CROSS-REFERENCE TO RELATED APPLICATIONS This application is a continuation-in-part of U.S. patent application Ser. No. 12/013,351, entitled “SPINAL IMPLANTS AND METHODS” and filed on Jan. 11, 2008 which is a continuation-in-part of U.S. patent application Ser. No. 11/293,438, entitled “INTERSPINOUS DISTRACTION DEVICES AND ASSOCIATED METHODS OF INSERTION” and filed on Dec. 2, 2005, which is a continuation-in-part of U.S. patent application Ser. No. 11/257,647, entitled “INTERSPINOUS DISTRACTION DEVICES AND ASSOCIATED METHODS OF INSERTION” and filed on Oct. 25, 2005, each of which is incorporated in full by reference herein.
The present application is also a continuation-in-part of U.S. patent application Ser. No. 11/934,604, entitled “SPINOUS PROCESS IMPLANTS AND ASSOCIATED METHODS” and filed Nov. 2, 2007 which is incorporated in full by reference herein.
The present application further claims the benefit of U.S. Provisional Patent Application No. 60/884,581, entitled “SPINAL STABILIZATION” and filed Jan. 11, 2007, U.S. Provisional Patent Application No. 60/621,712, entitled “INTERSPINOUS DISTRACTION DEVICES AND ASSOCIATED METHODS OF INSERTION,” and filed on Oct. 25, 2004; U.S. Provisional Patent Application No. 60/633,112, entitled “INTERSPINOUS DISTRACTION DEVICES AND ASSOCIATED METHODS OF INSERTION,” and filed on Dec. 3, 2004; U.S. Provisional Patent Application No. 60/639,938, entitled “INTERSPINOUS DISTRACTION DEVICES AND ASSOCIATED METHODS OF INSERTION,” and filed on Dec. 29, 2004; U.S. Provisional Patent Application No. 60/654,483, entitled “INTERSPINOUS DISTRACTION DEVICES AND ASSOCIATED METHODS OF INSERTION,” and filed on Feb. 21, 2005; U.S. Provisional Patent Application No. 60/671,301, entitled “INTERSPINOUS DISTRACTION DEVICES AND ASSOCIATED METHODS OF INSERTION,” and filed on Apr. 14, 2005; U.S. Provisional Patent Application No. 60/678,360, entitled “INTERSPINOUS DISTRACTION DEVICES AND ASSOCIATED METHODS OF INSERTION,” and filed on May 6, 2005; and U.S. Provisional Application No. 60/912,273; entitled “FUSION PLATE WITH REMOVABLE OR ADJUSTABLE SPIKES” and filed Apr. 17, 2007, each of which is incorporated in full by reference herein.
FIELD OF THE INVENTION The present invention relates to spinal implants and associated methods.
BACKGROUND The vertebrae of the human spine are arranged in a column with one vertebra on top of the next. An intervertebral disc lies between adjacent vertebrae to transmit force between the adjacent vertebrae and provide a cushion between them. The discs allow the spine to flex and twist. With age, spinal discs begin to break down, or degenerate resulting in the loss of fluid in the discs and consequently resulting in them becoming less flexible. Likewise, the disks become thinner allowing the vertebrae to move closer together. Degeneration may also result in tears or cracks in the outer layer, or annulus, of the disc. The disc may begin to bulge outwardly. In more severe cases, the inner material of the disc, or nucleus, may actually extrude out of the disc. In addition to degenerative changes in the disc, the spine may undergo changes due to trauma from automobile accidents, falls, heavy lifting, and other activities. Furthermore, in a process known as spinal stenosis, the spinal canal narrows due to excessive bone growth, thickening of tissue in the canal (such as ligament), or both. In all of these conditions, the spaces through which the spinal cord and the spinal nerve roots pass may become narrowed leading to pressure on the nerve tissue which can cause pain, numbness, weakness, or even paralysis in various parts of the body. Finally, the facet joints between adjacent vertebrae may degenerate and cause localized and/or radiating pain. All of the above conditions are collectively referred to herein as spine disease.
Conventionally, surgeons treat spine disease by attempting to restore the normal spacing between adjacent vertebrae. This may be sufficient to relieve pressure from affected nerve tissue. However, it is often necessary to also surgically remove disc material, bone, or other tissues that impinge on the nerve tissue and/or to debride the facet joints. Most often, the restoration of vertebral spacing is accomplished by inserting a rigid spacer made of bone, metal, or plastic into the disc space between the adjacent vertebrae and allowing the vertebrae to grow together, or fuse, into a single piece of bone. The vertebrae are typically stabilized during this fusion process with the use of bone plates and/or pedicle screws fastened to the adjacent vertebrae.
Although techniques for placing intervertebral spacers, plates, and pedicle screw fixation systems have become less invasive in recent years, they still require the placement of hardware deep within the surgical site adjacent to the spine. Recovery from such surgery can require several days of hospitalization and long, slow rehabilitation to normal activity levels.
More recently, investigators have promoted the use of motion preservation implants and techniques in which adjacent vertebrae are permitted to move relative to one another. One such implant that has met with only limited success is the artificial disc implant. These typically include either a flexible material or a two-piece articulating joint inserted in the disc space. Another such implant is the spinous process spacer which is inserted between the posteriorly extending spinous processes of adjacent vertebrae to act as an extension stop and to maintain a minimum spacing between the spinous processes when the spine is in extension. The spinous process spacer allows the adjacent spinous processes to move apart as the spine is flexed.
BRIEF DESCRIPTION OF THE DRAWINGS Various examples of the present invention will be discussed with reference to the appended drawings. These drawings depict only illustrative examples of the invention and are not to be considered limiting of its scope.
