-05-11
2005-01-27
Surgical Connections, Inc.
Surgical stabilizer devices and methods
US6517566B1
(en)
*
1998-05-11
2003-02-11
Surgical Connections, Inc.
Devices and methods for treating e.g. urinary stress incontinence
AU2001217746A1
(en)
*
1998-05-14
2002-05-27
Calypso Medical, Inc.
Systems and methods for locating and defining a target location within a human body
US6514265B2
(en)
1999-03-01
2003-02-04
Coalescent Surgical, Inc.
Tissue connector apparatus with cable release
US6607541B1
(en)
1998-06-03
2003-08-19
Coalescent Surgical, Inc.
Tissue connector apparatus and methods
US6613059B2
(en)
1999-03-01
2003-09-02
Coalescent Surgical, Inc.
Tissue connector apparatus and methods
EP1997441B1
(en)
*
1998-06-03
2011-07-20
Medtronic, Inc.
Tissue connector apparatus
US6945980B2
(en)
*
1998-06-03
2005-09-20
Medtronic, Inc.
Multiple loop tissue connector apparatus and methods
DE69942800D1
(en)
*
1998-06-03
2010-11-11
Medtronic Inc
DEVICES FOR CONNECTING TISSUE
US6641593B1
(en)
*
1998-06-03
2003-11-04
Coalescent Surgical, Inc.
Tissue connector apparatus and methods
US6325813B1
(en)
1998-08-18
2001-12-04
Scimed Life Systems, Inc.
Method and apparatus for stabilizing vascular wall
US8118822B2
(en)
1999-03-01
2012-02-21
Medtronic, Inc.
Bridge clip tissue connector apparatus and methods
US6981983B1
(en)
1999-03-31
2006-01-03
Rosenblatt Peter L
System and methods for soft tissue reconstruction
US20050283189A1
(en)
*
1999-03-31
2005-12-22
Rosenblatt Peter L
Systems and methods for soft tissue reconstruction
AU4187800A
(en)
*
1999-03-31
2000-10-16
Peter L. Rosenblatt
Systems and methods for soft tissue reconstruction
US6695859B1
(en)
1999-04-05
2004-02-24
Coalescent Surgical, Inc.
Apparatus and methods for anastomosis
FR2791883B1
(en)
1999-04-08
2001-08-10
Ethicon Inc
FLEXIBLE PROSTHESIS IN PARTICULAR FOR CELIOSCOPIC HERNIA TREATMENT
US20070038231A1
(en)
1999-05-28
2007-02-15
Ferree Bret A
Methods and apparatus for treating disc herniation and preventing the extrusion of interbody bone graft
US7273497B2
(en)
1999-05-28
2007-09-25
Anova Corp.
Methods for treating a defect in the annulus fibrosis
US20060247665A1
(en)
1999-05-28
2006-11-02
Ferree Bret A
Methods and apparatus for treating disc herniation and preventing the extrusion of interbody bone graft
US8574243B2
(en)
1999-06-25
2013-11-05
Usgi Medical, Inc.
Apparatus and methods for forming and securing gastrointestinal tissue folds
US7637905B2
(en)
2003-01-15
2009-12-29
Usgi Medical, Inc.
Endoluminal tool deployment system
US7416554B2
(en)
2002-12-11
2008-08-26
Usgi Medical Inc
Apparatus and methods for forming and securing gastrointestinal tissue folds
US7618426B2
(en)
2002-12-11
2009-11-17
Usgi Medical, Inc.
Apparatus and methods for forming gastrointestinal tissue approximations
US6425919B1
(en)
1999-08-18
2002-07-30
Intrinsic Orthopedics, Inc.
Devices and methods of vertebral disc augmentation
US7972337B2
(en)
2005-12-28
2011-07-05
Intrinsic Therapeutics, Inc.
Devices and methods for bone anchoring
US7094258B2
(en)
1999-08-18
2006-08-22
Intrinsic Therapeutics, Inc.
Methods of reinforcing an annulus fibrosis
JP4247519B2
(en)
1999-08-18
2009-04-02
イントリンジック セラピューティックス インコーポレイテッド
Apparatus and method for nucleus augmentation and retention
US7998213B2
(en)
1999-08-18
2011-08-16
Intrinsic Therapeutics, Inc.
Intervertebral disc herniation repair
US7553329B2
(en)
1999-08-18
2009-06-30
Intrinsic Therapeutics, Inc.
Stabilized intervertebral disc barrier
US7717961B2
(en)
1999-08-18
2010-05-18
Intrinsic Therapeutics, Inc.
Apparatus delivery in an intervertebral disc
WO2004100841A1
(en)
1999-08-18
2004-11-25
Intrinsic Therapeutics, Inc.
Devices and method for augmenting a vertebral disc nucleus
US8323341B2
(en)
2007-09-07
2012-12-04
Intrinsic Therapeutics, Inc.
Impaction grafting for vertebral fusion
US8529583B1
(en)
1999-09-03
2013-09-10
Medtronic, Inc.
Surgical clip removal apparatus
ATE298532T1
(en)
1999-09-29
2005-07-15
Zimmer Gmbh
TISSUE HOLDER
EP1088518B1
(en)
*
1999-09-29
2005-06-29
Zimmer GmbH
Surgical fixing device
US6592625B2
(en)
1999-10-20
2003-07-15
Anulex Technologies, Inc.
Spinal disc annulus reconstruction method and spinal disc annulus stent
US8128698B2
(en)
1999-10-20
2012-03-06
Anulex Technologies, Inc.
Method and apparatus for the treatment of the intervertebral disc annulus
US7935147B2
(en)
1999-10-20
2011-05-03
Anulex Technologies, Inc.
Method and apparatus for enhanced delivery of treatment device to the intervertebral disc annulus
US7615076B2
(en)
1999-10-20
2009-11-10
Anulex Technologies, Inc.
Method and apparatus for the treatment of the intervertebral disc annulus
US7951201B2
(en)
1999-10-20
2011-05-31
Anulex Technologies, Inc.
Method and apparatus for the treatment of the intervertebral disc annulus
US7052516B2
(en)
1999-10-20
2006-05-30
Anulex Technologies, Inc.
Spinal disc annulus reconstruction method and deformable spinal disc annulus stent
US8632590B2
(en)
1999-10-20
2014-01-21
Anulex Technologies, Inc.
Apparatus and methods for the treatment of the intervertebral disc
US7004970B2
(en)
1999-10-20
2006-02-28
Anulex Technologies, Inc.
Methods and devices for spinal disc annulus reconstruction and repair
US6926730B1
(en)
2000-10-10
2005-08-09
Medtronic, Inc.
Minimally invasive valve repair procedure and apparatus
US6391048B1
(en)
2000-01-05
2002-05-21
Integrated Vascular Systems, Inc.
Integrated vascular device with puncture site closure component and sealant and methods of use
US6780197B2
(en)
2000-01-05
2004-08-24
Integrated Vascular Systems, Inc.
Apparatus and methods for delivering a vascular closure device to a body lumen
US6197042B1
(en)
2000-01-05
2001-03-06
Medical Technology Group, Inc.
