This invention relates to the treatment of degenerative disc disease in general, and more particularly to methods and apparatus for closing fissures in the annulus of an intervertebral disc. This invention also relates to methods and apparatus for effecting other anatomical repairs and/or fixations.
The human spine is a column of articulating vertebrae separated by intervertebral discs. It provides support for the torso, and houses and protects the spinal cord in its spinal canal.
The human intervertebral disc is an oval-shaped to kidney-shaped structure of variable size depending on its location in the spine. The outer portion of the disc is known as the annulus fibrosus (or anulus fibrosus, annulus fibrosis, anulus fibrosis) or simply “the annulus”. The inner portion of the disc is known as the nucleus pulposis or simply “the nucleus”.
The annulus is made up of ten to twenty collagen fiber lamellae. The collagen fibers within a given lamella extend parallel to one another. Successive lamellae have their collagen fibers oriented in alternating directions. About 48 percent of the lamellae are incomplete, but this percentage varies with location and it increases with age. On average, the collagen fibers of a given lamella lie at an angle of about sixty degrees to the vertebral axis line, but this too varies with location. The orientations of the lamellae serve to control vertebral motion (i.e., one half of the lamellae tighten to check motion when the vertebra above or below the disc are turned in either direction).
The annulus contains the nucleus. The nucleus has a consistency generally similar to that of crabmeat. The nucleus serves to transmit and dampen axial loads. A high water content (approximately 70-80 percent) assists the nucleus in this function. The water content has a diurnal variation. The nucleus absorbs water while a person lies recumbent. Activity generates increased axial loads which squeeze water from the disc. The nucleus comprises roughly 50 percent of the entire disc. The nucleus contains cells (chondrocytes and fibrocytes) and proteoglycans (chondroitin sulfate and keratin sulfate). The cell density in the nucleus is on the order of 4,000 cells per microliter.
The intervertebral disc changes, or “degenerates”, with age. As a person ages, the water content of the disc falls from approximately 85 percent at birth to approximately 70 percent in the elderly. The ratio of chondroitin sulfate to keratin sulfate decreases with age, while the ratio of chondroitin 6 sulfate to chondroitin 4 sulfate increases with age. The distinction between the annulus and the nucleus decreases with age. Generally, disc degeneration is painless.
Premature or accelerated disc degeneration is known as degenerative disc disease. A large portion of patients suffering from chronic lower back pain are thought to have this condition. As the disc degenerates, the nucleus and annulus functions are compromised. The nucleus becomes thinner and less able to handle compressive loads. The annulus fibers become redundant as the nucleus shrinks. The redundant annular fibers are less effective in controlling vertebral motion. This disc pathology can result in (i) tears of the annulus (both “full-thickness” tears and “partial-thickness” tears) as abnormal loads are transmitted to the annulus and the annulus is subjected to excessive motion between vertebrae, and (ii) disc herniation (i.e., extrusion of the nucleus) through complete (i.e., full-thickness) annular tears. Degenerative disc disease is frequently the cause of substantial pain for a patient.
Current surgical treatments for disc degeneration are generally “destructive”, in the sense that they generally involve the removal or destruction of disc tissue.
One group of procedures, which includes microlumbar discectomy, removes the nucleus or a portion of the nucleus.
A second group of procedures destroys nuclear material. This group includes Chymopapin (an enzyme) injection, laser discectomy, and thermal therapy (i.e., heat treatment to denature proteins in the nucleus).
The foregoing two groups of procedures compromise the nucleus of the treated disc, and may exacerbate fissures in the annulus while accessing the nucleus.
A third group of procedures, which includes spinal fusion procedures, either removes the disc or effectively eliminates the disc's function by connecting together two or more vertebrae, e.g., by “fusing” the vertebrae together with bone. However, such spinal fusion procedures transmit additional stress to the adjacent discs, which typically results in premature degeneration of the adjacent discs over time.
In general, the “destructive” nature of current surgical treatments for disc degeneration can provide substantial pain relief for the patient, but it can also lead to further disc degeneration over time, which can result in new pain for the patient. By way of example but not limitation, procedures to remove the nucleus or a portion of the nucleus, and procedures to destroy nuclear material, compromise nucleus function and may exacerbate fissures in the annulus while accessing the nucleus, thereby leading to further disc degeneration. By way of further example but not limitation, spinal fusion procedures can induce premature disc degeneration in adjacent intervertebral discs.
Ideally, disc herniation (i.e., the extrusion of nucleus through full-thickness annular tears) should be treated by closing the fissures in the annulus. However, in practice, this is difficult to achieve.
By way of example but not limitation, it is difficult to close fissures in the annulus by conventional suturing. For one thing, the annulus is tough and thick and does not lend itself to manual suturing, particularly given the limited access corridors often imposed on the surgeon. For another thing, the loads imposed on the nucleus are large, so that inadequate closure of the fissures can lead to subsequent recurrence of the fissures. Furthermore, the area surrounding the intervertebral disc is crowded with delicate structures (e.g., nerves), so that the use of knots to secure suture can be problematic.
By way of further example but not limitation, it is difficult to close fissures in the annulus using conventional toggle anchors. More particularly, in U.S. Pat. No. 7,004,970, issued Feb. 28, 2006 to Cauthen III et al., there is disclosed a system for closing fissures in the annulus, wherein the system comprises first and second conventional toggle anchors connected together by filament, and wherein the filament comprises a cinch knot and a cinch line. See, for example,
In Cauthen III et al., there is also disclosed a knotless system for tensioning the filament between the two conventional toggle anchors, wherein enlargements are formed on the filament and are pulled through a narrow opening formed on one of the conventional toggle anchors so as to provide a knotless ratchet securement. However, this knotless ratchet securement is limited to preset tension levels (i.e., it is not continuously adjustable) and has limited holding power, among other things.
Thus there is a need for a new and improved method and apparatus for closing fissures in the annulus of an intervertebral disc, whereby to treat degenerative disc disease.
In addition to the foregoing, in many other situations it may be necessary and/or desirable to effect anatomical repairs and/or fixations.
By way of example but not limitation, two pieces of soft tissue may need to be held in apposition to one another to effect a repair (e.g., so as to close an incision in the skin), or two pieces of cartilage may need to be held in apposition to one another to effect a repair (e.g., so as to close a tear in meniscal cartilage), or two pieces of bone may need to be held in apposition to one another so as to effect a repair (e.g., so as to fuse together bone).
By way of further example but not limitation, a piece of soft tissue may need to be held in apposition to bone to effect a repair (e.g., so as to attach soft tissue to bone), or a piece of cartilage may need to be held in apposition to bone to effect a repair (e.g., so as to attach labrum to bone or to attach meniscal cartilage to bone).
By way of further example but not limitation, a prosthesis may need to be held in apposition to soft tissue or bone, or soft tissue or bone may need to be held in apposition to a prosthesis, and/or any first object may need to be held in apposition to any second object.
In these and other situations, it would also be advantageous to provide a new and improved method and apparatus for effecting anatomical repairs and/or fixations.
The present invention provides a new and improved method and apparatus for closing fissures in the annulus of an intervertebral disc, whereby to treat degenerative disc disease.
The present invention also provides a new and improved method and apparatus for effecting other anatomical repairs and/or fixations.
More particularly, among other things, the present invention facilitates the reconstruction of the annulus by providing a novel method and apparatus for closing fissures in the annulus of an intervertebral disc. Among other things, such reconstruction prevents recurrent herniation following a microlumbar discectomy. The invention may also be used in the treatment of herniated discs, annular tears of the disc, and/or other disc degeneration, while enabling surgeons to preserve (or even augment or replace) the contained nucleus. The method and apparatus of the present invention may be used to treat discs throughout the spine, including the cervical, thoracic, and lumbar spines of humans and animals.
Preferred embodiments of the present invention include a flexible longitudinal fixation component (e.g., a filament) extending across a soft tissue defect, such as a fissure in the annulus. A pair of transverse anchor components (e.g., bar anchors), selectively connected to the flexible longitudinal fixation component, are preferably placed behind an inner layer of the annulus on opposite sides of the fissure, so as to anchor the flexible longitudinal fixation component to the annulus, with the flexible longitudinal fixation component extending axially through the annulus and laterally across the fissure so as to hold the fissure closed, whereby to prevent nucleus material from passing out the fissure and pressing on the adjacent nerves, including the spinal cord. Significantly, with the present invention, the transverse anchor components can be passed through the annulus and into the nucleus of the intervertebral disc using a direct “needle plunge” action, which facilitates passage through the tough, thick annulus, and which is highly compatible with the limited access corridors often imposed on the surgeon. Furthermore, the present invention allows the tension of the flexible longitudinal fixation component to be adjusted as necessary so as to effect proper fissure closure, and then set in place without requiring the use of knots.
And the flexible longitudinal fixation component (e.g., the filament) may be anchored to one of the upper and lower vertebral bodies adjacent to the intervertebral disc being treated.
In one preferred form of the present invention, two novel transverse anchor components (e.g., bar anchors) are provided. One novel anchor component (sometimes hereinafter referred to as the distal anchor) is provided with an associated inserter and the two, in conjunction with the flexible longitudinal fixation component (e.g., filament) provide enhanced toggling of the anchor component within dense structures such as a vertebral body and/or an intervertebral disc. The second novel anchor component (sometimes hereinafter referred to as the proximal anchor) is provided with novel means for knotlessly securing the flexible longitudinal fixation component to that anchor component, whereby to allow the tension of the flexible longitudinal fixation component to be reliably set between the two anchor components without requiring the use of knots.