FIG. 1 is a perspective view of a spinal implant according to the present invention;
FIG. 2 is a cross sectional view of the spinal implant of FIG. 1 showing the implant in a first position;
FIG. 3 is a cross sectional view of the spinal implant of FIG. 1 showing the implant in a second position;
FIG. 4 is an elevation view of a spinal implant according to the present invention showing the implant in a first position;
FIG. 5 is an elevation view of the spinal implant of FIG. 4 showing the implant in a second position;
FIG. 6 is a perspective view of a spinal implant according to the present invention;
FIG. 7 is a cross sectional view of the implant of FIG. 6;
FIG. 8 is a perspective view of a spinal implant according to the present invention;
FIG. 9 is a perspective view of a spacer component of the spinal implant of FIG. 8 in a first position;
FIG. 10 is a perspective view of a spacer component of the spinal implant of FIG. 8 in a second position;
FIG. 11 is an elevation view of a core component of the spinal implant of FIG. 8 in a first position;
FIG. 12 is a perspective view of a spinal implant according to the present invention;
FIG. 13 is a perspective view of the spinal implant of FIG. 12 illustrating one method of insertion;
FIG. 14 is a perspective view of the spinal implant of FIG. 12 illustrating another method of insertion;
FIG. 15 is a perspective view of an alternative configuration for the retention members of the spinal implant of FIG. 12;
FIG. 16 is a perspective view of a spinal implant according to the present invention;
FIG. 17 is an elevation view of a spinal implant according to the present invention in a first position;
FIG. 18 is an elevation view of the spinal implant of FIG. 17 in a second position;
FIG. 19 is a perspective detail view of one end of the spinal implant of FIG. 17 showing the first and second positions superimposed on one another
FIG. 20 is a perspective view of a spinal implant according to the present invention;
FIG. 21 is a perspective view of the spinal implant of FIG. 20 shown implanted in a first position;
FIG. 22 is a perspective view of the spinal implant of FIG. 20 shown implanted in a second position;
FIG. 23 is a perspective view of a spinal implant according to the present invention in a first position;
FIG. 24 is a perspective view of the spinal implant of FIG. 23 in a second position;
FIG. 25 is a perspective view of a spinal implant according to the present invention in a first position;
FIG. 26 is a perspective view of the spinal implant of FIG. 24 in a second position;
FIG. 27 is a perspective view of the spinal implant of FIG. 26 in a third position;
FIG. 28 is a cross sectional view of a spinal implant according to the present invention in a first position;
FIG. 29 is a cross sectional view of the spinal implant of FIG. 28 in a second position;
FIG. 30 is a perspective view of a spinal implant according to the present invention in a first position;
FIG. 31 is a side elevation view of the spinal implant of FIG. 30 in the first position;
FIG. 32 is a front elevation view of the spinal implant of FIG. 30 in the first position;
FIG. 33 is a perspective view of the spinal-implant of FIG. 30 in a second position;
FIG. 34 is a perspective view of a spinal implant according to the present invention in a first position;
FIG. 35 is a perspective view of the spinal implant of FIG. 34 in a second position;
FIG. 36 is a perspective view of the spinal implant of FIG. 34 in a third position;
FIG. 37 is a perspective view of the spinal implant of FIG. 34 implanted in a spine;
FIG. 38 is a perspective view of a spinal implant according to the present invention;
FIG. 39 is a front elevation view of the spinal implant of FIG. 38 implanted in a spine;
FIG. 40 is a cross sectional view of a spinal implant according to the present invention implanted in a spine;
FIG. 41 is a cross sectional view of a spinal implant according to the present invention implanted in a spine;
FIG. 42 is a front elevation view of a component of a spinal implant according to the present invention being implanted in a spine;
FIG. 43 is a front elevation view of the fully assembled implant of FIG. 42 implanted in a spine;
FIG. 44 is a perspective view of a spinal implant according to the present invention in a first position;
FIG. 45 is a perspective view of the spinal implant of FIG. 44 in a second position;
FIG. 46 is a perspective view of the spinal implant of FIG. 44 in a third position;
FIG. 47 is a perspective view of a spinal implant according to the present invention in a first position;
FIG. 48 is a perspective view of the spinal implant of FIG. 47 in a second position;
FIG. 49 is a perspective view of a spinal implant according to the present invention in a first position;
FIG. 50 is a side elevation view of the spinal implant of FIG. 49 in a second position;
FIG. 51 is a perspective view of a spinal implant according to the present invention in a first position;
FIG. 52 is a perspective view of the spinal implant of FIG. 51 in a second position;
FIG. 53 is a perspective view of a spinal implant according to the present invention in a first position;
FIG. 54 is a perspective view of the spinal implant of FIG. 53 in a second position;
FIG. 55 is an exploded perspective view of a spinal implant according to the present invention;
FIG. 56 is a front elevation view of the spinal implant of FIG. 55 in a first position;
FIG. 57 is a front elevation view of the spinal implant of FIG. 55 in a second position
FIG. 58 is an exploded perspective view of a spinal implant according to the present invention;
FIG. 59 is an exploded perspective view of a spinal implant according to the present invention;
FIG. 60 is a right perspective view of a spinal implant according to the present invention;
FIG. 61 is a left perspective view of the spinal implant of FIG. 60;
FIG. 62 is a left perspective view of a spinal implant according to the present invention;
FIG. 63 is a right perspective view of the spinal implant of FIG. 62;
FIG. 64 is a perspective view of a spinal implant according to the present invention;
FIG. 65 is a perspective view of a spinal implant according to the present invention;
FIG. 66 is a front elevation view of the spinal implant of FIG. 65;
FIG. 67 is a front elevation view of a spinal implant according to the present invention;
FIG. 68 is a flow diagram of a method of inserting a spinal implant according to the present invention;
FIG. 69 is a front elevation view of a spinal implant according to the present invention; and
FIG. 70 is a perspective view of an alternative embodiment of the spinal implant of FIG. 69.
DESCRIPTION OF THE ILLUSTRATIVE EXAMPLES Embodiments of spinal implants according to the present invention include a spacer and one or more retention members. Throughout this specification, the spinal implant will be referred to in the context of a spinous process implant. However, it is to be understood that the spinal implant may be configured for insertion into the cervical, thoracic, and/or lumbar spine between adjacent spinous processes, transverse processes, and/or other vertebral structures. The spacer may be provided in a variety of sizes to accommodate anatomical variation amongst patients and varying degrees of space correction. The spacer may include openings to facilitate tissue in-growth to anchor the spacer to the vertebral bodies such as tissue in-growth from the spine. For example, the spacer may be configured for tissue in-growth from superior and inferior spinous processes to cause fusion of the adjacent spinous processes. The openings may be relatively large and/or communicate to a hollow interior of the spacer. A hollow interior may be configured to receive bone growth promoting substances such as by packing the substances into the hollow interior. The openings may be relatively small and/or comprise pores or interconnecting pores over at least a portion of the spacer surface. The openings may be filled with bone growth promoting substances.
The spacer may have any suitable cross-sectional shape. For example, it may be cylindrical, wedge shaped, D-shaped, C-shaped, H-shaped, include separated cantilevered beams, and/or any other suitable shape. The shape may include chamfers, fillets, flats, relief cuts, and/or other features to accommodate anatomical features such as for example the laminae and/or facets.
The spacer may be incompressible, moderately compressible, highly compressible, convertible from compressible to incompressible, and/or any other configuration. For example, the spacer may be compressible into a compact configuration for insertion between adjacent bones and then expandable to space the bones apart. The spacer may be allowed to flex to provide a resilient cushion between the bones. The spacer may be locked in the expanded condition to prevent it from returning to the compact configuration.
The retention member may extend transversely from the spacer relative to a spacer longitudinal axis to maintain the spacer between adjacent spinous processes. A single retention member may extend in one or more directions or multiple extensions may be provided that extend in multiple directions. One or more retention members may be fixed relative to the spacer longitudinally and/or radially. One or more retention members may be adjustable relative to the spacer and/or other retention members longitudinally and/or radially to allow the retention members to be positioned relative to the spinous processes. The retention members may be deployable through and/or from within the spacer to allow the spacer to be placed and the retention members deployed in a minimally invasive manner. The retention members may include one or more screws, pins, nails, bolts, staples, hooks, plates, wings, bars, extensions, filaments, wires, loops, bands, straps, cables, cords, sutures, and/or other suitable retention member. The retention members may be made of metals, metal alloys, polymers, and/or other suitable materials. The retention members may grip bone and/or soft tissue, abut bone and/or soft tissue, facilitate tissue ingrowth and/or ongrowth, and/or otherwise retain the implant.
The retention members may cooperate with fasteners engageable with the spinous processes and/or soft tissue. Such fasteners may include one or more screws, pins, nails, rivets, bolts, staples, hooks, sutures, wires, straps, clamps, spikes, teeth, adhesives, and/or other suitable fasteners. The fasteners may be integrated into the retention members or they may be modular. The retention members and/or fasteners may be adjustable, replaceable, and/or removable and may be employed in one direction and/or on one side of the implant or in multiple directions and/or on multiple sides of the implant to allow tailoring of the kind and quality of fixation of adjacent bones. For example, the implant may be placed such that it acts only as a spacer between adjacent bones, as an elastic restraint between adjacent bones, or as a rigid fixation between adjacent bones. The spacer, retention members, and/or fasteners may advantageously be made of different materials.
Cerclage may be used to stabilize the spinal implant and/or to provide other benefits. For example, wires, straps, bands, cables, cords, and/or other elongated members may encircle the pedicles, laminae, spinous processes, transverse processes, and/or other spinal structures. The cerclage may be relatively inextensible to provide a hard check to spine flexion or the cerclage may be relatively extensible to provide increasing resistance to flexion. The cerclage may be relatively flexible and drapeable such as a woven fabric or it may be relatively rigid such as a metal band. The cerclage may have shape memory properties that cause it to resume a prior set shape after implantation. The cerclage may be independent of the spinous process implant or may engage it. For example, the cerclage may pass through a hollow interior of the spinous process implant and/or engage the extension.