Vascular sheath with puncture site closure apparatus and methods of use
US9579091B2
(en)
2000-01-05
2017-02-28
Integrated Vascular Systems, Inc.
Closure system and methods of use
US6461364B1
(en)
2000-01-05
2002-10-08
Integrated Vascular Systems, Inc.
Vascular sheath with bioabsorbable puncture site closure apparatus and methods of use
US8758400B2
(en)
2000-01-05
2014-06-24
Integrated Vascular Systems, Inc.
Closure system and methods of use
US6942674B2
(en)
*
2000-01-05
2005-09-13
Integrated Vascular Systems, Inc.
Apparatus and methods for delivering a closure device
US7842068B2
(en)
2000-12-07
2010-11-30
Integrated Vascular Systems, Inc.
Apparatus and methods for providing tactile feedback while delivering a closure device
EP1897504A3
(en)
*
2000-02-09
2008-05-07
Eva Corporation
Surgical fastener
JP2003521989A
(en)
*
2000-02-09
2003-07-22
イーバ コーポレイション
Surgical fasteners
US6916327B2
(en)
2000-03-07
2005-07-12
Metacardia, Inc.
Device for creating an anastomosis, including penetration structure and eversion structure
US6551332B1
(en)
2000-03-31
2003-04-22
Coalescent Surgical, Inc.
Multiple bias surgical fastener
US6805695B2
(en)
2000-04-04
2004-10-19
Spinalabs, Llc
Devices and methods for annular repair of intervertebral discs
US6610067B2
(en)
2000-05-01
2003-08-26
Arthrosurface, Incorporated
System and method for joint resurface repair
US6520964B2
(en)
2000-05-01
2003-02-18
Std Manufacturing, Inc.
System and method for joint resurface repair
US7713305B2
(en)
2000-05-01
2010-05-11
Arthrosurface, Inc.
Articular surface implant
US7618462B2
(en)
2000-05-01
2009-11-17
Arthrosurface Incorporated
System and method for joint resurface repair
US7163541B2
(en)
2002-12-03
2007-01-16
Arthrosurface Incorporated
Tibial resurfacing system
US7678151B2
(en)
2000-05-01
2010-03-16
Ek Steven W
System and method for joint resurface repair
US8177841B2
(en)
2000-05-01
2012-05-15
Arthrosurface Inc.
System and method for joint resurface repair
FR2812188B1
(en)
*
2000-07-31
2003-06-13
Spinevision Sa
RACHIS IMMOBILIZATION CAGE AND OSTEOSYNTHESIS, METHOD FOR MANUFACTURING THE CAGE AND DRILLING EQUIPMENT FOR THE LAYOUT OF THE CAGE
WO2002017797A1
(en)
*
2000-09-01
2002-03-07
Advanced Vascular Technologies, Llc
Endovascular fastener and grafting apparatus and method
WO2002017796A1
(en)
2000-09-01
2002-03-07
Advanced Vascular Technologies, Llc
Vascular bypass grafting instrument and method
EP1317213A2
(en)
*
2000-09-01
2003-06-11
Advanced Vascular Technologies LLC
Multi-fastener surgical apparatus and method
EP1294289B8
(en)
2000-09-08
2007-07-04
Abbott Vascular Inc
Surgical stapler
WO2002026168A2
(en)
*
2000-09-29
2002-04-04
Tricardia, Llc
Venous valvuloplasty device
US6953462B2
(en)
*
2000-10-05
2005-10-11
The Cleveland Clinic Foundation
Apparatus for implantation into bone
US6468309B1
(en)
2000-10-05
2002-10-22
Cleveland Clinic Foundation
Method and apparatus for stabilizing adjacent bones
US6551322B1
(en)
2000-10-05
2003-04-22
The Cleveland Clinic Foundation
Apparatus for implantation into bone
US6626918B1
(en)
2000-10-06
2003-09-30
Medical Technology Group
Apparatus and methods for positioning a vascular sheath
AU2002246923A1
(en)
*
2000-10-20
2002-07-30
Onux Medical, Inc.
Surgical suturing instrument and method of use
WO2002034122A2
(en)
*
2000-10-20
2002-05-02
Onux Medical, Inc.
Surgical suturing instrument and method of use
US6663633B1
(en)
*
2000-10-25
2003-12-16
Pierson, Iii Raymond H.
Helical orthopedic fixation and reduction device, insertion system, and associated methods
US7033373B2
(en)
2000-11-03
2006-04-25
Satiety, Inc.
Method and device for use in minimally invasive placement of space-occupying intragastric devices
US6551320B2
(en)
2000-11-08
2003-04-22
The Cleveland Clinic Foundation
Method and apparatus for correcting spinal deformity
US6527774B2
(en)
2000-11-08
2003-03-04
The Cleveland Clinic Foundation
Apparatus for attaching fractured sections of bone
US6488683B2
(en)
2000-11-08
2002-12-03
Cleveland Clinic Foundation
Method and apparatus for correcting spinal deformity
US6551319B2
(en)
2000-11-08
2003-04-22
The Cleveland Clinic Foundation
Apparatus for implantation into bone
US6544265B2
(en)
2000-11-08
2003-04-08
The Cleveland Clinic Foundation
Apparatus for implantation into bone related applications
US6695867B2
(en)
2002-02-21
2004-02-24
Integrated Vascular Systems, Inc.
Plunger apparatus and methods for delivering a closure device
US7211101B2
(en)
2000-12-07
2007-05-01
Abbott Vascular Devices
Methods for manufacturing a clip and clip
US7905900B2
(en)
2003-01-30
2011-03-15
Integrated Vascular Systems, Inc.
Clip applier and methods of use
US6623510B2
(en)
2000-12-07
2003-09-23
Integrated Vascular Systems, Inc.
Closure device and methods for making and using them
US7806904B2
(en)
2000-12-07
2010-10-05
Integrated Vascular Systems, Inc.
Closure device
US8690910B2
(en)
2000-12-07
2014-04-08
Integrated Vascular Systems, Inc.
Closure device and methods for making and using them
US6719777B2
(en)
2000-12-07
2004-04-13
Integrated Vascular Systems, Inc.
Closure device and methods for making and using them
US20020173803A1
(en)
2001-05-01
2002-11-21
Stephen Ainsworth
Self-closing surgical clip for tissue
US7083629B2
(en)
*
2001-05-30
2006-08-01
Satiety, Inc.
Overtube apparatus for insertion into a body
US6558400B2
(en)
2001-05-30
2003-05-06
Satiety, Inc.
Obesity treatment tools and methods
IES20010547A2
(en)
2001-06-07
2002-12-11
Christy Cummins
Surgical Staple
US20020193685A1
(en)
2001-06-08
2002-12-19
Calypso Medical, Inc.
Guided Radiation Therapy System
US7497862B2
(en)
*
2001-08-03
2009-03-03
Tyco Healthcare Group Lp
Tissue marking apparatus and method
US7104949B2
(en)
*
2001-08-31
2006-09-12
Ams Research Corporation
Surgical articles for placing an implant about a tubular tissue structure and methods
US7135978B2
(en)
2001-09-14
2006-11-14
Calypso Medical Technologies, Inc.