The present invention may also be used to effect other anatomical repairs and/or fixations.
By way of example but not limitation, the present invention may be used to hold two pieces of soft tissue in apposition to one another to effect a repair (e.g., so as to close an incision in the skin), or the present invention may be used to hold two pieces of cartilage in apposition to one another to effect a repair (e.g., so as to close a tear in meniscal cartilage), or the present invention may be used to hold two pieces of bone in apposition to one another so as to effect a repair (e.g., so as to fuse together bone).
By way of further example but not limitation, the present invention may be used to hold a piece of soft tissue in apposition to bone to effect a repair (e.g., so as to attach soft tissue to bone), or the present invention may be used to hold a piece of cartilage in apposition to bone to effect a repair (e.g., so as to attach labrum to bone or to attach meniscal cartilage to bone).
By way of further example but not limitation, the present invention may be used to hold a prosthesis in apposition to soft tissue or bone, or to hold soft tissue or bone in apposition to a prosthesis, and/or to hold any first object in apposition to any second object.
In one preferred form of the present invention, there is provided apparatus for attaching a first object to a second object, said apparatus comprising:
a distal anchor comprising a generally cylindrical body, a distal end and a proximal end, wherein said distal end comprises an inclined distal end surface, and a vertical bore extending through said generally cylindrical body, perpendicular to the longitudinal axis of said generally cylindrical body;
a proximal anchor comprising a generally cylindrical body, a distal end and a proximal end, a top surface and a bottom surface, a first vertical bore extending through said generally cylindrical body from said top surface to said bottom surface, perpendicular to the longitudinal axis of the generally cylindrical body, a second vertical bore spaced distally from said first vertical bore and extending from said top surface to said bottom surface parallel to said first vertical bore, a third vertical bore spaced distally from said second vertical bore and extending from said top surface to said bottom surface parallel to said first vertical bore, and a fourth vertical bore spaced distally from said third vertical bore and extending from said top surface to said bottom surface parallel to said first vertical bore; and
a suture having a proximal end and a distal end, with an enlargement formed at said distal end, wherein said suture extends through said vertical bore of said distal anchor, through said fourth vertical bore of said proximal anchor, through said third vertical bore of said proximal anchor, through said second vertical bore of said proximal anchor and through said first vertical bore of said proximal anchor.
In another preferred form of the present invention, there is provided a method for connecting a first object to a second object, said method comprising:
providing apparatus comprising:
advancing said distal anchor into the first object, with said suture and said enlargement advancing with said distal anchor;
while holding said suture and said enlargement in place, further advancing said distal anchor so that said inclined distal end surface of said distal anchor engages said enlargement and causes said distal anchor to turn relative to the first object;
advancing said proximal anchor into the second object;
pulling proximally on the portion of said suture extending between said second vertical bore of said proximal anchor and said third vertical bore of said proximal anchor so as to cause said proximal anchor to turn relative to the second object;
passing said proximal end of said suture between (i) the portion of said suture extending between said second vertical bore of said proximal anchor and said third vertical bore of said proximal anchor and (ii) said proximal anchor, so as to form a half hitch in said suture; and
pulling proximally on said proximal end of said suture so as to set said half hitch.
In another preferred form of the present invention, there is provided apparatus for attaching a suture to an object, said apparatus comprising:
an anchor comprising a generally cylindrical body, a distal end and a proximal end, wherein said distal end comprises an inclined distal end surface, and a vertical bore extending through said generally cylindrical body, perpendicular to the longitudinal axis of said generally cylindrical body; and
a suture having a proximal end and a distal end, with an enlargement formed at said distal end, wherein said suture extends through said vertical bore of said anchor.
In another preferred form of the present invention, there is provided a method for attaching a suture to an object, said method comprising:
providing apparatus comprising:
advancing said anchor into said object, with said suture and said enlargement advancing with said anchor;
while holding said suture and said enlargement in place, further advancing said anchor so that said inclined distal end surface of said anchor engages said enlargement and causes said anchor to turn relative to said object.
In another preferred form of the present invention, there is provided apparatus for attaching a suture to an object, said apparatus comprising:
an anchor comprising a generally cylindrical body, a distal end and a proximal end, a vertical bore extending through said generally cylindrical body, perpendicular to the longitudinal axis of said generally cylindrical body, a recess formed on one side of said generally cylindrical body and a U-shaped slot formed on the opposing side of said generally cylindrical body whereby to form a flexible finger extending distally within said generally cylindrical body, and further wherein said distal end of said finger is spaced from an opposing portion of said generally cylindrical body; and
a suture extending through said vertical bore, said recess and said U-shaped slot.
In another preferred form of the present invention, there is provided a method for attaching a suture to an object, said method comprising
providing apparatus comprising:
advancing said anchor into the object; and
pulling on said proximal end of said suture.
In another preferred form of the present invention, there is provided apparatus for attaching a suture to an object, said apparatus comprising:
an anchor comprising a body having a distal end and a proximal end, and a vertical bore extending through said body substantially perpendicular to the longitudinal axis of said body;
wherein said anchor further comprises a recess formed on one side of said body and a U-shaped slot formed on the opposing side of said body, whereby to form a flexible finger extending distally within said body, and further wherein said distal end of said finger is spaced from an opposing portion of said body; and
wherein at least one of said flexible finger and said body comprises a cutout extending therethrough, with said cutout cooperating with said U-shaped slot and said recess so as to together form a suture loading hole extending through said body, with said suture loading hole being sized to receive a suture therein.
In another preferred form of the present invention, there is provided a method for attaching a suture to an object, said method comprising
providing apparatus comprising:
passing said suture through said vertical bore of said anchor, forming a loop, passing said suture back through said vertical bore of said anchor, and passing said suture through said suture loading hole.
In another preferred form of the present invention, there is provided a method for anchoring a sensory nerve stimulator (SNS) lead to the anatomy of a patient, the method comprising:
providing an anchor assembly comprising:
forming an opening through the dermis and the superficial fascia;
positioning the body of the anchor anterior to the thorocolumbar fascia;
positioning the SNS lead through the loop in the anchor assembly;
positioning the SNS lead on the fat layer disposed anterior to the superficial fascia; and
pulling a portion of the suture so as to cause the body of the anchor to engage the anterior surface of the thorocolumbar fascia and to cause the SNS lead to move anteriorly through the fat layer and toward the thorocolumbar fascia until the SNS lead reaches a desired depth in the fat layer.
In another preferred form of the present invention, there is provided apparatus for attaching a first object to a second object, said apparatus comprising:
a distal anchor comprising a generally cylindrical body, a distal end and a proximal end, wherein said distal end comprises an inclined distal end surface, and a vertical bore extending through said generally cylindrical body, perpendicular to the longitudinal axis of said generally cylindrical body;
a distal suture having a proximal end and a distal end, with an enlargement formed at said distal end and an eyelet formed at said proximal end, wherein said suture extends through said vertical bore of said distal anchor;
a proximal anchor comprising a generally cylindrical body, a distal end and a proximal end, a vertical bore extending through said generally cylindrical body, perpendicular to the longitudinal axis of said generally cylindrical body, a recess formed on one side of said generally cylindrical body and a U-shaped slot formed on the opposing side of said generally cylindrical body, whereby to form a flexible finger extending distally within said generally cylindrical body, and further wherein said distal end of said finger is spaced from an opposing portion of said generally cylindrical body; and
a proximal suture having a proximal end and a distal end, with an enlargement formed at said distal end, wherein said proximal suture extends through said vertical bore of said proximal anchor, through said eyelet of said distal suture, back through said vertical bore of said proximal anchor, through said recess of said proximal bore and through said U-shaped slot of said proximal anchor, with a loop of proximal suture extending through said eyelet of said distal suture.
In another preferred form of the present invention, there is provided a method for connecting a first object to a second object, said method comprising:
providing apparatus comprising:
advancing said distal anchor into the first object, with said distal suture, said enlargement of said distal suture and said loop of proximal suture advancing with said distal anchor;
while holding said distal suture and said enlargement in place, further advancing said distal anchor so that said inclined distal end surface of said distal anchor engages said enlargement and causes said distal anchor to turn relative to the first object;
advancing said proximal anchor into the second object;
pulling proximally on the said loop of proximal suture so as to cause said proximal anchor to turn relative to the second object; and
pulling proximally on said proximal end of said proximal suture so as reduce the amount of suture extending between the first object and the second object.
In another preferred form of the present invention, there is provided apparatus for attaching a suture to an object, said apparatus comprising:
an anchor comprising a generally cylindrical body, a distal end and a proximal end, wherein said distal end comprises an inclined distal end surface, and a vertical bore extending through said generally cylindrical body, perpendicular to the longitudinal axis of said generally cylindrical body; and
a suture having a proximal end and a distal end, with an enlargement formed at said distal end and an eyelet formed at said proximal end, wherein said suture extends through said vertical bore of said anchor.
In another preferred form of the present invention, there is provided a method for attaching a suture to an object, said method comprising:
providing apparatus comprising:
advancing said anchor into said object, with said suture, said enlargement and said eyelet advancing with said anchor;
while holding said suture, said enlargement and said eyelet in place, further advancing said anchor so that said inclined distal end surface of said anchor engages said enlargement and causes said anchor to turn relative to said object.