The implant may be supplemented with bone growth promoting substances to facilitate fusion of adjacent vertebrae between spinous processes, laminae, transverse processes, facets, and/or other spinal structures. The bone growth promoting substances may be spaced from the implant, placed adjacent the implant, sandwiched between the implant and underlying bone, placed inside the implant, coated onto the implant, and/or otherwise placed relative to the implant. If it is coated onto the implant it may cover the entire implant or only selected portions of the implant such as the spacer, retention members, fasteners, and/or other portions.
As used herein, bone growth promoting substances may include bone paste, bone chips, bone strips, structural bone grafts, platelet derived growth factors, bone marrow aspirate, stem cells, bone growth proteins, bone growth peptides, bone attachment proteins, bone attachment peptides, hydroxylapatite, calcium phosphate, statins, and/or other suitable bone growth promoting substances.
The spinal implant and any associated cerclage or other components may be made of any suitable biocompatible material including among others metals, resorbable ceramics, non-resorbable ceramics, resorbable polymers, and non-resorbable polymers. Some specific examples include stainless steel, titanium and its alloys including nickel-titanium alloys, tantalum, hydroxylapatite, calcium phosphate, bone, zirconia, alumina, carbon, bioglass, polyesters, polylactic acid, polyglycolic acid, polyolefins, polyamides, polyimides, polyacrylates, polyketones, fluropolymers, and/or other suitable biocompatible materials and combinations thereof.
The spinal implant may be used to treat spine disease in a variety of surgical techniques including superspinous ligament sacrificing posterior approaches, superspinous ligament preserving posterior approaches, lateral approaches, and/or other suitable approaches. The spinal implant may be used to treat spine disease by fusing adjacent vertebrae or by preserving motion between adjacent vertebrae. It may include only an extension stop such as a spacer, only a flexion stop such as flexible cerclage elements, or both a flexion and extension stop. The spinous process implant may be used to reduce loads on the facet joints, increase spinous process spacing, reduce loads on the disc, increase disc spacing, and/or otherwise treat spine disease. Techniques for the spinal implant may include leaving the tissues at the surgical site unmodified or modifying tissues such as trimming, rasping, roughening, and/or otherwise modifying tissues at the implant site.
For example, FIGS. 1-3 illustrate a spinal implant 100 including a spacer 102 and a plurality of retention members in the form of first and second plate extensions 104, 105 and deployable retention members 106, 108, and 110. The spacer 102 has a generally cylindrical body 112 having a proximal end 114, a distal end 116, and a longitudinal spacer axis 118 extending therebetween. The distal end 116 tapers to an edge to facilitate inserting the spacer 102 between two bones, e.g. adjacent spinous processes. The distal end is defined by a superior facet 120, an inferior facet 122, and lateral facets 124 (one shown).
The first plate extension 104 projects radially outwardly from the spacer 102 adjacent the proximal end and the second plate extension 105 projects radially outwardly from the spacer 102 opposite the first plate extension 104. The plate extensions 104, 105 may be integral with the spacer 102 as shown in FIGS. 1-3 or modular and separable from the spacer 102. The plate extensions 104, 105 provide an insertion stop by abutting the spinous processes 126, 128.
The deployable retention members 106, 108, 110 may be pre-installed within the spacer 102 or inserted into the spacer 102 intraoperatively. Preferably they are pre-installed and retracted within the spacer 102 as shown in FIG. 2. Each deployable retention member 106, 108, 110 is directed into a channel 130, 132, 134 that communicates from the interior of the spacer 102 out through the distal end 116 to the exterior of the spacer 102. The deployable retention members 106, 108, 110 are joined at their proximal ends 136 so that they move together. The interior of the spacer includes a cavity 137 that houses the deployable retention members 106, 108, 110 in the un-deployed position. The cavity 137 is threaded and receive an actuator screw 138 in axial translating relationship.
In use, the spinal implant 100 is inserted between adjacent spinous processes 126, 128 as shown. The actuator screw 138 is then rotated so that it translates along the spacer axis 118 and pushes the deployable retention members 106, 108, 110 distally through the channels 130, 132, 134. The spacer 102 includes a pair of sockets 139 at its proximal end 114 for receiving a tool for applying a counter torque to the spacer 102 while the actuator screw 138 is rotated. The channels 130, 132, 134 may be curved to cause the deployable retention members 106, 108, 110 to bend away from the spacer axis 118 and grip the spinous processes 126, 128 and/or surrounding soft tissue. The deployable retention members 106, 108, 110 may also be pre-bent and then elastically straightened as they are loaded into the un-deployed position of FIG. 2. Upon being deployed, they may then return to their pre-bent shape. The deployable retention members 106, 108, 110 may advantageously be made of a superelastic material such as Nitinol. They may also respond to the patient's body temperature to change shape from the straight configuration of FIG. 2 to the curved configuration of FIG. 3. Soft tissue may also grow around, adhere to, scar around, and/or otherwise grip the deployable retention members 106, 108, 110 over time. Deployable retention member 110 is split at its distal-end to form a loop 140 that opens upon being deployed from the spacer 102 to facilitate tissue growth into and around the loop 140 for increased retention strength. A plurality of holes 142 are formed through the plate extensions 104, 105 for receiving fasteners for attaching the plate extensions 104, 105 to the surrounding bone and/or soft tissue. Such fasteners may include any of the fasteners listed above. A pin 144 is shown in one of the holes 142 in FIG. 3.
FIGS. 4-5 illustrate a spinal implant 200 similar in form and function to that of FIGS. 1-3. The spinal implant 200 includes a spacer 202, deployable retention members 204, and spacer end pieces 206. The spacer 202 and end pieces 206 are generally cylindrical and are aligned along a spacer axis 208 and connected by a threaded shaft 210 that threadably engages the end pieces 206. The threaded shaft 210 is mounted to the spacer 202 for axial rotation and includes a driver engaging end 212. The deployable retention members 204 are fixed in the spacer 202 and are slidably received in channels 214 in the end pieces 206.
In use, the spinal implant 200 is inserted between adjacent bones such as spinous processes 220, 222. A driver (not shown) is engaged with the driver engaging end 212 of the threaded shaft 210 and rotated to move the end pieces 206 toward the spacer 202 causing the retention members 204 to extend out of the channels 214 away from the spacer axis 208 as shown in FIG. 5. A tool (not shown) may be engaged with one or more sockets 224 in one of the end pieces 206 or notches 226 in the spacer 202 to apply a counter torque while the threaded shaft 210 is rotated.
FIGS. 6-7 illustrate a spinal implant 300 similar in form and function to that of FIGS. 1-3. The spinal implant 300 includes a spacer 302, a core 304, and deployable retention members 306 extending from the core 304. The deployable retention members 306 include a plurality of wires projecting in a radial array from a core/spacer axis 308 at each end of the core 304. In the illustrative example, which have been designed for interspinous placement, there are no wires projecting anteriorly to avoid impingement with the facets and/or other spinal structures. The core 304 and deployable retention members 306 are received in a passageway 309 through the spacer 302 parallel to the spacer axis 308.
In use, the spacer 302 is positioned between adjacent bones such as spinous processes 310, 312. The core 304 and deployable retention members 306 may be partially pre-inserted as shown in FIG. 7 such that after the spacer 302 is positioned the core is advanced to deploy the deployable retention members 306. Alternatively, the core and deployable retention members 306 may be separate from the spacer 302 and inserted after the spacer is placed. In either case, a tube 314 may optionally be used to hold the deployable retention members 306 and/or core 304 prior to deployment. As shown in FIG. 7, the tube 314 may be engaged with the spacer 302 in alignment with the passageway 309 and the core 304 and deployable retention members 306 pushed from the tube 314 into the passageway 309 until the deployable retention members 306 deploy from the opposite end of the passageway 309. The tube 314 may be withdrawn to permit the remaining deployable retention members 306 to deploy.
