WO2004107952A2 - Improved vertebral implants adapted for posterior insertion - Google Patents

Abstract

Disclosed is an endoprosthetic implant for a human spinal disc. The structure of the implant allows it to be inserted posteriorly. This insertion is accomplished by performing a partial discectomy in the affected region. An intervertebral space is then created by removing the fibrocartilage between the facing surfaces of adjacent vertebrae. The implant is then inserted into the intervertebral space. The implant is thus adapted to replace damaged or worn intervertebral discs. Furthermore, the structure of the implant, and its posterior insertion, alleviate most spinal pathologies.

Description

IMPROVED VERTEBRAL IMPLANTS ADAPTED FORPOSTERIOR

INSERTION

BACKGROUND OF THE INVENTION

Related Application Data

This application is a continuation-in-part of co-pending application

serial number 10/696,727 filed October 28, 2003 and entitled "Improved

Vertebral Implants Adapted for Posterior Insertion" which is a

continuation-in-part of application serial number 10/449,733 entitled "Vertebral Implant with Dampening Matrix Adapted for Posterior

Insertion" filed on May 30, 2003, which is a continuation-in-part of application serial number 10/021,319 filed December 7, 2001 and entitled

"Vertebral Implant Adapted for Posterior Insertion" (now U.S. Patent 6,572,653). The contents of all prior applications are incorporated herein

by reference.

Field of the Invention

This invention relates to an endoprosthesis to replace an

intervertebral disc. More particularly, the present invention relates to an

endoprosthetic implant that is specifically designed to be inserted posteriorly. Description of the Background Art

The human spine is made up of twenty-four stacked segments called vertebrae. Between adjacent vertebrae are small fibrocartilage cushions called intervertebral discs. These discs act as shock absorbers between adjacent vertebrae and permit the spinal column to bend. As bodily forces

are transmitted along spine, an individual disc can often encounter

hundreds of pounds of force. Spinal forces are also transmitted by way of inferior and superior articular processes that contact each other at facet

joints. Intervertebral discs and facet joints are the two spinal mechanisms by which most spinal forces are transmitted. Consequently, most spinal

pathology occurs at these locations.

For example, the fibrocartilage in the intervertebral discs often

becomes worn or damaged through wear, age and/or disease. This damage

limits spinal movements and can also result in pain as nerves become

pinched and swollen. Damaged fibrocartilage, in turn, increases the

pressure that is otherwise encountered by the facet joint adjacent the disc.

This causes a premature wearing of the bone that makes up the joint.

Again, limited spinal movement and pain result.

One of the oldest methods of repairing damaged intervertebral discs

involves fusing adjacent vertebrae by way of a bone graft. Such methods, however, have serious drawbacks in that the resulting fused vertebrae

limit the overall movement of the spine. Furthermore, once two vertebrae

are fused, the pressures encountered by adjacent healthy discs is increased. This dramatically increases the likelihood that such healthy

discs may become damaged and worn. Thus, the fusing of vertebrae often propagates the malady it seeks to cure. Prosthetics are also employed to alleviate damaged intervertebral

discs. This involves the removal of damaged fibrocartilage. The

fibrocartilage is then replaced by an implant, typically formed from an

elastomeric or an elastomeric composite. Prosthetic implants have the

benefit of providing a more full range of spinal movement over fusion processes. Nonetheless, the elastomerics typically wear out over the life of

the prosthetic. As a result additional medical procedures are required to

replace the worn out prosthetic. Even prior to wearing out, elastomerics

may simply wear unevenly, whereby the prosthetic provides an uneven

resilient force between the vertebrae. This causes nerves to become

pinched and swollen. Absent any type of wearing, elastomerics do not

provide a cushioning effect that is equivalent to naturally occurring fibrocartilage. Forces not absorbed by the elastomeric are then

transferred to the adjacent facet joint. This results in premature wearing

of the joint.

An example of a synthetic intervertebral disc is disclosed by U.S.

Patent 5,458,642 to Beer, et al. Beer discloses the use of a synthetic

intervertebral disc for implantation in the human body. The synthetic disc includes a polymeric core that is inserted between two plates. Spring means are included in addition to the polymeric core. Each of the plates

includes a tab that is secured to a vertebrae via a screw. Additionally, U.S. Patent 6,231,609 to Mehdizadeh discloses a disc

replacement prosthesis. The prosthesis includes screw threads which

engage the vertebrae. A vertical stiffness is obtained from a series of coil

springs affixed between upper an lower rigid members. The coil springs

also provide assistance in resisting shear forces.