Miniature resonating marker assembly
US10098640B2
(en)
2001-12-04
2018-10-16
Atricure, Inc.
Left atrial appendage devices and methods
US20030225420A1
(en)
*
2002-03-11
2003-12-04
Wardle John L.
Surgical coils and methods of deploying
WO2003088815A2
(en)
*
2002-04-17
2003-10-30
Tyco Healthcare Group, Lp
Tacking tool and tack
WO2003088846A1
(en)
2002-04-22
2003-10-30
Tyco Healthcare Group, Lp
Tack and tack applier
US7494496B2
(en)
*
2002-05-17
2009-02-24
Ucl Biomedica Plc
Device for transfixing and joining tissue
US7850709B2
(en)
2002-06-04
2010-12-14
Abbott Vascular Inc.
Blood vessel closure clip and delivery device
US8244330B2
(en)
2004-07-23
2012-08-14
Varian Medical Systems, Inc.
Integrated radiation therapy systems and methods for treating a target in a patient
US7101395B2
(en)
*
2002-06-12
2006-09-05
Mitral Interventions, Inc.
Method and apparatus for tissue connection
US6746460B2
(en)
2002-08-07
2004-06-08
Satiety, Inc.
Intra-gastric fastening devices
US7214233B2
(en)
2002-08-30
2007-05-08
Satiety, Inc.
Methods and devices for maintaining a space occupying device in a relatively fixed location within a stomach
US7033384B2
(en)
2002-08-30
2006-04-25
Satiety, Inc.
Stented anchoring of gastric space-occupying devices
US20040138704A1
(en)
*
2002-09-06
2004-07-15
Gambale Richard A.
Tissue capturing devices
US8066724B2
(en)
2002-09-12
2011-11-29
Medtronic, Inc.
Anastomosis apparatus and methods
US20040054375A1
(en)
*
2002-09-18
2004-03-18
Liganex Llc
Methods and apparatus for vessel ligation
US8105345B2
(en)
2002-10-04
2012-01-31
Medtronic, Inc.
Anastomosis apparatus and methods
US7220237B2
(en)
2002-10-23
2007-05-22
Satiety, Inc.
Method and device for use in endoscopic organ procedures
US7108710B2
(en)
2002-11-26
2006-09-19
Abbott Laboratories
Multi-element biased suture clip
US7901408B2
(en)
2002-12-03
2011-03-08
Arthrosurface, Inc.
System and method for retrograde procedure
US7942898B2
(en)
2002-12-11
2011-05-17
Usgi Medical, Inc.
Delivery systems and methods for gastric reduction
US7942884B2
(en)
2002-12-11
2011-05-17
Usgi Medical, Inc.
Methods for reduction of a gastric lumen
US7912529B2
(en)
*
2002-12-30
2011-03-22
Calypso Medical Technologies, Inc.
Panel-type sensor/source array assembly
US7926491B2
(en)
*
2002-12-31
2011-04-19
Calypso Medical Technologies, Inc.
Method and apparatus for sensing field strength signals to estimate location of a wireless implantable marker
US9248003B2
(en)
2002-12-30
2016-02-02
Varian Medical Systems, Inc.
Receiver used in marker localization sensing system and tunable to marker frequency
US7247160B2
(en)
*
2002-12-30
2007-07-24
Calypso Medical Technologies, Inc.
Apparatuses and methods for percutaneously implanting objects in patients
US8905937B2
(en)
2009-02-26
2014-12-09
Integrated Vascular Systems, Inc.
Methods and apparatus for locating a surface of a body lumen
US8398656B2
(en)
2003-01-30
2013-03-19
Integrated Vascular Systems, Inc.
Clip applier and methods of use
US8202293B2
(en)
2003-01-30
2012-06-19
Integrated Vascular Systems, Inc.
Clip applier and methods of use
US7857828B2
(en)
2003-01-30
2010-12-28
Integrated Vascular Systems, Inc.
Clip applier and methods of use
US8821534B2
(en)
2010-12-06
2014-09-02
Integrated Vascular Systems, Inc.
Clip applier having improved hemostasis and methods of use
US8758398B2
(en)
2006-09-08
2014-06-24
Integrated Vascular Systems, Inc.
Apparatus and method for delivering a closure element
US8388624B2
(en)
2003-02-24
2013-03-05
Arthrosurface Incorporated
Trochlear resurfacing system and method
US7175638B2
(en)
*
2003-04-16
2007-02-13
Satiety, Inc.
Method and devices for modifying the function of a body organ
PT1628702E
(en)
*
2003-04-28
2013-08-22
Erwin De Winter
Anchoring screw device
DE602004031612D1
(en)
2003-06-20
2011-04-14
Intrinsic Therapeutics Inc
DEVICE FOR DISTRIBUTING AN IMPLANT THROUGH A RINGED DEFECT IN A RIBBON DISC
US7182769B2
(en)
2003-07-25
2007-02-27
Medtronic, Inc.
Sealing clip, delivery systems, and methods
US8216252B2
(en)
2004-05-07
2012-07-10
Usgi Medical, Inc.
Tissue manipulation and securement system
US20050043749A1
(en)
2003-08-22
2005-02-24
Coalescent Surgical, Inc.
Eversion apparatus and methods
US8394114B2
(en)
2003-09-26
2013-03-12
Medtronic, Inc.
Surgical connection apparatus and methods
US7914543B2
(en)
2003-10-14
2011-03-29
Satiety, Inc.
Single fold device for tissue fixation
US7097650B2
(en)
2003-10-14
2006-08-29
Satiety, Inc.
System for tissue approximation and fixation
US7951163B2
(en)
2003-11-20
2011-05-31
Arthrosurface, Inc.
Retrograde excision system and apparatus
CA2546582A1
(en)
2003-11-20
2005-06-09
Arthrosurface, Inc.
Retrograde delivery of resurfacing devices
EP1845890A4
(en)
2003-11-20
2010-06-09
Arthrosurface Inc
System and method for retrograde procedure
US7879047B2
(en)
*
2003-12-10
2011-02-01
Medtronic, Inc.
Surgical connection apparatus and methods
US20050251189A1
(en)
2004-05-07
2005-11-10
Usgi Medical Inc.
Multi-position tissue manipulation assembly
US7347863B2
(en)
2004-05-07
2008-03-25
Usgi Medical, Inc.
Apparatus and methods for manipulating and securing tissue
US7361180B2
(en)
2004-05-07
2008-04-22
Usgi Medical, Inc.
Apparatus for manipulating and securing tissue
EP1547526A1
(en)
*
2003-12-23
2005-06-29
UMC Utrecht Holding B.V.
Operation element, operation set and method for use thereof
US7684849B2
(en)
*
2003-12-31
2010-03-23
Calypso Medical Technologies, Inc.
Marker localization sensing system synchronized with radiation source
US20050154280A1
(en)
*
2003-12-31
2005-07-14
Wright J. N.
Receiver used in marker localization sensing system
WO2005067563A2
(en)
*
2004-01-12
2005-07-28
Calypso Medical Technologies, Inc.