FIGS. 8-11 illustrate a spinal implant 400 similar in form and function to that of FIGS. 1-3. The spinal implant 400 includes a generally cylindrical hollow spacer 402 having a first end 404, a second end 406, and a spacer axis 408 extending from the first end 404 to the second end 406. A core 410 is positionable within the spacer 402 along the spacer axis 408. Optionally, a plurality of deployable retention members 412 project radially away from the spacer axis 408 at each end of the core 410. The spacer 402 is made of a compressible material such as a superelastic metal or polymer such that it can be compressed to facilitate insertion. For example, as shown in FIG. 9, the prongs 420 of a tool (not shown) may be inserted into the spacer 402 and spread apart to stretch the spacer 402 into a flattened elliptical shape. The spacer 402 may then be inserted and the prongs removed to allow the spacer 402 to recover to its original shape. Depending on the modulus of the spacer 402 and the loads exerted on it by the surrounding bones, it may recover to its full pre-insertion height and distract the bones or it may only recover partially. The core 410 may then be inserted to maintain the spacer 402 at its recovered height. The core 410 may be sized to press into the spacer 402 and thereby prevent any compression of the spacer 402 post-insertion or the core may be sized to allow a predetermined amount of compression of the spacer 402 to provide a resilient spacer. The optional deployable retention members 412 may be omitted and the spinal implant 400 used in the condition shown in FIG. 10. Preferably, the core 410 includes deployable retention members 412 in the form of filaments that can be deployed as an array of loops projecting radially outwardly from the spacer axis 408 at each end of the core 410. The retention members 412 may retain the space 402 in place by physically blocking withdrawal. The retention members 412 may also retain the spacer 402 due to tissue growth around the retaining members 412.
FIG. 11 illustrates one way of arranging the deployable retention members 412. A plurality of rings 422 are mounted on the core 410 with at least one of the rings 422 being axially translatable along the core 410. The rings are connected by a plurality of filaments 424 spiraling around the core 410.
In use, the spacer 402 is inserted between adjacent bones such as adjacent spinous processes and the core 410 is inserted into the spacer 402. At least one ring 422 is moved toward another ring 422 causing the filaments 424 to bend away from the core and form the array of loops as shown in FIG. 8. Alternatively, the retaining members 412 may be folded down parallel to the spacer axis 408 similar to the embodiment of FIG. 7.
FIGS. 12-14 illustrate a spinal implant 500 similar in form and function to that of FIGS. 1-3. The spinal implant 500 includes a spacer 502 having a generally cylindrical hollow body 504 including a first end 506, a second end 508, and a spacer axis 510 extending from the first end 506 to the second end 508. The ends of the spacer 502 are tapered to facilitate insertion between adjacent bones. A plurality of channels 512 extend through the body 504 from the first end 506 to the second end 508 generally parallel to the spacer axis 510. Deployable retention members 514 are engageable with channels 512 in axially slidable relationship. In the illustrative example of FIGS. 12-14, the channels 512 and deployable retention members 514 have complimentary rectangular cross sectional shapes. The deployable retention members 514 are curved to extend radially away from the spacer axis 510 and grip the spinous processes.
In use, the deployable retention members 514 are straightened and/or retracted to allow the spinal implant 500 to be inserted between the spinous processes. This may be accomplished in a variety of ways. As shown in FIG. 13, the deployable retention members 514 may be withdrawn partway through the channels 512 forcing them to straighten. They may include a stop to prevent them from being withdrawn completely. After the spacer 502 is inserted between the spinous processes, the deployable retention members 514 may be fed through the channels 512 and allowed to resume their curved configuration. Alternatively the deployable retention members 514 may be separated from the spacer 502 completely and not introduced until after the spacer 502 has been inserted. As shown in FIG. 14, the deployable retention members 514 may be straightened and the spinal implant 500 inserted through a tube 520 and into the space between the spinous processes. FIG. 12 illustrates the spinal implant 500 post-insertion with the deployable retention members 514 fully deployed. FIG. 15 illustrates a spinal implant 600 similar to that of FIGS. 12-14. Spinal implant 600 has deployable retention members 602 in the form of wires rather than the rectangular ribbon-like deployable retention members 514 of FIGS. 12-14.
FIG. 16 illustrates a spinal implant 700 similar to that of FIGS. 12-14. Spinal implant 700 includes a spacer 702 having a passageway 704 through the spacer 702 parallel to a spacer axis 706. After the spacer 702 is inserted between adjacent spinous processes, a preformed deployable retention member 708 in the form of a wire is inserted through the passageway 704 from a first end to a second end of the passageway so that it emerges from the second end and returns to its preformed shape to extend transverse to the spacer axis 706 beyond the outer surface of the spacer 702. The end of the deployable retention member may also extend transverse to spacer axis 706 at the first end of the spacer axis so that the deployable retention member may extend on both sides of a process to capture the process. Alternatively, a set screw or other mechanism may be provided to fix the deployable retention member 708 in the passageway 704 after the deployable retention member 708 has been deployed. In the illustrative embodiment the deployable retention member 708 is preformed into a coil.
FIGS. 17-19 illustrate a spinal implant 800 similar to the previous embodiments. The spinal implant 800 includes a spacer 802 having first and second ends 804, 806 and a spacer axis 808 extending therebetween. The spacer 802 may be wedge shaped, cylindrical, elliptical, rectangular, and/or any other suitable shape. The shape may be based on anatomical considerations. Deployable retention members are provided in the form of a terminal portion 810, 812 extending from each end 804, 806 of the spacer 802. The terminal portions 810, 812 have a compact position or shape closer to the spacer axis 808 as shown in FIG. 17 and an expanded position or shape further from the spacer axis 808 as shown in FIG. 18. FIG. 19 illustrates the compact and expanded positions superimposed for comparison. In the illustrative embodiment of FIGS. 17-19 the terminal portions 810, 812 are provided as coils such as a conventional helical spring coil and the compact position corresponds to a coil being tightly wound and the expanded position corresponds to the coil being loosely wound. However, the terminal portions 810, 812 may be shaped as a flange, solid disc, protrusion, bar, or the like as a matter of design choice. The spinal implant 800 is implanted with at least one of the terminal portions 810, 812 in the compact position. Once placed, one or both terminal portions are allowed to expand. For example, the coils may unwind due to their own spring tension. Alternatively, the coils may be activated, such as e.g. by heat, to expand. The spacer 802 separates adjacent spinous processes and the expanded terminal portions 810, 812 maintain the spacer 802 between the spinous processes.
While the terminal portions 810, 812 may be separate devices, in the illustrative embodiment of FIGS. 17-19, the terminal portions 810, 812 are connected through a passageway 814 formed through the spacer 802 along the spacer axis 808. In this embodiment, the terminal portions 810, 812 are the ends of a continuous coil placed within the passageway 814. The coil may be designed to be in tension such that the terminal portions tend to seat against the spinous processes to hold the spacer 802 firmly in place.
The termination portions 810, 812 may be formed of any number of materials, but superelastic materials such as shape memory metal alloys or polymers are advantageous. In particular, shape memory materials can be designed having a first small shape to allow less traumatic implantation of the device. Once implanted, activation of the shape memory material would cause the terminal portions 810, 812 to move from the compact position to the expanded position. Moreover, for a continuous coil embodiment, the coil may be configured to retract and thereby seat the terminal portions against the spinous process.
The spacer 802 may be provided with one or more surface grooves 816 to receive, e.g., the prongs of a surgical distraction tool so that the spacer may be placed along the prongs after the spinous processes have been distracted.
FIGS. 20-22 illustrate an alternative arrangement to that of FIGS. 17-19 in which a spinal implant 900 includes a spacer 902 and a coil 904 wrapped around the outside of the spacer 902. The coil 904 may have shape memory properties allowing it to be transformed from a compact position to an expanded position or it may always be biased toward the expanded position. In the case where it is always biased toward the expanded position, the coil 904 may be maintained in the compact position by a sleeve 906 or other surrounding structure. The spinal implant 900 is placed between adjacent bones, e.g. spinous processes 910, 912, in the compact position (FIG. 21) and allowed, or activated, to transition to the expanded position (FIG. 22) to maintain the spacer 902 between the bones. Alternatively, the spacer 902 may be removed after the spinal implant is implanted or the spacer 902 may be omitted entirely such that just the coil 904 serves as both a spacer and retention member.