In another preferred form of the present invention, there is provided apparatus for inserting a distal anchor into the first object and a proximal anchor into the second object, wherein a length of suture connects the distal anchor to the proximal anchor, the apparatus comprising:
handle;
a tube mounted to said handle and extending distally therefrom, said tube being sized to receive the distal anchor and the proximal anchor;
a push rod slidably disposed within said tube; and
a suture sled movably mounted to said handle, said suture sled comprising a cylindrical body having a hollow lumen for receiving the proximal anchor and a suture cleat mounted to the cylindrical body for releasably securing the suture to said suture sled, wherein the suture sled is configured to be moved between a first position in which the suture sled is vertically offset from the tube, and a second position in which the suture sled is aligned with the tube.
In another preferred form of the present invention, there is provided a method for connecting a first object to a second object, said method comprising:
providing apparatus for inserting a distal anchor into the first object and a proximal anchor into the second object, wherein a length of suture connects the distal anchor to the proximal anchor, the apparatus comprising:
positioning said distal anchor in the tube and positioning the proximal anchor in the suture sled, with the suture sled disposed in its first position;
advancing said distal anchor into the first object;
moving said suture sled from its first position to its second position; and
advancing said proximal anchor into the second object.
These and other objects and features of the present invention will be more fully disclosed or rendered obvious by the following detailed description of the preferred embodiments of the invention, which is to be considered together with the accompanying drawings wherein like numbers refer to like parts, and further wherein:
The present invention comprises the provision and use of a novel system for closing a fissure in the annulus of an intervertebral disc, whereby to treat degenerative disc disease.
The present invention also provides a new and improved method and apparatus for effecting other anatomical repairs and/or fixations.
More particularly, and looking first at
Looking now at
As seen in
As seen in
As seen in
As seen in
Shaft 195 generally comprises a hollow tube having a distal end 210, a proximal end 215 and a lumen 220 extending therebetween. Distal end 210 of shaft 195 terminates in a sharp point 225. A slot 227 is formed in distal end 210 of shaft 195 and may terminate in a shoulder 228. Alternatively, and more preferably, slot 227 extends proximally along shaft 195 so that it is coextensive with a slot 229 formed in inserter 15 (
Handle 200 comprises a distal end 235, a proximal end 240, and a bore 245 extending therebetween. A first counterbore 250 is formed at the distal end of handle 200, and a second counterbore 255 is formed just proximal to first counterbore 250, with first counterbore 250 being sized to receive shaft 195 and second counterbore 255 being sized to receive mount 230, whereby to secure shaft 195 to handle 200. A third counterbore 260 is formed at the proximal end of handle 200. A groove 265 is formed on the top side of handle 200 for receiving proximal anchor 25 (
Pushrod 205 comprises a pusher 295 which is sized to be slidably received within bore 245 of handle 200 and lumen 220 of shaft 195. Pusher 295 comprises a distal end 300 (
Prior to use, anchor assembly 10 is mounted to inserter 15. More particularly, distal anchor 20 is loaded into distal end 210 of shaft 195 so that suture 30 extends out slot 227 of shaft 195 (
Preferably suture assembly 10 is mounted to inserter 15 at the time of manufacture and prior to packaging and sterilization, although suture assembly 10 may also be mounted to inserter 15 at the time of use if desired.
In use, in order to close a fissure in the annulus of an intervertebral disc, distal anchor 20 is intended to be positioned on one side of a fissure, proximal anchor 25 is intended to be positioned on another side of the fissure, and suture 30 is thereafter tensioned so as to close the fissure, whereby to treat degenerative disc disease.
By way of example but not limitation, and looking now at
By way of further example but not limitation, and looking now at
For purposes of illustrating the present invention, an annulus reconstruction will now be discussed in the context of positioning distal anchor 20 in a vertebral body and proximal anchor 25 in the intervertebral disc.
More particularly, and looking now at
In this respect it should be appreciated that the provision of the novel apparatus of the present invention (i.e., distal anchor 20, suture 30 and inserter 15) provides a significant advantage over conventional toggle anchors of the prior art, since the present invention permits the toggle-type distal anchor 20 to be reliably toggled and set in dense tissue such as an intervertebral body and/or an intervertebral disc. As noted above, conventional toggle-type anchors have had limited success when set within the interior of tissue in general, and particularly when set within the interior of dense tissue such as an intervertebral body and/or an intervertebral disc, since they provide inconsistent toggling and low pull-out strengths. By contrast, with the present invention, the unique camming engagement of inclined distal surface 60 of distal anchor 20 with the restrained ball 85 causes distal anchor 20 to turn even when it is within the interior of dense tissue such as an intervertebral body and/or an intervertebral disc. Furthermore, the pointed heel 87 of distal anchor 20 facilitates setting of the anchor when suture 30 is tensioned.
Thereafter, loop 320 of suture 30 is released from suture cleats 290, pushrod 205 is removed from shaft 195 and handle 200, and inserter 15 is withdrawn from the bone (if it has not already been withdrawn from the bone). As this occurs, proximal anchor 25 is drawn distally through passageway 270 and into bore 245 in handle 200 (due to the fact that proximal anchor 25 encounters some impedance to sliding along suture 30 since suture 30 follows a serpentine path through proximal anchor 25, and due to the fact that inserter 15 is being withdrawn proximally).
Then removable stop 315 is replaced on thumb button 310, and pushrod 205 is advanced into bore 245 of handle 200 and into lumen 220 of shaft 195. This action advances proximal anchor 25 along lumen 220 of shaft 195. Pushrod 205 is advanced until removable stop 315 engages the proximal end of handle 200. At this point, proximal anchor 25 is disposed in the distal end of shaft 195, but is prevented from being ejected out of the distal end of shaft 195 due to the engagement of removable stop 315 with the proximal end of handle 200.
Next, shaft 195 of inserter 15 is inserted through the annulus on the far side of the fissure, so that suture 30 spans the fissure. See
The proximal end 190 of suture 30 may then be trimmed away, whereby to complete the repair.
In this respect it should be appreciated that the unique construction of proximal anchor 25 provides a significant advantage over the conventional toggle anchors of the prior art, since it provides novel means for knotlessly securing suture 30 to proximal anchor 25, whereby to allow the tension of suture 30 to be reliably set between distal anchor 20 and proximal anchor 25. Significantly, the novel construction provided by proximal anchor 25 provides a unique solution to the problem of knotlessly securing suture to an anchor. More particularly, the knotless securement mechanism of proximal anchor 25 avoids the deficiencies of prior art toggle anchor systems using cinch knots (see Cauthen III et al. as discussed above) and/or filament enlargements/anchor narrowings (see Cauthen III et al. as discussed above).
In addition, the knotless securement mechanism of proximal anchor 25 provides a significant improvement over the prior art serpentine suture securement mechanisms sometimes found in prior art bone anchors. More particularly, various prior art bone anchors (e.g., screw-type bone anchors) have previously attempted to use serpentine passageways through the bone anchor to knotlessly secure a suture to the bone anchor. However, such prior art serpentine suture securement mechanisms have traditionally required the designer to choose between low holding strength (but relative ease in pulling the suture through the serpentine passageways) or high holding strength (and significant difficulty in pulling the suture through the serpentine passageways). The present invention avoids this problem, providing both high holding strength and relative ease of pulling the suture through the serpentine passageways, by (i) allowing the suture to be accessed at a midpoint within the anchor's serpentine pathway (e.g., by pulling on loop 320), and (ii) providing additional holding means to supplement the holding power of the serpentine suture pathway (i.e., the aforementioned half-hitch and, to a significantly lesser extent, the friction fit of suture 30 within narrower inner portion 175 of bottom horizontal slot 165 and narrower inner portion 160 of bottom horizontal slot 150 (to the extent that bottom horizontal slot 165 comprises a narrower inner portion 175 and bottom horizontal slot 150 comprises a narrower inner portion 160).
Thus, with the present invention, the distal anchor 20 is set into tissue on one side of the fissure, the proximal anchor is deployed into tissue on the other side of the fissure, and then the suture is appropriately tensioned and made fast to the proximal anchor, whereby to effect the repair with the degree of tension selected by the user. Furthermore, with the present invention, the distal anchor can be reliably turned and set within the interior of relatively dense tissue such as bone (as well as within the interior of other tissue) due to its unique construction and deployment mechanism. And with the present invention, the proximal anchor is capable of providing high holding strengths, e.g., on the order of 16 pounds of holding strength. In this respect it should be appreciated that proximal anchor 25 is held to suture 30 to a large extent by the impedance provided by the half-hitch construct (which is aided against slipping by virtue of its disposition in top horizontal slot 145), and to a lesser extent by the serpentine suture path through proximal anchor 25, and to a much smaller extent by the light hold imposed on suture 30 by narrower inner portion 175 of bottom horizontal slot 165 and narrower inner portion 155 of bottom horizontal slot 150 (to the extent that bottom horizontal slot 165 comprises a narrower inner portion 175 and bottom horizontal slot 150 comprises a narrower inner portion 160).
Note that where bottom horizontal slot 165 comprises a narrower inner portion 175, the hold imposed on suture 30 by narrower inner portion 175 of bottom horizontal slot 165 may be relatively nominal, inasmuch as it provides a useful impedance on suture 30 only during the brief period of time that loop 320 is being reduced and the aforementioned half-hitch is being formed—after loop 320 has been reduced and the aforementioned half-hitch has been set, the significant holding power on suture 30 is provided by the half-hitch construct and the serpentine suture path extending through proximal anchor 25. In this respect it should also be appreciated that, where bottom horizontal slot 165 comprises a narrower inner portion 175, and during the brief period of time that narrower inner portion 175 is providing a useful impedance on suture 30, the patient is lying stationary on the operating table and only a nominal load is imposed on the suture—unlike when the patient is upright and moving about, when a substantial load is imposed on the suture.