Instruments with location markers and methods for tracking instruments through anatomical passageways
US20050177176A1
(en)
2004-02-05
2005-08-11
Craig Gerbi
Single-fold system for tissue approximation and fixation
US20070135838A1
(en)
*
2004-02-09
2007-06-14
Meyer Matthew E
Safety suture needle assemblies and methods
WO2005079673A2
(en)
2004-02-13
2005-09-01
Satiety, Inc.
Methods for reducing hollow organ volume
US8882786B2
(en)
*
2004-02-17
2014-11-11
Lawrence Livermore National Security, Llc.
System for closure of a physical anomaly
AU2005218318A1
(en)
2004-02-27
2005-09-15
Ethicon Endo-Surgery, Inc
Methods and devices for reducing hollow organ volume
US9028511B2
(en)
2004-03-09
2015-05-12
Ethicon Endo-Surgery, Inc.
Devices and methods for placement of partitions within a hollow body organ
US8628547B2
(en)
2004-03-09
2014-01-14
Ethicon Endo-Surgery, Inc.
Devices and methods for placement of partitions within a hollow body organ
US7703459B2
(en)
2004-03-09
2010-04-27
Usgi Medical, Inc.
Apparatus and methods for mapping out endoluminal gastrointestinal surgery
US8449560B2
(en)
2004-03-09
2013-05-28
Satiety, Inc.
Devices and methods for placement of partitions within a hollow body organ
US8252009B2
(en)
2004-03-09
2012-08-28
Ethicon Endo-Surgery, Inc.
Devices and methods for placement of partitions within a hollow body organ
US7513904B2
(en)
*
2004-03-15
2009-04-07
Marlen Andreevich Sulamanidze
Surgical thread and cosmetic surgery method
AU2005231323B2
(en)
2004-03-26
2011-03-31
Ethicon Endo-Surgery, Inc
Systems and methods for treating obesity
US7736374B2
(en)
2004-05-07
2010-06-15
Usgi Medical, Inc.
Tissue manipulation and securement system
US7736378B2
(en)
2004-05-07
2010-06-15
Usgi Medical, Inc.
Apparatus and methods for positioning and securing anchors
US7918869B2
(en)
2004-05-07
2011-04-05
Usgi Medical, Inc.
Methods and apparatus for performing endoluminal gastroplasty
US8257394B2
(en)
2004-05-07
2012-09-04
Usgi Medical, Inc.
Apparatus and methods for positioning and securing anchors
US8444657B2
(en)
2004-05-07
2013-05-21
Usgi Medical, Inc.
Apparatus and methods for rapid deployment of tissue anchors
IES20040368A2
(en)
2004-05-25
2005-11-30
James E Coleman
Surgical stapler
US7645285B2
(en)
*
2004-05-26
2010-01-12
Idx Medical, Ltd
Apparatus and methods for occluding a hollow anatomical structure
US7736379B2
(en)
2004-06-09
2010-06-15
Usgi Medical, Inc.
Compressible tissue anchor assemblies
US8206417B2
(en)
2004-06-09
2012-06-26
Usgi Medical Inc.
Apparatus and methods for optimizing anchoring force
US7678135B2
(en)
2004-06-09
2010-03-16
Usgi Medical, Inc.
Compressible tissue anchor assemblies
US7695493B2
(en)
2004-06-09
2010-04-13
Usgi Medical, Inc.
System for optimizing anchoring force
JP2008507996A
(en)
2004-06-24
2008-03-21
カリプソー メディカル テクノロジーズ インコーポレイテッド
System and method for treating a patient’s lung using guided radiation therapy or surgery
AU2005260590A1
(en)
2004-06-28
2006-01-12
Arthrosurface, Inc.
System for articular surface replacement
WO2006023055A2
(en)
2004-07-23
2006-03-02
Calypso Medical Technologies, Inc.
Systems and methods for real time tracking of targets in radiation therapy and other medical applications
WO2006012630A2
(en)
*
2004-07-23
2006-02-02
Calypso Medical Technologies, Inc.
Apparatuses and methods for percutaneously implanting objects in patients
US9586059B2
(en)
2004-07-23
2017-03-07
Varian Medical Systems, Inc.
User interface for guided radiation therapy
US7899513B2
(en)
2004-07-23
2011-03-01
Calypso Medical Technologies, Inc.
Modular software system for guided radiation therapy
US8437449B2
(en)
2004-07-23
2013-05-07
Varian Medical Systems, Inc.
Dynamic/adaptive treatment planning for radiation therapy
US8095203B2
(en)
2004-07-23
2012-01-10
Varian Medical Systems, Inc.
Data processing for real-time tracking of a target in radiation therapy
US9138228B2
(en)
2004-08-11
2015-09-22
Emory University
Vascular conduit device and system for implanting
ATE410961T1
(en)
*
2004-08-16
2008-10-15
Zimmer Spine Inc
SPIRAL SEWING DEVICE
US8876820B2
(en)
2004-10-20
2014-11-04
Atricure, Inc.
Surgical clamp
US20060106288A1
(en)
2004-11-17
2006-05-18
Roth Alex T
Remote tissue retraction device
US7828853B2
(en)
2004-11-22
2010-11-09
Arthrosurface, Inc.
Articular surface implant and delivery system
CH697177A5
(en)
*
2004-12-17
2008-06-25
Zuercher Hochschule Winterthur
Helix needle.
US7731705B2
(en)
2005-01-10
2010-06-08
Wardle John L
Eluting coils and methods of deploying and retrieving
US8789736B2
(en)
*
2005-02-04
2014-07-29
Moshe Dudai
Staples, staplers, anastomosis devices, and methods for their applications
CA2603499A1
(en)
2005-04-22
2006-11-02
Rex Medical, L.P.
Closure device for left atrial appendage
CN101193665B
(en)
2005-05-04
2012-03-28
斯恩蒂斯有限公司
Joining element
US8298291B2
(en)
2005-05-26
2012-10-30
Usgi Medical, Inc.
Methods and apparatus for securing and deploying tissue anchors
US9585651B2
(en)
2005-05-26
2017-03-07
Usgi Medical, Inc.
Methods and apparatus for securing and deploying tissue anchors
US8926633B2
(en)
2005-06-24
2015-01-06
Abbott Laboratories
Apparatus and method for delivering a closure element
US8313497B2
(en)
2005-07-01
2012-11-20
Abbott Laboratories
Clip applier and methods of use
WO2007009099A2
(en)
2005-07-14
2007-01-18
Idx Medical Ltd.
Apparatus and methods for occluding a hollow anatomical structure
US9456811B2
(en)
2005-08-24
2016-10-04
Abbott Vascular Inc.
Vascular closure methods and apparatuses
US20070060895A1
(en)
2005-08-24
2007-03-15
Sibbitt Wilmer L Jr
Vascular closure methods and apparatuses
US8920442B2
(en)
2005-08-24
2014-12-30
Abbott Vascular Inc.
Vascular opening edge eversion methods and apparatuses
EP1926520B1
(en)
2005-09-19
2015-11-11
Varian Medical Systems, Inc.
Apparatus and methods for implanting objects, such as bronchoscopically implanting markers in the lung of patients
WO2007061890A2
(en)
2005-11-17
2007-05-31
Calypso Medical Technologies, Inc.