FIGS. 23-24 illustrate a spinal implant 1000 including a spacer 1002 having a proximal end 1004, a distal end 1006, and a spacer axis 1008 extending therebetween. Optionally, the distal end 1006 may be tapered as shown to facilitate insertion between adjacent bones. The spinal implant 1000 includes one or more deployable retention members mounted for rotation to the spacer 1002 for rotation between a compact or stowed position (FIG. 23) and an expanded or deployed position (FIG. 24). In the illustrative embodiment of FIGS. 23-24, the deployable retention members are in the form of wires 1010 mounted to brackets 1012 extending radially away from the spacer axis 1008. The wires 1010 extend between the brackets 1012 generally parallel to the spacer axis 1008 and then bend transverse to the spacer axis 1008 at the proximal and distal ends 1004, 1006. The spacer 1002 includes an annular groove 1014 adjacent the distal end and the wires 1010 are curved distally to engage the groove 1014 in the compact or stowed position. As shown in FIG. 23, the groove 1014 may receive the wires 1010 so that their curved portions are completely recessed to ease implantation. The proximal ends of the wires 1010 are positioned behind the proximal end 1004 of the spacer 1002 in the compact or stowed position to ease implantation. After the spinal implant 1000 is inserted between adjacent bones, e.g. spinous processes, the wires 1010 are rotated from the stowed position to the deployed position to maintain the spacer 1002 between the bones. In the illustrative embodiment of FIGS. 23-24 the proximal ends of the wires can be accessed after implantation to rotate the wires 1010. The wires may maintain their position due to friction with the brackets 1012 or an additional locking mechanism may be provided. For example, detents 1016 may be provided to receive the wires and help maintain them in position, e.g. in the deployed position.
FIGS. 25-27 illustrate a spinal implant 1100 including a spacer 1102 having a first end 1104, a second end 1106, and a spacer axis 1108 extending therebetween. One or more deployable retention members in the form of end pieces are mounted to the spacer 1102 for rotation between a stowed position nearer the spacer axis 1108 and a deployed position further from the spacer axis. For example, the spinal implant may include a pair of outer end pieces 1110 and a pair of inner end pieces 1112 with one outer and one inner end piece at each end of the spacer. The outer end pieces 1110 are mounted for rotation about an axis 1114 offset from the spacer axis 1108 so that they move nearer to or further from the spacer axis 1108 as they rotate. For example, the outer end pieces 1110 may be mounted on a common shaft 1116 so that they rotate together. The inner end pieces 1112 may be similarly mounted for rotation about an offset axis 1118 on a common shaft 1120. Preferably the inner pieces 1112 are mounted on a shaft 1120 that is offset from both the spacer axis 1108 and the shaft 1116 that the outer end pieces 1110 are mounted on so that the inner and outer end pieces 1112, 1110 move away from the spacer axis 1108 in different directions. In the example of FIGS. 25-27, the inner end pieces 1112 have been relieve; e.g. to include notches 1122 (FIG. 27); to clear the shaft of the outer end pieces 1110 so that they may be rotated to a stowed position that is coaxial with the spacer 1102 as shown in FIG. 25. In use, the spinal implant 1100 is inserted between adjacent bones, e.g. spinous processes, in the stowed position of FIG. 25. Once the spacer 1102 is in the desired location one or more of the outer and inner end pieces 1110, 1112 may be rotated to the deployed position to maintain the spacer 1102 in position. Driver engaging sockets 1124 are provided to facilitate rotating the end pieces. Any number of end pieces may be provided up to and including an implant 1100 in which the entire spacer is made up of a series of end pieces. The end pieces may be selectively rotated to achieve the desired fit with the adjacent bones. The end pieces may be mounted to separate shafts or otherwise mounted for independent rotation. The end pieces may be mounted to a shaft so that they slip when a torque threshold is met. For example, the end pieces may be mounted for predetermined slipping such that if a plurality of end pieces are being rotated together on a common shaft and one abuts a bone, the abutting end piece may slip on the shaft and thereby permit the other end pieces to be rotated fully into the deployed position.
FIGS. 28-29 illustrate a spinal implant 1200 similar to that of FIGS. 25-27. The spinal implant 1200 includes a spacer 1202, a proximal end 1204, a distal end 1206, and a spacer axis 1208 extending therebetween. A fixed retention member in the form of a plate or bar shaped extension 1210 extends radially away from the spacer axis 1208 adjacent the proximal end 1204. A deployable retention member in the form of an end piece 1212 is mounted at the distal end 1206; The end piece. 1212 is preferably tapered as shown to facilitate insertion between adjacent bones. The end piece 1212 is mounted to the spacer 1202 for rotation about an end piece rotation axis 1214 transverse to the spacer axis 1208. For example, the distal end 1206 of the spacer may include a distal face 1216 transverse to the spacer axis 1208 and a trunnion 1218 projecting outwardly normal to the distal face 1216. The end piece 1212 includes a complimentary proximal face 1220 with a socket 1222 for receiving the trunnion 1218. The end piece 1212 is rotatable about the rotation axis 1214 from a compact or stowed position as shown in FIG. 28 in which the end piece 1212 extends generally parallel to the spacer axis 1288 to an expanded or deployed position as shown in FIG. 29 in which the end piece 212 extends generally transverse to the spacer axis 1208. To facilitate rotation of the end piece 1212, a shaft 1224 extends from the end piece 1212 through a passageway 1226 in the spacer 1202 to the proximal end 1204. The shaft 1224 may extend parallel to the rotation axis 1214 or it may bend as shown. A bent shaft may include a flexible portion, a universal joint, a bevel gear, and/or some other arrangement to permit transmitting torque through the bend. A driver engaging socket 1228 is provided at the end of the shaft to engage a tool for rotating the end piece.
FIGS. 30-33 illustrate a spinal implant 1300 similar to that of FIGS. 28-29. The spinal implant 1300 includes a spacer 1302 having a proximal end 1304, a distal end 1306, and a spacer axis 1308 extending therebetween. A plurality of deployable retention members are provided at each end in the form end pieces 1310, 1312 mounted for rotation about axes transverse to the spacer axis 1308. As revealed through the broken away portion of the spacer 1302 in FIG. 30, the end pieces are mounted to gears 1314 that engage additional gears 1316 on a drive shaft 1318. As the drive shaft 1318 is rotated, the end pieces 1310, 1312 rotate away from the spacer axis 1308 from the stowed position of FIGS. 30-32 to the deployed position of FIG. 33.
FIGS. 34-37 illustrate another spinal implant 1400 including a spacer 1402 having a first end 1404, a second end 1406, and a spacer axis 1408 extending therebetween. The spacer 1402 is in the form of a cylinder, rectangle, wedge, cone, and/or some other suitable shape and is compressible transverse to the spacer axis 1408. In the illustrative example of FIGS. 34-37 the spacer is hollow and made of an elastic material, preferably a superelastic and/or shape memory material. The spinal implant 1400 includes one or more arms 1410 extending away from the ends 1404, 1406 of the spacer 1402. The arms are also preferably made of an elastic material such as a superelastic and/or shape memory material. In a compact or stowed position (FIG. 34), the spacer 1402 is compressed radially toward the spacer axis 1408 and the arms 1410 extend outwardly generally parallel to the spacer axis 1408. In an expanded or deployed position (FIG. 36) the spacer 1402 is expanded away from the spacer axis 1408 and the arms 1410 extend transverse to the spacer axis 1408. In use, the spinal implant 1400 is inserted between adjacent bones; e.g. spinous processes 1420, 1422; in the compact position and then allowed or activated to transition to the expanded position (FIG. 37). In the illustrative example of FIGS. 34-37, the arms 1410 have a pre-formed shape in which they arch or curve back over the spacer 1402 to grip the spinous processes. In the illustrative example, the arms 1410 also have holes 1424 to receive fasteners similar to the embodiment of FIGS. 1-3. The spacer 1402 may also receive a core (not shown) to maintain a minimum expanded height similar to the embodiment of FIGS. 9-12.