By way of example but not limitation, in one form of the present invention, where bottom horizontal slot 165 comprises a narrower inner portion 175 and bottom horizontal slot 150 comprises a narrower inner portion 160, the serpentine suture path through proximal anchor 25, plus the light impedance imposed on suture 30 by narrower inner portion 175 of bottom horizontal slot 165 and narrower inner portion 155 of bottom horizontal slot 150, collectively provide about 4-6 pounds of holding strength, and the half-hitch construct of proximal end 190 of suture 30 passing through loop 320, with the half-hitch construct being drawn into top horizontal slot 145 of proximal anchor 25, brings the total holding strength to about 16 pounds of holding strength.
It will be appreciated that, due to the tortuous path of suture 30 through proximal anchor 25, as well as the need to pull the half-hitch construct into top horizontal slot 145 and, where bottom horizontal slot 165 comprises a narrower inner portion 175 and bottom horizontal slot 150 comprises a narrower inner portion 160, to pull suture 30 into the narrower inner portion 175 of bottom horizontal slot 165 and narrower inner portion 160 of bottom horizontal slot 150, substantial force must be applied to the proximal end of suture 30 in order to pull the length of suture between the anchors 20, 25 taut and secure the suture in position. This level of force is significantly greater than the level of force required to set distal anchor 20. Where the annulus of the vertebral disc is weak, the application of such a force to the proximal end of suture 30 presents the possibility of pulling proximal anchor 25 through the annulus. Therefore, in order to eliminate the possibility of this occurrence, it may be desirable to utilize a tensioner 375 (
More particularly, a suture retriever 380, having a loop 385 at its distal end, is advanced through a lumen 390 of tensioner 375 (
Alternatively, and looking now at
In use, when suture 30 is to be tensioned, the proximal end 190 of suture 30 is fed through ramped suture pathway 425, foot 420 is placed against the annulus adjacent to where suture 30 exits the annulus, and then suture 30 is tensioned, with foot 420 of the tensioner preventing the annulus from bowing outward. Thereafter, excess suture may be cut away by moving cutter tube 435 distally along shaft 405 until its sharpened distal rim 440 engages and trims away excess suture.
In the foregoing description, system 5 is discussed in the context of closing a fissure in the annulus of an intervertebral disc. However, it should be appreciated that system 5 may also be used to effect other anatomical repairs and/or fixations.
By way of example but not limitation, the present invention may be used to hold two pieces of soft tissue in apposition to one another to effect a repair (e.g., so as to close an incision in the skin). See, for example,
By way of further example but not limitation, the present invention may be used to hold a piece of soft tissue in apposition to bone to effect a repair (e.g., so as to attach soft tissue to bone). See, for example,
By way of further example but not limitation, the present invention may be used to hold a prosthesis in apposition to soft tissue or bone, or to hold soft tissue or bone in apposition to a prosthesis, and/or to hold any first object in apposition to any second object.
It is also possible to use just distal anchor 20 and suture 30 to effect anatomical repairs and/or fixations, with proximal anchor 25 being omitted altogether. See, for example,
It is also possible to use proximal anchor 25 and suture 30 with an anchor other than distal anchor 20 to effect anatomical repairs and/or fixations. By way of example but not limitation, proximal anchor 25 and suture 30 may be used in conjunction with a conventional bone anchor (e.g., a conventional screw-type bone anchor or by a conventional barb-type bone anchor), with the conventional bone anchor replacing the aforementioned distal anchor 20 of the present invention.
The following is a list of just some of the indications in which the present invention may be used:
As noted above, novel system 5 may be used to close a fissure in the annulus of an intervertebral disc, and/or to effect other anatomical repairs and/or other anatomical fixations.
In one preferred form of the invention, novel system 5 may be used in a novel approach to anchor sensory nerve stimulator (SNS) leads. More particularly, in sensory nerve stimulation therapy, electrical leads are positioned adjacent to nerves and used to deliver electrical stimulation to those nerves so as to provide pain relief to a patient. In one significant application of nerve stimulation therapy, sensory nerve stimulator (SNS) leads are disposed adjacent to nerves in the spinal column, whereby to deliver electrical stimulation to those nerves and provide pain relief to the patient. See, for example,
In practice, it has been found extremely difficult to reliably anchor an SNS lead adjacent to a nerve in the spinal column. This is due to, among other things, the highly complex and varying anatomy of the spinal column, the need to fabricate the SNS lead with an atraumatic configuration, and the need to ensure that the SNS lead is reliably fixed in position. These factors, and others, combine to make it extremely difficult to reliably anchor an SNS lead adjacent to a specific nerve in the spinal column.
Novel system 5 provides a new and improved approach for stabilizing an SNS lead adjacent to a nerve in the spinal column, by anchoring the SNS lead to one mass of material using the distal anchor of system 5 and by anchoring the SNS lead to another mass of material using the proximal anchor of system 5, with the intervening suture securing the SNS lead reliably in position. Among other things, novel system 5 comprises a distal anchor 20 which is deployable, using a minimally-invasive approach, against the exterior of a hard or soft object (e.g., a bone, soft tissue, a hard prosthesis, a soft prosthesis, etc.), or within the interior of a hard or soft object (e.g., a bone, soft tissue, a hard prosthesis, a soft prosthesis, etc.), thereby providing a wide range of objects to which the distal anchor may be secured. Novel system 5 also comprises a proximal anchor 25 which is deployable, using a minimally-invasive approach, against the exterior of a hard or soft object (e.g., a bone, soft tissue, a hard prosthesis, a soft prosthesis, etc.), or within the interior of a soft object (e.g., soft tissue, a soft prosthesis, etc.), thereby providing a wide range of objects to which the distal anchor may be secured. And novel system 5 comprises a connecting suture 30 which may be used to atraumatically, but reliably, secure an SNS lead in position.
Note that for the purposes of the present invention, the term “bone” is intended to include any bone or bone-like structure including, but not limited to, a vertebral body, a pedicle, a transverse process, a facet structure, a lamina, a spinous process, etc. Note also that for the purposes of the present invention, the term “soft tissue” is intended to include any relatively “soft” structure including, but not limited to, an intervertebral disc, a muscle, a ligament, a tendon, etc. See, for example,
Thus, with the present invention, distal anchor 20 may be deployed through, or deployed within, any appropriate anatomical or prosthetic structure, and proximal anchor 25 may be deployed through, or deployed within, any appropriate anatomical or prosthetic structure, whereby to enable suture 30 to secure SNS lead L in the desired position within the patient's anatomy.
As seen in
As noted above, novel system 5 may be used to close a fissure in the annulus of an intervertebral disc, and/or to effect other anatomical repairs and/or other anatomical fixations, including anchoring sensory nerve stimulator (SNS) leads.
In another preferred form of the present invention, novel system 5 utilizes the aforementioned distal anchor 20 and the aforementioned suture 30 (and also the aforementioned inserter 15), but substitutes an alternative proximal anchor 25A (
More particularly, in this form of the invention, proximal anchor 25A comprises a generally cylindrical body 90A having a distal end 95A, a proximal end 100A and a generally circular side wall 105A. Distal end 95A terminates in a distal surface 110A. Proximal end 100A terminates in a proximal surface 120A. A vertical bore 126A passes completely through proximal anchor 25A. Vertical bore 126A is sized to slidably receive suture 30 therein. A recess 131A passes part way through proximal anchor 25A. A U-shaped slot 136A passes part way through proximal anchor 25A. Recess 131A and U-shaped slot 136A together define a flexible finger 141A. In this form of the invention, a gap 142A is formed between the inner tip 143A of flexible finger 141A and the edge 144A formed at the convergence of recess 131A and U-shaped slot 136A. Preferably gap 142A is sized so as to be approximately 50% of the width of suture 30 when flexible finger 141A is in its relaxed, unbiased condition (i.e., in the position shown in
As seen in
In addition to the foregoing, it should be appreciated that suture 30 follows a non-linear path through proximal anchor 25A, and this non-linear path creates impedance to the passage of suture 30 through proximal anchor 25A.
In use, after the aforementioned distal anchor 20 has been deployed at the surgical site (preferably using the aforementioned inserter 15), proximal anchor 25A is also deployed at the surgical site (again, preferably using the aforementioned inserter 15), and then suture 30 is set by pulling proximally on suture 30. As suture 30 is pulled proximally, flexible finger 141A flexes away from the body of proximal anchor 25A, thereby allowing suture 30 to slide through recess 131A and U-shaped slot 136A (as well as through vertical bore 126A and wider outer portion 156A of bottom horizontal slot 151A). When the slack in suture 30 has been taken up, and suture 30 is thereafter tensioned further, where bottom horizontal slot 151A comprises a narrower portion 161A, suture 30 is pulled from wider outer portion 156A of bottom horizontal slot 151A into narrower portion 161A of bottom horizontal slot 151A so that suture 30 is snugly received therein, such that proximal anchor 25A provides a light hold on suture 30. When tension on the free end of suture 30 is thereafter relaxed, flexible finger 141A flexes back toward the body of proximal anchor 25A, whereby to lock suture 30 to proximal anchor 25A (i.e., with inner tip 143A of flexible finger 141A capturing the suture against edge 144A of proximal anchor 25A). In addition, inasmuch as suture 30 follows a non-linear path through proximal anchor 25A, the non-linear path creates impedance to the passage of suture 30 through proximal anchor 25A. In this way, suture 30 is secured to proximal anchor 25A. Thereafter, a half-hitch may be formed in suture 30 on the proximal side of proximal anchor 25A so as to further secure suture 30 to proximal anchor 25A.