Apparatus and methods for using an electromagnetic transponder in orthopedic procedures
US8726909B2
(en)
2006-01-27
2014-05-20
Usgi Medical, Inc.
Methods and apparatus for revision of obesity procedures
US8808310B2
(en)
2006-04-20
2014-08-19
Integrated Vascular Systems, Inc.
Resettable clip applier and reset tools
US9232938B2
(en)
2006-06-13
2016-01-12
Anova Corp.
Method and apparatus for closing fissures in the annulus fibrosus
US8834496B2
(en)
2006-06-13
2014-09-16
Bret A. Ferree
Soft tissue repair methods and apparatus
US8821549B2
(en)
2006-06-13
2014-09-02
Anova Corporation
Methods and apparatus for anulus repair
US8764835B2
(en)
2006-06-13
2014-07-01
Bret A. Ferree
Intervertebral disc treatment methods and apparatus
US8556930B2
(en)
*
2006-06-28
2013-10-15
Abbott Laboratories
Vessel closure device
USD611144S1
(en)
2006-06-28
2010-03-02
Abbott Laboratories
Apparatus for delivering a closure element
CN101511278B
(en)
*
2006-07-01
2012-03-14
欧帕斯Ksd股份有限公司
Tissue fasteners and related insertion devices, mechanisms, and methods
US8870916B2
(en)
2006-07-07
2014-10-28
USGI Medical, Inc
Low profile tissue anchors, tissue anchor systems, and methods for their delivery and use
US20110213375A1
(en)
2006-07-17
2011-09-01
Arthrosurface, Inc.
Tibial Resurfacing System and Method
CA2686814A1
(en)
2006-12-11
2008-06-19
Arthrosurface Incorporated
Retrograde resection apparatus and method
US8591533B2
(en)
*
2007-02-06
2013-11-26
The Ohio State University Research Foundation
Endolumenal restriction method and apparatus
US20080208214A1
(en)
*
2007-02-26
2008-08-28
Olympus Medical Systems Corp.
Applicator and tissue fastening method through natural orifice
US20080243141A1
(en)
2007-04-02
2008-10-02
Salvatore Privitera
Surgical instrument with separate tool head and method of use
FR2915087B1
(en)
*
2007-04-20
2021-11-26
Corevalve Inc
IMPLANT FOR TREATMENT OF A HEART VALVE, IN PARTICULAR OF A MITRAL VALVE, EQUIPMENT INCLUDING THIS IMPLANT AND MATERIAL FOR PLACING THIS IMPLANT.
US7846123B2
(en)
2007-04-24
2010-12-07
Emory University
Conduit device and system for implanting a conduit device in a tissue wall
US20080300628A1
(en)
*
2007-06-01
2008-12-04
Abbott Laboratories
Medical Devices
US8226681B2
(en)
2007-06-25
2012-07-24
Abbott Laboratories
Methods, devices, and apparatus for managing access through tissue
WO2009011824A1
(en)
*
2007-07-13
2009-01-22
The Brigham And Women’s Hospital, Inc.
System and method for hernia mesh fixation
US20110196492A1
(en)
2007-09-07
2011-08-11
Intrinsic Therapeutics, Inc.
Bone anchoring systems
US8858576B2
(en)
2007-09-10
2014-10-14
Olympus Medical Systems Corp.
Tissue fastening tool, stent, applicator for placing the same, and tissue fastening method through natural orifice
US20090157101A1
(en)
2007-12-17
2009-06-18
Abbott Laboratories
Tissue closure system and methods of use
US8893947B2
(en)
2007-12-17
2014-11-25
Abbott Laboratories
Clip applier and methods of use
US7841502B2
(en)
2007-12-18
2010-11-30
Abbott Laboratories
Modular clip applier
US8808314B2
(en)
*
2008-02-18
2014-08-19
Covidien Lp
Device and method for deploying and attaching an implant to a biological tissue
US8758373B2
(en)
2008-02-18
2014-06-24
Covidien Lp
Means and method for reversibly connecting a patch to a patch deployment device
CA2715740C
(en)
2008-02-18
2014-05-27
Polytouch Medical Ltd.
A device and method for deploying and attaching a patch to a biological tissue
US9398944B2
(en)
2008-02-18
2016-07-26
Covidien Lp
Lock bar spring and clip for implant deployment device
US8317808B2
(en)
2008-02-18
2012-11-27
Covidien Lp
Device and method for rolling and inserting a prosthetic patch into a body cavity
US9301826B2
(en)
2008-02-18
2016-04-05
Covidien Lp
Lock bar spring and clip for implant deployment device
US9044235B2
(en)
2008-02-18
2015-06-02
Covidien Lp
Magnetic clip for implant deployment device
US9393002B2
(en)
2008-02-18
2016-07-19
Covidien Lp
Clip for implant deployment device
US9393093B2
(en)
2008-02-18
2016-07-19
Covidien Lp
Clip for implant deployment device
US9833240B2
(en)
2008-02-18
2017-12-05
Covidien Lp
Lock bar spring and clip for implant deployment device
US9034002B2
(en)
2008-02-18
2015-05-19
Covidien Lp
Lock bar spring and clip for implant deployment device
US9131939B1
(en)
2008-02-27
2015-09-15
Mitralign, Inc.
Device for percutaneously delivering a cardiac implant through the application of direct actuation forces external to the body
WO2009111481A1
(en)
2008-03-03
2009-09-11
Arthrosurface Incorporated
Bone resurfacing system and method
US8177836B2
(en)
2008-03-10
2012-05-15
Medtronic, Inc.
Apparatus and methods for minimally invasive valve repair
AU2009233764A1
(en)
*
2008-04-08
2009-10-15
Endopro Solutions L.L.C.
Apparatus and method for gastric reduction
FR2929835B1
(en)
*
2008-04-11
2010-06-11
Sofradim Production
SURGICAL ATTACHMENT FOR ATTACHING A HERNIA PROSTHESIS
US9282965B2
(en)
2008-05-16
2016-03-15
Abbott Laboratories
Apparatus and methods for engaging tissue
US9237860B2
(en)
2008-06-05
2016-01-19
Varian Medical Systems, Inc.
Motion compensation for medical imaging and associated systems and methods
WO2010011661A1
(en)
2008-07-21
2010-01-28
Atricure, Inc.
Apparatus and methods for occluding an anatomical structure
US8163022B2
(en)
2008-10-14
2012-04-24
Anulex Technologies, Inc.
Method and apparatus for the treatment of the intervertebral disc annulus
EP2792307B1
(en)
*
2008-10-20
2017-10-04
Covidien LP
A device for attaching a patch to a biological tissue
US9241696B2
(en)
2008-10-30
2016-01-26
Abbott Vascular Inc.
Closure device
US8858594B2
(en)
2008-12-22
2014-10-14
Abbott Laboratories
Curved closure device
US8323312B2
(en)
2008-12-22
2012-12-04
Abbott Laboratories
Closure device
US9173644B2
(en)
2009-01-09
2015-11-03
Abbott Vascular Inc.