FIGS. 38-39 illustrate a spinal implant 1500 including a spacer 1502 having one or more holes 1504 to receive fasteners similar to the embodiment of FIGS. 1-3. In the illustrative example of FIGS. 38-39, the spacer 1502 is a hollow cylinder with the holes 1504 extending through the wall of the cylinder and being arrayed around the ends of the spacer 1502. The spacer 1502 may be secured by placing fasteners through the holes 1504 and into one or more adjacent bones and/or into surrounding soft tissue. The spacer 1502 may be secured at one end, at both ends, to tissue associated with one adjacent bone, to tissue associated with multiple adjacent bones, and/or any combination of securing arrangements. In the example of FIG. 39, the spacer 1502 is placed between adjacent spinous processes and sutured to the surrounding soft tissue 1506 at both ends.
FIG. 40 illustrates a spinal implant 1600 similar to that of FIGS. 38-39. The spinal implant 1600 includes a generally solid spacer 1602 and includes one or more transverse passageways 1604 for receiving one or more fasteners 1606. Preferably the passageways 1604 communicate from the end of the spacer to the outer surface of the spacer transverse to the spacer axis as shown. The spacer 1602 may be attached to one adjacent bone, both adjacent bones, from one side or from two sides. For example, in a unilateral procedure a fastener may be placed into only one bone to maintain the spacer 1602 in position. Alternatively a fastener may be placed into each of the adjacent bones to maintain the spacer 1602 in position and also to hold the adjacent bones in position relative to one another. In the example of FIG. 40, screws are placed from each side of the spacer 1602 into adjacent spinous processes 1610, 1612.
FIG. 41 illustrates a spinal implant 1700 similar to that of FIG. 40. Spinal implant 1700 includes a spacer 1702, a retention member in the form of a flange 1704, and holes 1706 through the flange for receiving fasteners 1708. The holes 1706 may be parallel to the spacer axis (as shown) or transverse to the spacer axis.
FIGS. 42-43 illustrate a spinal implant 1800 including a base 1802 having a base axis 1804 and a hook 1806 having a portion 1808 extending generally transversely away from the base axis 1804 and a portion 1810 extending generally parallel to the base axis 1804. The spinal implant 1800 further includes a spacer 1812 engageable with the base 1802. The spacer 1812 may be cylindrical, rectangular, conical, and/or any other suitable shape. In the illustrative example of FIGS. 42-43, the spacer 1812 is generally conical and threadably engages the base 1802 in axial translating relationship. In use, the hook 1806 is placed around a portion of one or more adjacent bones, e.g. it may be inserted between adjacent spinous processes to catch on one of the spinous processes as shown in FIG. 42. The spacer spaces them apart a desired distance as shown in FIG. 43. The spinal implant 1800 allows unilateral and minimally invasive placement like the previous examples and adjustable spacing determined by the axial position of the conical spacer 1812.
FIGS. 44-46 illustrate a spinal implant 1900 including a spacer 1902 and deployable retention members 1904. The spacer 1902 includes a split body 1906 having a superior surface 1908 and an inferior surface 1910. The superior surface 1908 and inferior surface 1910 are movably connected to a driver 1912. The driver 1912 has a screw 1914 attached to it and extending from the driver 1912 between the superior surface 1908 and inferior surface 1910 into a threaded bore 1916 in a wedge 1918. In operation, turning the driver 1912 causes the screw 1914 to thread into the bore 1916, which causes the wedge 1918 to move between the superior surface 1908 and the inferior surface 1910. As the wedge 1918 moves further between the surfaces 1908, 1910, the surfaces 1908, 1910 separate to increase the height of the spacer 1902. Combinations of channels 1920 and ribs 1922 provide stabilization for movement of the wedge 1918 relative to the surfaces 1908, 1910. Retention of the spacer 1902 may be accomplished using the coils, flanges, discs, wires and/or other protrusions described above. For example, deployable retention members 1904 in the of form elastic wires that may be folded parallel to the spacer axis 1924 for insertion may provide lateral retention of the spacer 1902.
FIGS. 47-48 illustrate a spinal implant 2000 including a spacer 2002. The spacer 2002 is generally shaped as a cylinder or sleeve having a bore 2004. A gap 2006, or slot, extends the length of spacer 2002. Bore 2004 may be a complete through bore or bore 2004 may allow for a central wall or plug (not shown) for stability. Spinal implant 2000 further comprises end caps 2010 having a generally conical shape or wedge shape. As end caps 2010 are pressed or threaded into bore 2004, the shape of caps 2010 causes the diameter of spacer 2002 to expand, which is allowed because of gap 2006. Gap 2006 could be filled with a suitable elastic material. Alternatively to shaped caps 2010, caps 2010 could be made of an expandable material, such as shape memory alloys, spring steel, resins, polymers or the like to achieve the same result. Lateral retention of the spacer may be accomplished using the coils, flanges, discs, wires and/or other protrusions described above and below and will not be re-described relative to this embodiment.
FIGS. 49-50 illustrate a spinal implant 2100 similar to that of FIGS. 47-48. The spinal implant 2100 has a spacer 2102 in the form of a coiled sheet. The spacer 2102 is moveable from a compact position (FIG. 49) in which the coil winds around itself multiple times and is closer to a spacer axis 2104 to an expanded position (FIG. 50) by uncoiling the spacer such that it winds around itself fewer times and is further from the spacer axis 2104, e.g. such that it forms a single continuous ring. The spacer has inner and outer hook shaped edges 2106, 2108 that can engage as shown in FIG. 50 to limit the amount of expansion of the spacer 2102. The spinal implant 2100 may also include plugs or cores as shown in prior examples to support the spacer 2102 against collapse. Lateral retention of the spacer may be accomplished using the coils, flanges, discs, wires and/or other protrusions described above and below and will not be re-described relative to this embodiment.
FIGS. 51-52 illustrate a spinal implant 2200 similar to that of FIGS. 49-50. The spinal implant 2200 includes a coiled sheet-like spacer 2202 having tabs 2204 projecting away from the sheet to engage slots 2206 to limit the amount of expansion of the spacer 2202. The tabs 2204 and/or slots 2206 may be positioned at the inner and outer edges of the coiled spacer 2202 or they may be positioned at one or more positions intermediate the edges. For example, the spacer may have tabs 2204 at one end and slots placed at multiple locations to allow the spacer to be fixed at different sizes. The spinal implant 2200 may also include plugs or cores as shown in prior examples to support the spacer 2202 against collapse. Lateral retention of the spacer may be accomplished using the coils, flanges, discs, wires and/or other protrusions described above and below and will not be re-described relative to this embodiment.
FIGS. 53-54 illustrate a spinal implant 2300 including a spacer 2302, having a spacer axis 2303, formed of an elastic material, such as a polymer or resin material. For example, the spacer 2302 may be a hydrogel or other composite or polymer material such as a silicone material. A bore 2304 extends through the spacer 2302 into a base 2306. The base 2306 is shown with a wedge or conical shape to facilitate insertion but which could be any shape including rounded or blunt. Deployable retention members in the form of elastic arms 2308 are attached to the base 2306. In use, the base 2306 is inserted between adjacent bones, e.g. spinous processes, parallel to the spacer axis 2303. As the arms 2308 pass the spinous process, they fold into a compact or stowed insertion position in which they are nearer the spacer axis 2303 and lie along the sides of the spacer 2302 generally parallel to the spacer axis (FIG. 53). Once the arms 2308 pass the spinous process, they return to an expanded or deployed retention position in which they project outwardly transverse to the spacer axis 2303 (FIG. 54). Preferably, the arms 2308 only fold in one direction to provide increased retention once inserted. The spinal implant 2300 further includes a plate 2310 having a projection 2312, such as a threaded shaft, extendable through the bore 2304 and threadably engaging the base 2306. Threading, for example, the screw into the base 2306 compresses the spacer 2302 causing the diameter of the spacer 2302 to increase, providing distracting forces on the spinous process. Lateral stability is provided by the plate 2310 and the arms 2308 which extend away from the spacer axis 2303 on either side of the spinous process.