In another preferred form of the present invention, and looking now at
More particularly, anchor 515 comprises a generally cylindrical body 535 having a distal end 540, a proximal end 545 and a generally circular side wall 550. Distal end 540 terminates in a flat or somewhat inclined distal end surface 555 and a more inclined distal end surface 560. Flat or somewhat inclined distal end surface 555 is sufficiently large so as to render distal end 540 of anchor 515 substantially blunt (but, where distal end surface 555 is somewhat inclined, also having a tapered lead-in). Inclined distal end surface 560 is pitched at an appropriate angle (e.g., 30 degrees, 45 degrees, etc.) so as to cause anchor 515 to turn during deployment (in the same manner that the aforementioned distal anchor 20 comprises a corresponding inclined distal surface 60 for causing turning), as will hereinafter be discussed. Proximal end 545 terminates in an inclined proximal end surface 565.
A vertical bore 570 passes through anchor 515. Vertical bore 570 is sized to slidably receive suture 520 therein. A horizontal slot 575 extends between inclined distal end surface 560 and vertical bore 570. Horizontal slot 575 is preferably also sized to slidably receive suture 520 therein, and helps keep anchor 515 and suture 520 from binding when they are disposed within the aforementioned inserter 15. A pair of vertical bores 581, 583 are also disposed in anchor 515, proximal to vertical bore 570. Vertical bores 581, 583 are also sized to slidably receive suture 520 therein. A bottom horizontal slot 586 extends between vertical bore 581 and vertical bore 583.
Significantly, suture 520 follows a non-linear path through anchor 515, and this non-linear path creates impedance to the passage of suture 520 through anchor 515.
If desired, bottom horizontal slot 586 may be stepped, comprising a wider outer portion 587 and a narrower inner portion 588. Wider outer portion 587 may be sized to slidably receive suture 520 therein so as to help keep anchor 515 and suture 520 from binding when they are disposed within the aforementioned inserter 15, but narrower portion 588 may be sized to snugly receive suture 520 therein, whereby to provide a light hold on suture 520 when suture 520 is disposed therein.
As seen in
In use, anchor 515 is deployed at the surgical site with suture 520 under tension so that anchor 515 is turned as it is ejected from the aforementioned inserter 15 (in the same manner that the aforementioned distal anchor 20 is turned as it is ejected from the aforementioned inserter 15), then suture 520 is tensioned by pulling proximally on proximal end 593 of suture 520. As suture 520 is tensioned, sensory nerve stimulator “SNS” lead 505 is secured against fascia 510 (i.e., by virtue of anchor 515 being set in fascia 510 and by virtue of lead 505 being captured to anchor 515 via suture 520). Note that suture 520 will be held against slippage relative to anchor 515 by virtue of the fact that suture 520 follows a non-linear path through anchor 515, and this non-linear path creates impedance to the passage of suture 520 through anchor 515. When suture 520 is thereafter tensioned further, and where bottom horizontal slot 586 comprises a narrower portion 588, suture 520 will be pulled from wider outer portion 587 of bottom horizontal slot 586 into narrower portion 588 of bottom horizontal slot 586 so that suture 520 is snugly received therein. This can provide an additional hold on suture 520. Thereafter, a half-hitch 594 is formed in suture 520 on the proximal side of anchor 520 so as to secure the fixation. In this form of the invention, half hitch 594 will provide the primary fixation of suture 520 to anchor 515, and the impedance created by the non-linear path of suture 520 through anchor 515 will provide significant additional fixation of suture 520. Where bottom horizontal slot 586 comprises a narrower portion 588, movement of suture 520 into narrower portion 588 can also provide a small additional holding force.
In another preferred form of the present invention, and looking now at
More particularly, anchor 615 comprises a generally cylindrical body 625 having a distal end 630, a proximal end 635 and a generally circular side wall 640. Distal end 630 terminates in a flat or somewhat inclined distal end surface 645 and a more inclined distal end surface 650. Flat or somewhat inclined distal end surface 645 is sufficiently large so as to render distal end 630 of anchor 615 substantially blunt (but, where distal end surface 645 is somewhat inclined, also having a tapered lead-in). Inclined distal end surface 650 is pitched at an appropriate angle (e.g., 30 degrees, 45 degrees, etc.) so as to cause anchor 615 to turn during deployment (in the same manner that the aforementioned distal anchor 20 comprises a corresponding inclined distal surface 60 for causing turning), as will hereinafter be discussed. Proximal end 635 terminates in an inclined proximal end surface 655.
A vertical bore 660 passes completely through anchor 615. Vertical bore 660 preferably intersects inclined distal end surface 650 and is sized to slidably receive suture 620 therein. A recess 665 passes part way through anchor 615. A U-shaped slot 670 passes part way through anchor 615. Recess 665 and U-shaped slot 670 together define a flexible finger 675. In this form of the invention, a gap 680 is formed between the inner tip 685 of flexible finger 675 and the edge 690 formed at the convergence of recess 665 and U-shaped slot 670. Preferably gap 680 is sized so as to be approximately 50% of the width of suture 620 when flexible finger 675 is in its relaxed, unbiased condition (i.e., in the position shown in
As seen in
In addition to the foregoing, it should be appreciated that suture 620 follows a non-linear path through anchor 615, and this non-linear path creates impedance to the passage of suture 620 through anchor 615.
In use, anchor 615 is deployed at the surgical site with suture 620 under tension so that anchor 615 is turned as it is ejected from the aforementioned inserter 15 (in the same manner that the aforementioned distal anchor 20 is turned as it is ejected from the aforementioned inserter 15). In one preferred form of the invention, this is accomplished by releasably mounting loop 725 of suture 620 to suture sled 280 of inserter 15 during insertion of anchor 615. Then loop 725 of suture 620 is released from suture sled 280, SNS lead 605 is passed through loop 725, and then suture 620 is tensioned by pulling proximally on proximal end 720 of suture 620. As suture 620 is tensioned, flexible finger 675 flexes away from the body of anchor 615, thereby allowing suture 620 to slide through recess 680 and U-shaped slot 670 (as well as through vertical bore 660 and wider outer portion 700 of bottom horizontal slot 695). When the slack in suture 620 has been taken up, whereby to pull SNS lead 605 tight against fascia 610, and suture 620 is thereafter tensioned further, where bottom horizontal slot 695 comprises a narrower portion 705, suture 620 is pulled from wider outer portion 700 of bottom horizontal slot 695 into narrower portion 705 of bottom horizontal slot 695 so that suture 620 is snugly received therein, such that anchor 615 provides a light hold on suture 620. When tension on the free end of suture 620 is thereafter relaxed, flexible finger 675 flexes back toward the body of anchor 615, whereby to lock suture 620 to anchor 615 (i.e., with inner tip 685 of flexible finger 675 capturing the suture against edge 690 of anchor 615). In addition, inasmuch as suture 620 follows a non-linear path through anchor 615, the non-linear path creates impedance to the passage of suture 620 through anchor 615. In this way, suture 620 is secured to anchor 615. Thereafter, if desired, a half-hitch may be formed in suture 620 on the proximal side of anchor 615 so as to further secure suture 620 to anchor 615, and hence secure SNS lead 605 to fascia 610.
In one preferred form of the invention, single anchor system 600 is configured so that its failure mode comprises slipping, not breaking (i.e., suture 620 will slip relative to anchor 615 before anchor 615 will break).
And in one preferred form of the invention, anchor 615 comprises carbon fiber-reinforced PEEK (30%).
Furthermore, if desired, anchor 615 may comprise a radiopaque material so that anchor 615 is visible under X-ray visualization. By way of example but not limitation, a radiopaque element may be incorporated in the body of anchor 615. By way of further example but not limitation, a piece of Nitinol wire may be molded into anchor 615 so that the Nitinol wire extends through flexible finger 675 and into the adjoining body of anchor 615—in this form of the invention, the Nitinol wire reinforces flexible finger 675 at the same time that it provides a radiopaque element in anchor 615.
It is sometimes desirable to anchor sensory nerve stimulator (SNS) leads to anatomy adjacent to nerves in the spinal column.