Closure devices, systems, and methods
US20100179589A1
(en)
2009-01-09
2010-07-15
Abbott Vascular Inc.
Rapidly eroding anchor
US9089311B2
(en)
2009-01-09
2015-07-28
Abbott Vascular Inc.
Vessel closure devices and methods
US9414820B2
(en)
2009-01-09
2016-08-16
Abbott Vascular Inc.
Closure devices, systems, and methods
US9486191B2
(en)
2009-01-09
2016-11-08
Abbott Vascular, Inc.
Closure devices
KR101060722B1
(en)
*
2009-01-12
2011-08-31
이희영
Plastic injection needle with wrinkle removal surgeon
US9393023B2
(en)
2009-01-13
2016-07-19
Atricure, Inc.
Apparatus and methods for deploying a clip to occlude an anatomical structure
US20100185234A1
(en)
2009-01-16
2010-07-22
Abbott Vascular Inc.
Closure devices, systems, and methods
US9943704B1
(en)
2009-01-21
2018-04-17
Varian Medical Systems, Inc.
Method and system for fiducials contained in removable device for radiation therapy
US8518060B2
(en)
2009-04-09
2013-08-27
Medtronic, Inc.
Medical clip with radial tines, system and method of using same
WO2010116511A1
(en)
*
2009-04-09
2010-10-14
タキロン株式会社
Self-establishing implant material with reliable affixability
CA2759027C
(en)
2009-04-17
2020-02-25
Arthrosurface Incorporated
Glenoid resurfacing system and method
WO2016154393A1
(en)
2009-04-17
2016-09-29
Arthrosurface Incorporated
Glenoid repair system and methods of use thereof
US9662126B2
(en)
2009-04-17
2017-05-30
Arthrosurface Incorporated
Glenoid resurfacing system and method
US8668704B2
(en)
2009-04-24
2014-03-11
Medtronic, Inc.
Medical clip with tines, system and method of using same
US8500757B2
(en)
*
2009-07-28
2013-08-06
Edwards Lifesciences Corporation
Surgical puncture cinch and closure system
US8459524B2
(en)
2009-08-14
2013-06-11
Covidien Lp
Tissue fastening system for a medical device
CA2769666C
(en)
*
2009-08-17
2018-02-13
Arie Levy
Means and method for reversibly connecting an implant to a deployment device
EP2467093B1
(en)
*
2009-08-17
2019-08-28
Covidien LP
Articulating patch deployment device
US20110054492A1
(en)
2009-08-26
2011-03-03
Abbott Laboratories
Medical device for repairing a fistula
US8460319B2
(en)
2010-01-11
2013-06-11
Anulex Technologies, Inc.
Intervertebral disc annulus repair system and method
US8683895B2
(en)
*
2010-02-23
2014-04-01
Kensey Nash Corporation
Single revolution snap action drive for surgical fasteners
US8303624B2
(en)
2010-03-15
2012-11-06
Abbott Cardiovascular Systems, Inc.
Bioabsorbable plug
US9161778B2
(en)
2010-06-11
2015-10-20
Entourage Medical Technologies, Inc.
System and method for transapical access and closure
US9044267B2
(en)
2010-06-11
2015-06-02
Entourage Medical Technologies, Inc.
System and method for transapical access and closure
US8758399B2
(en)
2010-08-02
2014-06-24
Abbott Cardiovascular Systems, Inc.
Expandable bioabsorbable plug apparatus and method
US8603116B2
(en)
2010-08-04
2013-12-10
Abbott Cardiovascular Systems, Inc.
Closure device with long tines
US20120053598A1
(en)
*
2010-08-26
2012-03-01
Pavilion Medical Innovations
Helical Fasteners and Methods for Deploying Same
US8939936B2
(en)
2010-09-20
2015-01-27
Entorurage Medical Technologies, Inc.
System for providing surgical access
CN103347454B
(en)
2010-10-01
2016-10-12
瓦里安医疗系统公司
For delivering implant, such as through delivery catheter and the method for bronchoscope implantable marker thing in lung
US9017349B2
(en)
2010-10-27
2015-04-28
Atricure, Inc.
Appendage clamp deployment assist device
US9066741B2
(en)
2010-11-01
2015-06-30
Atricure, Inc.
Robotic toolkit
US8636754B2
(en)
2010-11-11
2014-01-28
Atricure, Inc.
Clip applicator
US9775602B2
(en)
2011-01-25
2017-10-03
Isuturing, Llc
Devices and methods for continuous surgical suturing
US8465504B2
(en)
2011-01-25
2013-06-18
Isuturing, Llc
Devices and methods for continuous surgical suturing
CA2824936A1
(en)
2011-01-28
2012-08-02
Apica Cardiovascular Limited
Systems for sealing a tissue wall puncture
CA2826413A1
(en)
2011-02-01
2012-08-09
Georgia Tech Research Corporation
Systems for implanting and using a conduit within a tissue wall
US8617184B2
(en)
2011-02-15
2013-12-31
Abbott Cardiovascular Systems, Inc.
Vessel closure system
US9149276B2
(en)
2011-03-21
2015-10-06
Abbott Cardiovascular Systems, Inc.
Clip and deployment apparatus for tissue closure
US9066716B2
(en)
2011-03-30
2015-06-30
Arthrosurface Incorporated
Suture coil and suture sheath for tissue repair
US8556932B2
(en)
2011-05-19
2013-10-15
Abbott Cardiovascular Systems, Inc.
Collapsible plug for tissue closure
RU2559922C1
(en)
2011-08-15
2015-08-20
Этрикьюэ Инк.
Surgical device
WO2013027107A1
(en)
*
2011-08-23
2013-02-28
Simcha Milo
Device for creating temporary access and then closure
US9332976B2
(en)
2011-11-30
2016-05-10
Abbott Cardiovascular Systems, Inc.
Tissue closure device
US8968336B2
(en)
2011-12-07
2015-03-03
Edwards Lifesciences Corporation
Self-cinching surgical clips and delivery system
EP2804565B1
(en)
2011-12-22
2018-03-07
Arthrosurface Incorporated
System for bone fixation
US9017347B2
(en)
2011-12-22
2015-04-28
Edwards Lifesciences Corporation
Suture clip deployment devices
US9107654B2
(en)
2012-01-05
2015-08-18
Cook Medical Technologies Llc
Attachment device for tissue approximation and retraction
US9282973B2
(en)
2012-01-20
2016-03-15
Atricure, Inc.
Clip deployment tool and associated methods
IN2014DN06720A
(en)
2012-03-01
2015-05-22
Synthes Gmbh
US9265514B2
(en)
2012-04-17
2016-02-23
Miteas Ltd.
Manipulator for grasping tissue
US9468448B2
(en)
2012-07-03
2016-10-18
Arthrosurface Incorporated
System and method for joint resurfacing and repair
US10016193B2
(en)
2013-11-18
2018-07-10
Edwards Lifesciences Ag
Multiple-firing crimp device and methods for using and manufacturing same
US9498202B2
(en)
2012-07-10
2016-11-22
Edwards Lifesciences Corporation
Suture securement devices
US10925606B2
(en)
2012-10-15
2021-02-23
Guy Friedman
Tendon repair apparatus
US9877713B2
(en)
*
2012-10-15
2018-01-30
Guy Friedman
Tendon repair apparatus
US9364209B2
(en)
2012-12-21
2016-06-14
Abbott Cardiovascular Systems, Inc.