Alternatively to screw threading into the base 2306, a bolt may be attached to the base and the plate 2310 and spacer 2302 compressed with a nut 2314. Other mechanisms could also be used to compress the spacer 2302 including ratchets, press fits, rivets, and/or any other suitable mechanism.
FIGS. 55-57 illustrate a spinal implant 2400 including a base plate 2402 and a wedge plate 2404. The base plate 2402 is shown as having a rectangular shape, but any shape is possible including, circular, elliptical, square, semi-circular, triangular, trapezoidal, random or the like. The base plate 2402 has a through hole 2406 (square in the example shown) and two attachment tabs 2408. The attachment tabs have bores 2410.
The wedge plate 2404 is shown as having a rectangular shape similar to the base plate 2402, but the base plate 2402 and wedge plate 2404 do not necessarily have the same shape. Moreover, the wedge plate 2404 may have numerous possible shapes as explained with reference to the base plate 2402. A wedge protrusion 2414 extends from a first side of the wedge plate 2404. The wedge protrusion 2414 is shown with a generally triangular shape having a straight side, but other shapes are possible including sides that are rounded, beveled, curved, arched, convex, concave, or the like. The wedge protrusion 2414 has a superior surface 2416 and an inferior surface 2418 that generally converge as they travel away from the wedge plate 2404. The wedge protrusion 2414 has a channel bore 2420 extending through a portion of the wedge protrusion 2414. While not necessary and depending on anatomical factors, the channel bore 2420 may be located halfway between the superior surface 2416 and the inferior surface 2418. The wedge protrusion 2414 and through hole 2406 are sized such that the base plate 2402 and wedge plate 2404 can abut, although in the typical implanted configuration, the base plate 2402 and wedge plate 2404 would not in fact abut as the bone, e.g. spinous process, would intervene between the base plate 2402 and wedge plate 2404 as shown in FIG. 57.
As best seen in FIGS. 56 and 57, the bores 2410 on attachment the tabs 2408 generally align with the channel bore 2420 when the wedge protrusion 2414 resides in the through hole 2406 such that a connector 2422 can extend through the bores 2410 and channel bore 2420 to connect the base plate 2402 and wedge plate 2404 during use. Typically, the connector 2422 comprises a screw and nut, but any conventional connector may be used. When first implanted, the base plate 2402 and wedge plate 2404 are aligned about a superior spinous process 2450 and an inferior spinous process 2452. The connector 2422 connects the attachment tabs 2408 and the wedge protrusion 2414. Ideally, but not necessarily, the connector 2422 is not tightened and the base plate 2402 and wedge plate 2404 may move with respect to each other, although in the initial condition they can only move closer together. Once the plates are aligned with the proper distraction, the connector 2422 may be tightened to lock the spinal implant 2400 in place. Ideally, but not necessarily, the supraspinous ligament remains intact to inhibit the spinal implant 2400 from moving posteriorly out of the interspinous process space. Alternatively, and optionally, base plate 2402 and wedge plate 2404 may comprise suture bores 2424 (FIG. 57). A suture 2426 may be connected to the suture bores 2424 and traverse superior the spinous process 2450 and the inferior spinous process 2452. Moreover, while only a pair of bores is shown with a pair of sutures, more may be provided. Moreover, the suture 2426 should be construed generically to refer to cables, wires, bands, or other flexible biocompatible connectors. Such sutures may be tied or locked using a tie, cable lock, or crimp.
FIG. 58 illustrates an alternative spinal implant 2500 similar in form and function to that of FIGS. 55-57. The spinal implant 2500 includes a base plate 2502 and a wedge plate 2504. The base plate 2502 includes an attachment tab 2506 and a bore 2508. The wedge plate 2504 has at least one wedge prong 2510, but two wedge prongs 2510 are provided for improved device stability. The two wedge prongs 2510 form a prong channel 2512 to receive the attachment tab 2506 and provide some additional stability. The wedge prongs 2510 have channel bores 2514. While both the attachment tab 2506 and the wedge prongs 2510 are shown as wedge shaped, both are not necessarily wedge shaped. The bore 2508 and channel bores 2514 align such that a connector 2516 can be fitted between them to couple the base plate 2502 and wedge plate 2504 together. Alternatively, the bore 2508 may be formed as a channel bore and the channel bores 2514 may be formed as a bore or they may all be channel bores to allow for lateral adjustment of the plates.
FIG. 59 illustrates an alternative spinal implant 2600 similar to that of FIG. 58 but instead of bores and connectors, protrusions 2602 are formed inside the prong channel 2604 and on the attachment tab 2606. The protrusions 2602 may be ribs, pins, shoulders, barbs, flanges, divots, detents, channels, grooves, teeth and/or other suitable protrusions. The protrusions 2602 may operate similar to a ratchet mechanism and may be configured so that the base plate and wedge plate can move towards each other and distract adjacent bones, e.g. spinous processes. The protrusions 2602 engage such that the plates do not move apart after they are pressed together. The prong channel 2604 may be widened, e.g. by prying it open, to disengage the protrusions 2602 and allow the plates to be separated.
FIGS. 60-61 illustrate a spinal implant 2700. The spinal implant 2700 includes a spacer having a spacer axis 2701, a first part 2702, and a second part 2704. The first part 2702 has a main body 2706 with a first end 2708 and a second end 2710. One or more lateral walls 2712 extend out from the first part 2702 transverse to the spacer axis 2701 at the first end 2708. The walls 2712 are adapted to extend along a superior and inferior spinous process on a first side. The second end 2710 is adapted to reside in a space between the superior and inferior spinous process. The second part 2704 includes a main body 2714 and has a first end 2716 and a second end 2718. One or more lateral walls 2720 extend out from the second part 2704 transverse to the spacer axis 2701 at the first end 2716. The walls 2720 are adapted to extend along a superior and inferior spinous process on a second side. The second end 2718 is adapted to reside in a space between the superior and inferior spinous process. The lateral wall 2712, 2720 may be shaped to accommodate anatomy. The second end 2710 of the first part 2702 and second end 2718 of second part 2704 abut or engage. A variety of features may be provided to enhance this engagement. For example, the second ends may include one or more channels and/or one or more protrusions that fit in the channels. A set screw or the like may threadably engage a bore extending through the first and second parts to maintain them in alignment. However, as explained below, a set screw and bore are optional. Interlocking channels and protrusions are optional as the ends may just abut or have interfering surfaces. The ends may be sloped transverse to the spacer axis 2701, as shown, to facilitate insertion and/or to increase the abutment area. Some alternate examples will be described below relative to FIGS. 62-67.
Continuing with FIGS. 60-61, one or more through channels or bores 2722 extend through the first and second parts 2702, 2704. A guidewire 2732 extends through the channels 2722 generally parallel to the spacer axis 2701. The guidewire 2732 may be formed of wire, braided or twisted cable (made of metallic or polymer strands), suture material, a flat metallic or polymer band (either braided or solid) and/or other suitable materials and configurations. Multiple through channels may allow the guidewire 2732 to form a loop about the first end 2702 as shown in FIG. 61. The guidewire 2732 ends may be connected around the second end such as with a tie, crimp, knot, twist lock, cable lock, and/or other suitable connections. When the guidewire 2732 is not looped, the guidewire 2732 may be locked against both the first and second ends using a locking device such as a cable lock, crimp, knot, and/or any other suitable locking device. The guidewire 2732 maintains the first and second parts locked together.