More particularly, and looking now at
Current, “prior art” approaches, such as the “dual anchor” fixation system sold under the name “Fixate™ Tissue Band” by Boston Scientific of Marlborough, Mass., USA, anchor a sensory nerve stimulator (SNS) lead against the posteriorly-facing surface of the thorocolumbar fascia using two anchors that are disposed on either side of the sensory nerve stimulator (SNS) lead, with suture extending between the two anchors and over the lead so as to “tie down” the lead to the thorocolumbar fascia. More particularly, such “dual anchor” fixation is typically effected by deploying a first anchor on one side of the sensory nerve stimulator (SNS) lead, and then deploying a second anchor on the other side of the sensory nerve stimulator (SNS) lead, such that a connecting suture extends between the first anchor and the second anchor and passes over the sensory nerve stimulator (SNS) lead, whereby to anchor the sensory nerve stimulator (SNS) lead in place relative to the adjacent anatomy (e.g., so as to anchor the sensory nerve stimulator (SNS) lead to the posteriorly-facing surface of the thorocolumbar fascia). See, for example,
However, in practice, it has been found that such a “dual anchor” fixation system/procedure requires significant trauma to the surrounding anatomy in order to allow the surgeon to visualize the surgical site, properly position the sensory nerve stimulator (SNS) lead, properly deploy the anchors, and then “tie down” the sensory nerve stimulator (SNS) lead. More particularly, in the case where “dual anchor” fixation is used to anchor a sensory nerve stimulator (SNS) lead to the posteriorly-facing surface of the thorocolumbar fascia, the surgeon needs to dissect the tissue down to the thorocolumbar fascia so as to ensure proper placement of the sensory nerve stimulator (SNS) lead relative to the anatomy and so as to ensure proper placement of the two anchors relative to the sensory nerve stimulator (SNS) lead and the anatomy to which the sensory nerve stimulator (SNS) lead is to be anchored (i.e., the thorocolumbar fascia). Visualization of the surgical site (i.e., the thorocolumbar fascia) generally requires retraction of the dermis, superficial fascia and fat layers during the surgical procedure, which retraction causes significant trauma to the adjacent anatomy and necessitates a large incision (in both length and width, and in depth).
By way of example but not limitation, and looking now at
Thus there is a need for a new and improved approach for anchoring a sensory nerve stimulator (SNS) lead to tissue (e.g., the thorocolumbar fascia) that minimizes the size of the incision and the resulting trauma to the patient.
To that end, there is now provided a novel approach for anchoring a sensory nerve stimulator (SNS) lead to the thorocolumbar fascia that minimizes the size of the incision and the resulting trauma to the patient. This novel approach uses the aforementioned single anchor fixation system 600 for anchoring a sensory nerve stimulator (SNS) lead to the thorocolumbar fascia.
More particularly, as discussed above, single anchor fixation system 600 generally comprises the aforementioned anchor 615 for implantation in tissue (i.e., in this form of the invention, beneath the thorocolumbar fascia, as will hereinafter be discussed) and the aforementioned suture 620 for looping around a sensory nerve stimulator (SNS) lead 905 (i.e, in the same manner as discussed above and shown in
As discussed above, and looking back at
It will be appreciated that inasmuch as suture 620 has a diameter greater than the size of gap 680, flexible finger 675 will normally bear against suture 620 disposed in gap 680. As a result, the presence of the “oversized” suture 620 in the “undersized” gap 680 will cause flexible finger 675 to be flexed upwardly slightly (i.e., away from recess 665) so as to accommodate suture 620, with inner tip 685 of flexible finger 675 capturing the suture against edge 690 of anchor 615. It will also be appreciated that, as a result of this construction, when proximal segment 720 of suture 620 is pulled proximally, flexible finger 675 deflects upwardly (i.e., away from recess 665) slightly so as to permit suture 620 to move within gap 680 of anchor 615. When proximally-directed tension on suture 620 is thereafter released, flexible finger 675 returns to its undeflected position (i.e., due to the inherent resiliency at flexible finger 675) and binds suture 620 in gap 680. As a result, flexible finger 675 of anchor 615 facilitates one-way movement of suture 620 relative to anchor 615. Importantly, as this one-way movement of suture 620 occurs, intermediate loop 725 is reduced, whereby to bring loop 725 (and sensory nerve stimulator (SNS) lead 905 disposed in loop 725) closer to anchor 615 (and, in this form of the invention, closer to the thermocolumbar fascia, as will hereinafter be discussed in further detail).
As previously discussed, and as will hereinafter be further discussed, anchor 615 and suture 620 are pre-assembled to one another so as to form an anchor assembly, and this anchor assembly is pre-loaded into inserter 15 so that anchor 615 is disposed in lumen 220 of shaft 195 of inserter 15, and intermediate loop 725 extends out through slot 227 of inserter 15 and is releasably secured to suture sled 280 of inserter. More particularly, intermediate loop 725 is releasably secured to suture sled 280 of inserter 15 before anchor 615 is deployed and while anchor 615 is being deployed; and after anchor 615 has been deployed, intermediate loop 725 is released from suture sled 280, sensory nerve stimulator (SNS) lead 905 is passed through intermediate loop 725, and then proximal segment 720 of suture 620 is pulled so as to reduce intermediate loop 725 and secure sensory nerve stimulator (SNS) lead 905 to tissue.
In the novel procedure for anchoring a sensory nerve stimulator (SNS) lead using single anchor system 600 of
Using inserter 15, anchor 615, which is pre-loaded in inserter 15 and has its intermediate loop 725 releasably attached to suture sled 280, is then passed through the fat layer anterior to the superficial fascia and then through the thorocolumbar fascia (e.g., using the aforementioned inserter 15). Anchor 615 is then ejected from inserter 15, with anchor 615 turning as it is ejected from inserter 15 by virtue of the fact that intermediate loop 725 is still attached to suture sled 280 and inclined distal end surface 650 of the ejected anchor 615 is driven against large ball or knot 715 disposed at the distal end of suture 620, thereby inducing anchor 615 to turn. At this point anchor 615 engages the anteriorly-facing surface of the thorocolumbar fascia, with proximal segment 720 and loop 725 of suture 620 extending through the thorocolumbar fascia, the fat layer, the superficial fascia and the dermis. Then intermediate loop 725 is released from suture sled 280. See
Sensory nerve stimulator (SNS) lead 905 (or, where used, lead anchor 910) is then passed through intermediate loop 725 of suture 620. The sensory nerve stimulator (SNS) lead 905 passed through intermediate loop 725 of single anchor system 600 is then set in the opening formed in the superficial fascia, resting on the posterior surface of the fat layer disposed anterior to the superficial fascia. See
The surgeon then pulls proximal segment 720 of suture 620 proximally. Anchor 615 bears against the anterior surface of the thorocolumbar fascia, and one-way movement of suture 620 causes intermediate loop 725 of suture 620 to reduce, pulling sensory nerve stimulator (SNS) lead 905 anteriorly into the fat layer and toward the thorocolumbar fascia. See
When the sensory nerve stimulator (SNS) lead 905 is at the desired depth within the fat layer (which desired depth may be intermediate the fat layer, such as is shown in
It will be appreciated that the novel foregoing approach facilitates a minimally-invasive anchoring of a sensory nerve stimulator (SNS) lead to the anatomy. Specifically, inasmuch as the surgeon does not need to visualize the thorocolumbar fascia in order to deploy anchor 615 and anchor a sensory nerve stimulator (SNS) lead, the foregoing approach of the present invention significantly reduces the size of the incision required and hence significantly reduces the trauma to the surrounding tissue. By way of example but not limitation, where a traditional “dual anchor” fixation system is used, the incision required is typically a “wedge-shaped” incision that is typically approximately 7 cm long by approximately 4 cm wide (after retraction by spreaders) by approximately 2.5-7.5 cm deep, disrupting approximately 35-105 cubic cm of the patient's tissue (i.e., (7 cm×4 cm×2.5 cm)/2=35 cubic cm, and (7 cm×4 cm×7.5 cm)/2=105 cubic cm). By contrast, the novel minimally-invasive single anchor fixation system of the present invention typically requires a “wedge-shaped” incision that is approximately 2.5 cm long by approximately 2 cm wide (after retraction by spreaders) by approximately 1.5 cm deep, disrupting only approximately 3.75 cubic cm of the patient's tissue (i.e., (2.5 cm×2 cm×1.5 cm)/2=3.75 cubic cm). Stated another way, the novel single anchor fixation system of the present invention requires only 0.107-0.036 of the volume of tissue (i.e., 3.75 cubic cm/35 cubic cm=0.107, and 3.75 cubic cm/105 cubic cm=0.036) to be disrupted as is typically disrupted by a traditional “dual anchor” fixation system. In other words, the novel single anchor fixation system of the present invention requires only 3.6%-10.7% of the volume of tissue to be disrupted as is typically disrupted by a traditional “dual anchor” fixation system.
In the foregoing disclosure, inserter 15 is characterized as having a suture sled 280 which is spring mounted to handle 200. Suture sled 280 serves as a movable mount for securing the proximal portion of suture loop 320 (or suture loop 725) to handle 200, such that suture sled 280 can slide along handle 200 as distal anchor 20 (or anchor 615) is advanced into a mass of material (e.g., an intervertebral disc, a bone, soft tissue, etc.), and then be stopped relative to handle 200 so that distal anchor 20 (or anchor 615) is driven against ball 185 (or ball 715), whereby to facilitate turning of distal anchor 20 (or anchor 615) within the mass of material.
To this end, in the foregoing disclosure, suture sled 280 is characterized as being spring mounted to handle 200 so that suture sled 280 initially remains in a proximal position, whereby to hold suture 30 (or suture 620) under tension, until distal anchor 20 (or anchor 615) is driven distally by push rod 205 of inserter 15, whereupon suture sled 280 is permitted to move distally, against the power of spring 285, until distal anchor 20 (or anchor 615) is at the proper depth within the mass of material, whereupon distal movement of suture sled 280 is stopped, thereby stopping distal movement of ball 185 (or ball 715) and hence setting the depth of distal anchor 20 (or anchor 615).