Articulating suturing device
US9592047B2
(en)
2012-12-21
2017-03-14
Edwards Lifesciences Corporation
System for securing sutures
EP2948104B1
(en)
2013-01-25
2019-07-24
Apica Cardiovascular Limited
Systems for percutaneous access, stabilization and closure of organs
US9737294B2
(en)
2013-01-28
2017-08-22
Cartiva, Inc.
Method and system for orthopedic repair
US10179012B2
(en)
2013-01-28
2019-01-15
Cartiva, Inc.
Systems and methods for orthopedic repair
US9232943B2
(en)
2013-01-31
2016-01-12
Opus Ksd Inc.
Delivering bioabsorbable fasteners
US9610076B2
(en)
2013-02-15
2017-04-04
Cook Medical Technologies Llc
Wound closure device
US9055933B2
(en)
*
2013-03-12
2015-06-16
St. Jude Medical Puerto Rico Llc
Large bore closure secondary hemostasis bioadhesive delivery systems and methods
EP2968717A4
(en)
2013-03-15
2017-02-22
Apk Advanced Medical Technologies, Inc.
Devices, systems, and methods for implanting and using a connnector in a tissue wall
US9492200B2
(en)
2013-04-16
2016-11-15
Arthrosurface Incorporated
Suture system and method
WO2015006739A1
(en)
2013-07-11
2015-01-15
Edwards Lifesciences Corporation
Knotless suture fastener installation system
CN105960208A
(en)
*
2013-10-29
2016-09-21
随行医疗技术公司
System for providing surgical access
US11607319B2
(en)
2014-03-07
2023-03-21
Arthrosurface Incorporated
System and method for repairing articular surfaces
US9962265B2
(en)
2014-03-07
2018-05-08
Arthrosurface Incorporated
System and method for repairing articular surfaces
US10624748B2
(en)
2014-03-07
2020-04-21
Arthrosurface Incorporated
System and method for repairing articular surfaces
US9919165B2
(en)
2014-05-07
2018-03-20
Varian Medical Systems, Inc.
Systems and methods for fiducial to plan association
US10043284B2
(en)
2014-05-07
2018-08-07
Varian Medical Systems, Inc.
Systems and methods for real-time tumor tracking
CN107106157A
(en)
2014-05-30
2017-08-29
爱德华兹生命科学公司
System for fixing suture
WO2016070025A1
(en)
*
2014-10-31
2016-05-06
Thoratec Corporation
Apical connectors and instruments for use in a heart wall
CR20170265A
(en)
2014-12-10
2017-11-17
Edwards Lifesciences Ag
MULTIPLE REACTIVATION HOLDING DEVICE AND METHODS FOR USE AND MANUFACTURING
US10512460B2
(en)
2014-12-19
2019-12-24
Renzo Cecere
Surgical method and system for performing the same
CN107106162B
(en)
2014-12-24
2020-10-27
爱德华兹生命科学公司
Suture clip deployment device
US10470759B2
(en)
2015-03-16
2019-11-12
Edwards Lifesciences Corporation
Suture securement devices
US10092286B2
(en)
2015-05-27
2018-10-09
Covidien Lp
Suturing loading unit
US10028733B2
(en)
*
2015-05-28
2018-07-24
National University Of Ireland, Galway
Fistula treatment device
US11701096B2
(en)
*
2015-05-28
2023-07-18
National University Of Ireland, Galway
Fistula treatment device
WO2016189107A1
(en)
*
2015-05-28
2016-12-01
National University Of Ireland, Galway
A fistula treatment device
US10939905B2
(en)
2016-08-26
2021-03-09
Edwards Lifesciences Corporation
Suture clips, deployment devices therefor, and methods of use
US10863980B2
(en)
2016-12-28
2020-12-15
Edwards Lifesciences Corporation
Suture fastener having spaced-apart layers
EP3831308A1
(en)
*
2017-06-09
2021-06-09
Signum Surgical Limited
An implant for closing an opening in tissue
US11160663B2
(en)
2017-08-04
2021-11-02
Arthrosurface Incorporated
Multicomponent articular surface implant
US10675030B2
(en)
*
2017-08-04
2020-06-09
C.R. Bard, Inc.
Absorbable surgical coil fastener
WO2020154602A1
(en)
*
2019-01-25
2020-07-30
Boston Scientific Scimed, Inc.
Devices, systems, and methods for tightening, fastening, or anchoring in tissue
GB2609338B
(en)
2019-03-12
2023-06-14
Arthrosurface Inc
Humeral and glenoid articular surface implant systems and methods
GB2590138B
(en)
2019-09-30
2023-08-02
Gyrus Acmi Inc
Suturing apparatus and method
CN114159187B
(en)
*
2021-11-17
2022-08-09
江南大学
Diameter-winding sewing method and device
Family Cites Families (59)
* Cited by examiner, † Cited by third party
Publication number
Priority date
Publication date
Assignee
Title
US816026A
(en)
*
1905-03-09
1906-03-27
Albert J Meier
Surgical clip.
US1123290A
(en)
*
1914-05-12
1915-01-05
Otto Von Herff
Surgical clip.
US2817339A
(en)
*
1953-08-10
1957-12-24
Norman M Sullivan
Rigid fascial suture
US3091828A
(en)
*
1961-08-11
1963-06-04
Soltis Mary
Clamp
US3446212A
(en)
*
1965-07-19
1969-05-27
New Research & Dev Lab Inc
Hemostatic clip and applicator therefor
US3545444A
(en)
*
1967-10-02
1970-12-08
United States Surgical Corp
Wire suture wrapping instrument
US3604425A
(en)
*
1969-04-11
1971-09-14
New Research And Dev Lab Inc
Hemostatic clip
US3735762A
(en)
*
1970-04-27
1973-05-29
Us Corp Baltimo E
Instrument for ligating suturing and dividing organic tubular structures
US3716058A
(en)
*
1970-07-17
1973-02-13
Atlanta Res Inst
Barbed suture
US3870048A
(en)
*
1973-07-30
1975-03-11
In Bae Yoon
Device for sterilizing the human female or male by ligation
US3989049A
(en)
*
1973-07-30
1976-11-02
In Bae Yoon
Method of applying an elastic ring to an anatomical tubular structure
US3939828A
(en)
*
1974-09-09
1976-02-24
Mohr Robert N
Method and clasp for internal osseous fixation
CA1101289A
(en)
*
1976-09-07
1981-05-19
Vsesojuzny Nauchno-Issledovatelsky I Ispytatelny Institut Meditsinskoi T Ekhniki
Surgical apparatus for suturing soft tissues with lengths of suturing material with spicules
SU715082A1
(en)
*
1977-01-24
1980-02-15
Всесоюзный научно-исследовательский и испытательный институт медицинской техники
Surgical suturing apparatus
US4217902A
(en)
*
1977-05-02
1980-08-19
March Alfred L
Hemostatic clip
US4337774A
(en)
*
1978-06-14
1982-07-06
Metatech Corporation
Micro surgical clip
US4485816A
(en)
*
1981-06-25
1984-12-04
Alchemia
Shape-memory surgical staple apparatus and method for use in surgical suturing
DE3139488C2
(en)
*
1981-10-03
1984-08-16
Aesculap-Werke Ag Vormals Jetter & Scheerer, 7200 Tuttlingen
Aneurysm clip
US4979954A
(en)
*
1981-10-21
1990-12-25
Owen Gwathmey
Staple suturing method
US4548201A
(en)
*
1982-04-20
1985-10-22
Inbae Yoon
Elastic ligating ring clip
US4535772A
(en)
*
1983-03-10
1985-08-20
Kells Medical, Incorporated
Skin closure device
US4595007A
(en)
*
1983-03-14
1986-06-17
Ethicon, Inc.