FIGS. 62-63 illustrate a spinal implant 2800 similar to that of FIGS. 60-61 except that it includes a protrusion 2804 extending from the second part 2704 to engage a slot 2802 extending from the first part 2702 to stabilize the first and second parts relative to one another.
FIG. 64 illustrates a spinal implant 2900 similar to that of FIGS. 60-61 except that the first part 2702 defines slot 2902 and the second part 2704 tapers to a blade-like nose 2904 that engages the slot 2902.
FIGS. 65-66 illustrate a spinal implant 3000 similar to that of FIGS. 60-6.1 except that the first part 2702 defines tapering side cutouts 3002 separated by a central wedge shaped wall 3004 and the second part 2704 tapers to a wedge shaped second end 3006. The wedge shaped second end is divided by a groove 3008. When the first and second parts are pressed together, the wall 3004 engages the groove 3008 and the wedge shaped second end 3006 engages the side cutouts 3002. Also, in the embodiment of FIGS. 65-66, the first and second parts 2702, 2704 have one or more bores 3010, 3012 transverse to the spacer axis 2701 for receiving a fastener to lock the parts together.
FIG. 67 illustrates a spinal implant 3100 similar to that of FIGS. 60-66 and shown in the implanted condition. The first and second parts 2702, 2704 are secured together with a single guide wire 3102 secured at each end by a crimp 3104. Passageways 3106 are provided through the lateral walls 2712, 2720. Sutures, wires, cables, bands, or other flexible biocompatible material 3108 may extend through the passageways 3106 and over and/or through a spinous process. The flexible biocompatible material 3108 may loop under or over a single process (as shown on the superior process 3110), may loop around a single process (as shown on the inferior process 3112), or may loop around both processes, or a combination thereof. The flexible biocompatible material 3108 may be locked using a locking device similar to those explained above. The flexible biocompatible material 3108 and guidewire 3102 may optionally be the same element.
FIG. 68 is a flowchart describing one exemplary methodology for implanting the spinal implants of FIGS. 60-67. First, the patient is prepared for implanting the spinal implant, step 3202. Preparing the patient may include, for example, making one or more incisions providing access to the spinal segment, placing the guidewire, etc. The surgical site is distracted (or measured as distraction may be caused by the spacer itself) using conventional distraction tools, step 3204. Once exposed, the interspinous process space is prepared to receive the spinal implant, step 3206. This typically includes preparing the spinous processes to accept the spinal implant, which may include removing some portion of the spinous process, and removing muscle, tendons, and ligaments that may interfere with implanting the spinal implant and/or may provide force tending to unseat the spinal implant. The first part of the spinal implant is inserted, over or with the guidewire, to the surgical site through the incision or the like, step 3208. Once at the site, the first part of the spinal implant is positioned or aligned such that the lateral walls are loosely abutting a first side of the superior and inferior spinous processes and the second end extends into the interspinous space, step 3210. Generally, this means that the first part is implanted through the interspinous process space. The guidewire, which is attached to the first part of the spinal implant as explained above extends from the second end of the first part and is attached to the second part of the spinal implant. Thus, the surgeon inserts the second part along the guidewire, step 3212. Note, the first part and second part may be positioned using tools or the surgeon may place the parts using hands and fingers. Using the guidewire, the protrusions (if any) on the second part are inserted into the channels of the first part (if any) to align the first part and second part of the spinal implant, step 3214. Compressive force is applied to mate the first part and the second part, step 3216. The compressive force may be applied by crimping the guidewire, threading a cable lock, a separate clamp, or the like. Once sufficiently compressed, the first part and second part are locked together, step 3218. Optionally, excess guidewire may be cut and removed or looped around the adjacent superior and inferior spinous process to provide secured seating, step 3220. Once mated in the interspinous space, the distraction of the spinal segment may be released, step 3222, and the patient's surgical site may be closed, step 3224.
FIG. 69 illustrates a spinal implant 3300. The spinal implant 3300, includes a superior spinous process seat 3302 and an inferior spinous process seat 3304. As shown, seats 3302 and 3304 form a U and inverted U shape, but other shapes are possible including a square channel shape for each seat, a C-shape, and/or any other suitable shape, although it is believed the saddle shape as shown would work well.
Seat 3302 includes a surface 3306 which contacts the superior spinous process and walls 3308 traversing each side of the superior spinous process to capture superior spinous process in seat 3302. Walls 3308 may be convergent, divergent or relatively parallel. Walls 3308 may be more akin to bumps, ribs, or shoulders to traverse only a minor portion of the spinous process or may be longer to traverse a major portion of the spinous process. Surface 3306 and walls 3308 may be discrete or shaped like a saddle forming a smooth surface in which spinous process can rest. Attached to one wall 3308 is a vertical distraction post 3310 extending towards inferior seat 3304. While only one vertical distraction post 3310 is shown, multiple posts are possible. Moreover, if multiple posts are used, vertical distraction posts 3310 may reside on opposite sides of superior spinous process seat 3302. While shown as a straight post, vertical distraction post 3310 may be curved or straight depending on anatomical considerations or the like.
Similar to seat 3302, seat 3304 includes a surface 3306 which contacts the inferior spinous process and walls 3308 traversing each side of the inferior spinous process to capture inferior spinous process in seat 3304. Attached to one wall 3308, on the side corresponding to vertical distraction post 3310 is an attachment tab 3312. Attachment tab 3312 has a vertical bore 3314 through which vertical distraction post 3310 extends. Seat 3304 can be moved closer to or further from seat 3302 along vertical distraction post 3310. Attachment tab 3312 also comprises a horizontal bore 3316. Horizontal bore 3316 intersects vertical bore 3314. A seating device 3318 is insertable into horizontal bore 3316. As shown horizontal bore 3316 is threaded to accept a set screw or the like.
In use, a surgeon would distract superior and inferior spinous processes and implant spinal implant 3300. Seats 3302 and 3304 would be set at a desired distraction and, for example, set screw 3318 would be threaded into horizontal bore 3316 to apply seating force to seat vertical distraction post 3310 in vertical bore 3314 locking seats 3302 and 3304 at the set distraction distance.
Vertical distraction post 3310 and/or vertical bore 3314 may be arranged with a protrusion 3319 or detent to inhibit the ability of withdrawing vertical distraction post 3310 from vertical bore 3314.
FIG. 70 illustrates alternative seats 3400 and 3402. Seats 3400 and 3402 are designed to nest or interlock. In that regard, seat 3400 has one or more first blades 3404 or multiple surfaces spaced apart so first gaps 3406 separate first blades 3404. Seat 3402 would similarly have one or more second blades 3408 or multiple surfaces. Seat 3402 is shown with a single second blade for convenience. Second plate 3408 is aligned with first gaps 3406 such that seats 3400 and 3402 may nest or interlock. Similarly, first blades 3404 could align with second gaps, not shown. Either first blades 3404 (as shown) or second blade 3408 may attach to a vertical distraction post 3410 and second blade 3408 (as shown) or first blades 3404 may attach to attachment tab 3412.
Although examples of a spinal implant and its use have been described and illustrated in detail, it is to be understood that the same is intended by way of illustration and example only and is not to be taken by way of limitation. The invention has been illustrated in the form of a spinal implant for use in spacing adjacent spinous processes of the human spine. However, the spinal implant may be configured for spacing other portions of the spine or other bones. Accordingly, variations in and modifications to the spinal implant and its use will be apparent to those of ordinary skill in the art. The various illustrative embodiments illustrate alternative configurations of various component parts such as spacers, retention members, additional fasteners, and the like. In most cases, and as will be readily understood by one skilled in the art, the alternative configuration of a component part in one embodiment may be substituted for a similar component part in another embodiment. For example, the differently shaped or expandable spacers in one example may be substituted for a spacer in another example. Likewise the various mechanisms for deploying a retention member or for providing additional fasteners may be interchanged. Furthermore, throughout the exemplary embodiments, where component part mating relationships are illustrated, the gender of the component parts may be reversed as is known in the art within the scope of the invention. The following claims are intended to cover all such modifications and equivalents.