However, if desired, spring 285 may be omitted, and other means may be provided for releasably holding suture sled 280 in a proximal position until distal anchor 20 (or anchor 615) is driven distally by push rod 205. By way of example but not limitation, suture sled 280 may be releasably held in a proximal position by means of a yielding stop finger, a ball-and-detent mechanism, or other releasable holding mechanism of the sort well known in the art.
In the foregoing disclosure, inserter 15 is characterized as having a push rod 205 which is moved distally by manually pressing on thumb button 310 (e.g., in the manner of manually pressing on the plunger of a syringe), whereby to drive distal anchor 20 (or anchor 615) distally.
However, in some circumstances it can be desirable to drive distal anchor 20 (or anchor 615) with an impulse mechanism, so that an impulse of drive energy is applied to distal anchor 20 (or anchor 615). By way of example but not limitation, where distal anchor 20 (or anchor 615) is formed out of a material having limited strength (e.g., PEEK or PLLA), and where distal anchor 20 (or anchor 615) is to be set in a harder mass of material (e.g., bone), it can be helpful to set distal anchor 20 (or anchor 615) with an impulse mechanism.
To this end, and looking now at
As discussed above, the free end of suture 620 is passed through suture anchor 615 (i.e., up through vertical bore 660, back down through vertical bore 660, across bottom horizontal slot 695, up recess 665 and out U-shaped slot 670) along a tortuous path. See
However, it has been found that it is often challenging to thread a suture through a narrow opening (e.g., through recess 665 and through U-shaped slot 670) without employing a suture threader (not shown). A suture threader is well known in the field of sutures and medical devices utilizing sutures, and generally comprises a substantially resilient device (e.g., a flexible wire) which can be passed through the narrow opening and then used to draw the suture back through the opening (e.g., by passing the suture through an opening in the suture threader, and then pulling the suture threader, including the suture, back through the narrow opening).
Thus it would be desirable to provide a suture anchor which facilitates loading a suture into the suture anchor, and which avoids the need for using a separate suture threader, and which facilitates quick and easy loading of a suture through the tortuous path of the suture anchor.
To this end, and looking now at
Anchor 615A preferably comprises a generally cylindrical body 625A having a distal end 630A, a proximal end 635A and a generally circular side wall 640A. Distal end 630A terminates in a flat or somewhat inclined distal end surface 645A and a more inclined distal end surface 650A. Flat or somewhat inclined distal end surface 645A is sufficiently large so as to render distal end 630A of anchor 615A substantially blunt (but, where distal end surface 645A is somewhat inclined, flat or somewhat inclined distal end surface 645A is sufficient to provide anchor 615A with a tapered lead-in). Inclined distal end surface 650A is pitched at an appropriate angle (e.g., 30 degrees, 45 degrees, etc.) so as to cause anchor 615A to turn during deployment (i.e., in the same manner that the aforementioned distal anchor 20 comprises a corresponding inclined distal surface 60 for causing turning), as will hereinafter be discussed. Proximal end 635A preferably terminates in an inclined proximal end surface 655A.
A vertical bore 660A passes completely through anchor 615A. Vertical bore 660A preferably extends substantially perpendicular to the longitudinal axis of anchor 615A. Vertical bore 660A preferably intersects inclined distal end surface 650A and is sized to slidably receive suture 620A therein. A recess 665A is formed on one side of generally cylindrical body 625A and passes part way through anchor 615A. Recess 665A preferably extends substantially perpendicular to the longitudinal axis of anchor 615A. A U-shaped slot 670A is formed on the opposite side of generally cylindrical body 625A (i.e., opposite to recess 665A) and passes part way through anchor 615A. U-shaped slot 670A preferably extends substantially perpendicular to the longitudinal axis of anchor 615A. Recess 665A and U-shaped slot 670A together define a flexible finger 675A which preferably extends distally within generally cylindrical body 625A. In this form of the invention, a gap 680A is formed between the inner tip 685A of flexible finger 675A and the edge 690A formed at the convergence of recess 665A and U-shaped slot 670A. Preferably gap 680A is sized so as to be approximately 50% of the width of suture 620A when flexible finger 675A is in its relaxed, unbiased condition (i.e., in the position shown in
A suture loading hole 730A is formed near the proximal end of U-shaped slot 670A in the proximal portion of flexible finger 675A. More particularly, a portion of flexible finger 675A is cut away (e.g., so as to form a hemicylindrical cutout) near the proximal end of flexible finger 675A to form suture loading hole 730A which passes through U-shaped slot 670A and into recess 665A. Suture loading hole 730A is configured to be wider than gap 680A (i.e., wider than the gap between inner tip 685A of flexible finger 675A and edge 690A formed at the convergence of recess 665A and U-shaped slot 670A) so as to facilitate passage of the free end of suture 620A therethrough.
Note that, if desired, suture loading hole 730A may be formed in generally cylindrical body 625A rather than in flexible finger 675A (i.e., a hemicylindrical cutout may be formed in generally cylindrical body 625A rather than in flexible finger 675A); or suture loading hole 730A may be formed in both flexible finger 675A and in generally cylindrical body 625A rather than in just flexible finger 675A or in just generally cylindrical body 625A (i.e., hemicylindrical cutouts may be formed in both flexible finger 675A and in generally cylindrical body 625A rather than in just flexible finger 675A or in just generally cylindrical body 625A).
Suture 620A is generally the same as the aforementioned suture 620, however, suture 620A preferably comprises a stiffened free end for facilitating threading of the free end through vertical bore 660A and through suture loading hole 730A, as will hereinafter be discussed in further detail. More particularly, as seen in
After suture 620A has been threaded through suture loading hole 730A, the suture is pulled distally so as to lodge suture 620A in gap 680A between inner tip 685A of flexible finger 675A and edge 690A formed at the convergence of recess 665A and U-shaped slot 670A. Note that inasmuch as suture 620A has a diameter which is approximately twice the size of gap 680A formed between inner tip 685A of flexible finger 675A and edge 690A of anchor 615A, flexible finger 675A will normally bear against the suture disposed in gap 680A. In this condition, the presence of the “oversized” suture 620A in the “undersized” gap 680A will cause flexible finger 675A to be flexed upwardly (from the angle of view of
In addition to the foregoing, it should be appreciated that suture 620A follows a non-linear path through anchor 615A, and this non-linear path creates impedance to the passage of suture 620A through anchor 615A.
It should be appreciated that while suture 620A is preferably formed with a stiffened free end in order to facilitate passage of the free end of the suture through vertical bore 660A and/or through suture loading hole 730A, the stiffened free end may be omitted, and/or, if desired, a suture threader may be passed through suture loading hole 730A, used to grasp suture 620A, and then used to pull suture 620A through suture loading hole 730A.
It will be appreciated that novel anchor 615A and suture 620A together form a single anchor system 600A, and single anchor system 600A may be used (e.g., with the aforementioned inserter 15) to secure an object (e.g., a sensory nerve stimulator SNS lead 605) to tissue (e.g., fascia 610) in substantially the same manner that single anchor system 600 (and the aforementioned inserter 15) may be used.
As discussed above, it is generally desirable to provide inserter 15 with a stop (e.g., removable stop 315,
To this end, and looking now at
In this form of the invention, handle 200 preferably has a non-circular cross-section, comprising a recessed flat 752.
When it is desired to actuate thumb button 310, thumb button 310 is pulled proximally to release seat 742 from engagement with tab 750 (i.e., by moving seat 742 proximally such that seat 742 no longer contacts tab 750), and thumb button 310 is rotated 180 degrees (i.e., along an arc 755) so that member 740 is arcuately aligned with recessed flat 752 of handle 200. See
In another form of the invention, and looking now at
When it is desired to actuate thumb button 310, tab 765 is swung radially away from the shaft of thumb button 310, cutout 770 disengages from the shaft of thumb button 310 and the body of tab 765 is no longer interposed between proximal end 240 of handle 200 and the head of thumb button 310, whereby to allow thumb button 310 to be actuated as desired. If it is thereafter desired to lock thumb button 310 against actuation, tab 765 can be swung inwardly such that cutout 770 re-engages the shaft of thumb button 310 and is re-interposed between thumb button 310 and proximal end 240 of handle 200.
As noted above, novel system 5 may be used to close a tear in the annulus of an intervertebral disc, and/or to effect other anatomical repairs and/or other anatomical fixations, and/or to anchor sensory nerve stimulator (SNS) leads, etc.
In another preferred form of the present invention, novel system 5 utilizes an alternative anchor assembly 905 (see
In this preferred form of the invention, and looking now at
More particularly, in this form of the invention, distal anchor 915 is preferably substantially the same as the distal anchor 20 described above and shown in
And, in this form of the invention, and still looking now at
Cinching toggling filament 930 is passed through proximal anchor 925 so that large ball or knot 940 is disposed against the more inclined distal end surface 650A, and into vertical bore 660A, loops around to form loop 945 (which is passed through eyelet 935 of toggling filament 920 of distal anchor 915) and extends back down vertical bore 660A, through wider outer portion 700A (see
In use, and looking now at
Preferably, novel inserter 910 (see
And with the inserter 15 previously disclosed, the suture sled terminates the suture construct and limits the deployment depth of the distal anchor so as to force the distal anchor to toggle in hard tissues (e.g., bone). The second, proximal anchor is in the molded handle pathway distal to the sled.