Split ring type tissue fastener
US4637395A
(en)
*
1983-10-04
1987-01-20
Aesculap-Werke Ag
Applicator for C-shaped scalp clips
US4777950A
(en)
*
1986-04-11
1988-10-18
Kees Surgical Specialty Co.
Vascular clip
US4791707A
(en)
*
1986-08-26
1988-12-20
Tucker Wilson H
Clip applicator, spreadable clips and method for applying the clips
US4869268A
(en)
*
1987-05-14
1989-09-26
Inbae Yoon
Multi-functional instruments and stretchable ligating and occluding devices
JP2561853B2
(en)
*
1988-01-28
1996-12-11
株式会社ジェイ・エム・エス
Shaped memory molded article and method of using the same
US5374261A
(en)
*
1990-07-24
1994-12-20
Yoon; Inbae
Multifunctional devices for use in endoscopic surgical procedures and methods-therefor
US4990152A
(en)
*
1988-10-12
1991-02-05
Inbae Yoon
Applicator device housing multiple elastic ligatures in series and for dilating and applying elastic ligatures onto anatomical tissue
US4924866A
(en)
*
1988-10-26
1990-05-15
Inbae Yoon
Wound-closing device
US5047047A
(en)
*
1988-10-26
1991-09-10
Inbae Yoon
Wound closing device
GB2226245A
(en)
*
1988-11-18
1990-06-27
Alan Crockard
Endoscope, remote actuator and aneurysm clip applicator.
US4961743A
(en)
*
1989-01-03
1990-10-09
Codman & Shurtleff, Inc.
Torsion spring
US5053047A
(en)
*
1989-05-16
1991-10-01
Inbae Yoon
Suture devices particularly useful in endoscopic surgery and methods of suturing
US5222976A
(en)
*
1989-05-16
1993-06-29
Inbae Yoon
Suture devices particularly useful in endoscopic surgery
US5030224A
(en)
*
1989-09-25
1991-07-09
Pioneering Technologies, Inc.
Coronary artery retraction clip
US5026390A
(en)
*
1989-10-26
1991-06-25
Brown Alan W
Surgical staple
US5007921A
(en)
*
1989-10-26
1991-04-16
Brown Alan W
Surgical staple
US5026379A
(en)
*
1989-12-05
1991-06-25
Inbae Yoon
Multi-functional instruments and stretchable ligating and occluding devices
US5217473A
(en)
*
1989-12-05
1993-06-08
Inbae Yoon
Multi-functional instruments and stretchable ligating and occluding devices
US5226908A
(en)
*
1989-12-05
1993-07-13
Inbae Yoon
Multi-functional instruments and stretchable ligating and occluding devices
IT1238173B
(en)
*
1990-01-15
1993-07-09
FOUR-TWO-TWO-TWO-CONVERGENT METAL STITCH SUITABLE FOR CONTEMPORARY SUTURE OF THE SKIN AND SUB-SKIN FABRIC
US5035692A
(en)
*
1990-02-13
1991-07-30
Nicholas Herbert
Hemostasis clip applicator
US5207692A
(en)
*
1990-07-30
1993-05-04
Codman & Shurtleff, Inc.
Surgical clip applier with reciprocating clip sleeve and dual ratchet mechanism
US5171252A
(en)
*
1991-02-05
1992-12-15
Friedland Thomas W
Surgical fastening clip formed of a shape memory alloy, a method of making such a clip and a method of using such a clip
US5395034A
(en)
1991-11-07
1995-03-07
American Cyanamid Co.
Linear surgical stapling instrument
US5242456A
(en)
*
1991-11-21
1993-09-07
Kensey Nash Corporation
Apparatus and methods for clamping tissue and reflecting the same
DE4217202C2
(en)
*
1992-05-23
1994-06-23
Kernforschungsz Karlsruhe
Surgical sewing instrument
US5342373A
(en)
*
1992-09-14
1994-08-30
Ethicon, Inc.
Sterile clips and instrument for their placement
US5309927A
(en)
*
1992-10-22
1994-05-10
Ethicon, Inc.
Circular stapler tissue retention spring method
US5382259A
(en)
*
1992-10-26
1995-01-17
Target Therapeutics, Inc.
Vasoocclusion coil with attached tubular woven or braided fibrous covering
AU7568994A
(en)
*
1993-08-25
1995-03-21
Apollo Camera, L.L.C.
Surgical ligation clip
US5467991A
(en)
1993-11-08
1995-11-21
White, Iv; Walter
Detachable golf swing training device using two light beams
US5476505A
(en)
*
1993-11-18
1995-12-19
Advanced Cardiovascular Systems, Inc.
Coiled stent and delivery system
US5465894A
(en)
1993-12-06
1995-11-14
Ethicon, Inc.
Surgical stapling instrument with articulated stapling head assembly on rotatable and flexible support shaft
US5486187A
(en)
*
1994-01-04
1996-01-23
Schenck; Robert R.
Anastomosis device and method
US5465895A
(en)
1994-02-03
1995-11-14
Ethicon Endo-Surgery, Inc.
Surgical stapler instrument
US5582616A
(en)
*
1994-08-05
1996-12-10
Origin Medsystems, Inc.
Surgical helical fastener with applicator
US5480089A
(en)
1994-08-19
1996-01-02
United States Surgical Corporation
Surgical stapler apparatus with improved staple pockets
1996
1996-03-05
US
US08/610,951
patent/US5810851A/en
not_active
Expired – Fee Related
1997
1997-03-05
WO
PCT/US1997/002978
patent/WO1997032526A1/en
not_active
Application Discontinuation
1997-03-05
AU
AU21375/97A
patent/AU719161B2/en
not_active
Ceased
1997-03-05
EP
EP97906771A
patent/EP0955897A1/en
not_active
Withdrawn
1997-03-05
CA
CA002248122A
patent/CA2248122A1/en
not_active
Abandoned
Also Published As
Publication number
Publication date
US5810851A
(en)
1998-09-22
EP0955897A4
(en)
1999-11-17
WO1997032526A1
(en)
1997-09-12
CA2248122A1
(en)
1997-09-12
EP0955897A1
(en)
1999-11-17
AU719161B2
(en)
2000-05-04
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2002-10-10
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