As will be hereinafter discussed, and looking now at
More particularly, and looking now at
For purposes of illustrating the construction, operation and use of inserter 910, an annulus repair will now be discussed, in combination with
The steps for using inserter 910 are very much similar to the steps for using the previous inserter 15 of
More particularly, as discussed above, a bore is formed (e.g., by drilling, tapping, punching, etc.) in a vertebral body, and the distal end of shaft 195 is inserted into the bore created in the vertebral body to an appropriate depth. Then, thumb button 310 is pulled proximally to release seat 742 (
Thereafter, pushrod 205 is removed from shaft 195 and handle 200, either completely or enough so the distal tip of pushrod 205 is disposed proximal to snap collar 970 (see
Pushrod 205 is now re-inserted into handle 200, thumb button 310 is rotated to arcuately align distally-extending member 740 with recessed flat 752 of handle 200, and thumb button 310 is advanced distally towards handle 200, thereby causing the advancing pushrod 205 to engage proximal anchor 925 and move proximal anchor 925 to the distal end of shaft 195 for deployment into the intervertebral disc. If desired, thumb button 310 can be pulled proximally and rotated to align seat 742 of distally-extending member 740 with tab 750 of handle 200, such that seat 742 will re-engage tab 750 if thumb button 310 should be moved distally, thereby preventing proximal anchor 925 from being prematurely ejected from the distal end of shaft 195 of inserter 910.
Next, inserter 910 is withdrawn from the bone (if it has not already been withdrawn from the bone), and shaft 195 of inserter 910 is inserted through the annulus of the intervertebral disc on the far side of the fissure so that toggling filament 920 and cinching toggling filament 930 spans the fissure. If seat 742 is engaged with tab 750, thumb button 310 is now rotated to arcuately align member 740 with recessed flat 752 of handle 200, and thumb button 310 is advanced distally so as to cause pushrod 205 to eject proximal anchor 925 out of shaft 195 and into the nucleus of the intervertebral disc (see (see
Next, shaft 195 of inserter 910 is removed from the annulus, cinching end 950 of cinching toggling filament 940 is pulled proximally (i.e., perpendicular to the insertion site of proximal anchor 925) causing toggling filament 920 and cinching toggling filament 930 to be pulled taut until closure of the fissure is attained. As this occurs, the geometry of proximal anchor 925, the ball 940 and the tension on cinching toggling filament 930 causes proximal anchor 925 to begin turning within the nucleus of the intervertebral disc.
Once the fissure has been closed, cinching end 950 of cinching toggling filament 930 may be trimmed away at the tissue surface, whereby to complete the repair. Note that the annulus tissue, which is fibrotic and contains many layers of varying tissue orientations, does not allow the proximal anchor to back out during tensioning. Therefore, pulling cinching end 950 of cinching toggling filament 930 also toggles proximal anchor 925 against the inside of the annulus and seats proximal anchor 925 perpendicular to the insertion angle, whereby to set proximal anchor 925 in the nucleus of the intervertebral disc.
Significantly, since two load-sharing suture segments (i.e., toggling filament 920 and cinching toggling filament 930) are now disposed over the fissure in the intervertebral disc, the suture holding power of proximal anchor 925 has now been doubled (in contrast to the holding power provided by single suture 30 of the previously-described anchor assembly 10).
In the foregoing discussion, anchor assembly 905 and inserter 910 are discussed in the context of closing a tear in the annulus of an intervertebral disc. However, it will be appreciated by those skilled in the art that anchor assembly 905 and inserter 910 may be used, separately or in combination with one another, to effect other anatomical repairs and/or other anatomical fixations, and/or to anchor sensory nerve stimulator (SNS) leads, etc.
It should be understood that many additional changes in the details, materials, steps and arrangements of parts, which have been herein described and illustrated in order to explain the nature of the present invention, may be made by those skilled in the art while still remaining within the principles and scope of the invention.
This patent application: (1) is a continuation-in-part of pending prior U.S. patent application Ser. No. 16/681,420, filed Nov. 12, 2019 by Anchor Innovation Medical, Inc. and Duane Lee Griffith et al. for METHOD AND APPARATUS FOR CLOSING A FISSURE IN THE ANNULUS OF AN INTERVERTEBRAL DISC, AND/OR FOR EFFECTING OTHER ANATOMICAL REPAIRS AND/OR FIXATIONS (Attorney's Docket No. SUTURECONCEPTS-12) which in turn: (A) is a continuation-in-part of prior U.S. patent application Ser. No. 15/827,322, filed Nov. 30, 2017 by Anchor Innovation Medical, Inc. and Peter Sorensen et al. for METHOD AND APPARATUS FOR CLOSING A FISSURE IN THE ANNULUS OF AN INTERVERTEBRAL DISC, AND/OR FOR EFFECTING OTHER ANATOMICAL REPAIRS AND/OR FIXATIONS (Attorney's Docket No. SUTURECONCEPTS-6) which in turn: (i) is a continuation-in-part of prior U.S. patent application Ser. No. 14/461,992, filed Aug. 18, 2014 by Suture Concepts Inc. and Peter Sorensen et al. for METHOD AND APPARATUS FOR CLOSING A FISSURE IN THE ANNULUS OF AN INTERVERTEBRAL DISC, AND/OR FOR EFFECTING OTHER ANATOMICAL REPAIRS AND/OR FIXATIONS (Attorney's Docket No. SUTURECONCEPTS-010203), which patent application in turn: (a) claims benefit of prior U.S. Provisional Patent Application Ser. No. 61/866,955, filed Aug. 16, 2013 by Suture Concepts Inc. and Peter Sorensen et al. for METHOD AND APPARATUS FOR CLOSING A FISSURE IN THE ANNULUS OF AN INTERVERTEBRAL DISC, AND/OR FOR EFFECTING OTHER ANATOMICAL REPAIRS AND/OR FIXATIONS (Attorney's Docket No. SUTURECONCEPTS-1 PROV);(b) claims benefit of prior U.S. Provisional Patent Application Ser. No. 61/915,433, filed Dec. 12, 2013 by Suture Concepts Inc. and Peter Sorensen et al. for METHOD AND APPARATUS FOR CLOSING A FISSURE IN THE ANNULUS OF AN INTERVERTEBRAL DISC, AND/OR FOR EFFECTING OTHER ANATOMICAL REPAIRS AND/OR FIXATIONS (Attorney's Docket No. SUTURECONCEPTS-2 PROV);(c) claims benefit of prior U.S. Provisional Patent Application Ser. No. 61/984,431, filed Apr. 25, 2014 by Suture Concepts Inc. and Peter Sorensen et al. for METHOD AND APPARATUS FOR CLOSING A FISSURE IN THE ANNULUS OF AN INTERVERTEBRAL DISC, AND/OR FOR EFFECTING OTHER ANATOMICAL REPAIRS AND/OR FIXATIONS (Attorney's Docket No. SUTURECONCEPTS-3 PROV); and(d) is a continuation-in-part of prior U.S. patent application Ser. No. 14/068,406, filed Oct. 31, 2013 by Suture Concepts Inc. and Bret A. Ferree for METHOD AND APPARATUS FOR CLOSING FISSURES IN THE ANNULUS FIBROSUS (Attorney's Docket No. ANOVA-BAF-24602/29), which in turn claims benefit of prior U.S. Provisional Patent Application Ser. No. 61/720,593, filed Oct. 31, 2012 by Bret A. Ferree for METHOD AND APPARATUS FOR CLOSING FISSURES IN THE ANNULUS FIBROSUS (Attorney's Docket No. ANOVA-BAF-24618/29); and(ii) claims benefit of prior U.S. Provisional Patent Application Ser. No. 62/427,879, filed Nov. 30, 2016 by Suture Concepts Inc. and Peter Sorensen et al. for METHOD AND APPARATUS FOR CLOSING A FISSURE IN THE ANNULUS OF AN INTERVERTEBRAL DISC, AND/OR FOR EFFECTING OTHER ANATOMICAL REPAIRS AND/OR FIXATIONS (Attorney's Docket No. SUTURECONCEPTS-6 PROV); and(B) claims benefit of prior U.S. Provisional Patent Application Ser. No. 62/758,157, filed Nov. 9, 2018 by Anchor Innovation Medical, Inc. and Duane Lee Griffith et al. for METHOD AND APPARATUS FOR CLOSING A FISSURE IN THE ANNULUS OF AN INTERVERTEBRAL DISC, AND/OR FOR EFFECTING OTHER ANATOMICAL REPAIRS AND/OR FIXATIONS (Attorney's Docket No. SUTURECONCEPTS-12 PROV); (2) claims benefit of pending prior U.S. Provisional Patent Application Ser. No. 63/076,170, filed Sep. 9, 2020 by Suture Concepts Inc. and Peter Sorensen et al. for Annular Repair System (Attorney's Docket No. SUTURECONCEPTS-15 PROV). The nine (11) above-identified patent applications are hereby incorporated herein by reference.
Number | Date | Country | |
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61866955 | Aug 2013 | US | |
61915433 | Dec 2013 | US | |
61984431 | Apr 2014 | US | |
61720593 | Oct 2012 | US | |
62427879 | Nov 2016 | US | |
62758157 | Nov 2018 | US | |
63076170 | Sep 2020 | US |
Number | Date | Country | |
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Parent | 16681420 | Nov 2019 | US |
Child | 17471046 | US | |
Parent | 15827322 | Nov 2017 | US |
Child | 16681420 | US | |
Parent | 14461992 | Aug 2014 | US |
Child | 15827322 | US | |
Parent | 14068406 | Oct 2013 | US |
Child | 14461992 | US |