U.S. Patent 5,556,431 to Bύttner-Janz discloses an intervertebral

disc endoprosthesis. The prosthesis includes two plates intermediate

which a prosthesis core is included. The prosthesis core is made from a

polyethylene. Bone screws are utilized in securing the two plates.

U.S. Patent 5,824,093 to Ray discloses a prosthetic spinal disc

nucleus employing a hydrogel core surrounded by a constraining jacket.

Finally, U.S. Patent 6,156,067 to Bryan, et al discloses a spinal disc

endoprosthesis with concave surfaces. A resilient body is included intermediate the two surfaces.

_t Although each of the above-referenced inventions achieves its

individual objective they all suffer from common problems. Namely, none

of the background art discloses an endoprosthesis which is specifically designed to be inserted posteriorly to thereby eliminate the most common source of spinal pathology. SUMMARY OF THE INVENTION

It is therefore one of the objectives of this invention to provide an intervertebral disc endoprosthesis which is specifically adapted to be

inserted posteriorly.

It is also an object of this invention to provide an intervertebral

endoprosthesis which utilizes a mechanical spring to achieve a longer

wear life and accommodate increased intervertebral forces.

Still another object of this invention is to provide an endoprosthesis

which substantially eliminates most posterior spinal pathology.

Yet another object of this invention is to provide an endoprosthesis

which eliminates the need for facet joints.

These and other objectives are accomplished by providing a vertebral implant adapted for posterior insertion and designed to replace

the fibrocartilage between the facing surfaces of adjacent superior and

inferior lumbar vertebrae. The implant includes two pairs of

hydroxyapatite coated superior and inferior supports. Each support includes plate and lip portions. The lip portion is formed at a right angle

to the plate portion. In the case of the inferior support the lip portion is

offset to one side. The plate portion of each support further includes a plurality of teeth, a retainer, and a pair of tapering side edges. Each plate portion is received within a channel formed within one of the facing surfaces of the superior or inferior vertebrae such that the lip portions abut the posterior edge of the vertebrae. In the case of the inferior

support, the offset lip accommodates a vertebral pedical.

The implant additionally includes a pair of springs. Each spring is

formed from a plurality of oblong tapered coils. Each spring is positioned

between the side edges of opposing superior and inferior supports with the

position of the spring being fixed by the opposing retainers. Each spring

has an axial force under compression that functions to drive the teeth of

the opposing superior and inferior supports into the facing surfaces of the

adjacent vertebrae.

The foregoing has outlined rather broadly the more pertinent and

important features of the present invention in order that the detailed

description of the invention that follows may be better understood so that the present contribution to the art can be more fully appreciated.

Additional features of the invention will be described hereinafter which

form the subject of the claims of the invention. It should be appreciated by

those skilled in the art that the conception and the specific embodiment

disclosed may be readily utilized as a basis for modifying or designing

other structures for carrying out the same purposes of the present

invention. It should also be realized by those skilled in the art that such equivalent constructions do not depart from the spirit and scope of the invention as set forth in the appended claims. BRIEF DESCRIPTION OF THE DRAWINGS

For a fuller understanding of the nature and objects of the

invention, reference should be had to the following detailed description

taken in connection with the accompanying drawings in which:

Fig. 1 is a posterior view of the lumbar region of a human

spine;

Fig. 2 is a detailed illustration taken from Figure 1;

Fig. 3 is a side elevational view of the implant of the present

invention fully inserted and is taken from line 3-3 of Figure 2;

Fig. 4 is a cross-sectional view taken from line 4-4 of Figure

2; '

Fig. 5 is a top plan view of the superior support;

Fig. 6 is a side elevational view of one of the superior

supports;

Fig. 7 is a bottom plan view of one of the superior supports;

Fig. 8 is an end view taken along line 8-8 of Figure 6;

Fig. 9 is an end view of one of the inferior supports;

Fig. 10 is an end view of one of the inferior supports;

Fig. 11 is a side elevational view of one of the springs;

Fig. 12 is a plan view of one of the springs;

Fig. 13 is an exploded view of the implant system of the present invention; ι Fig. 14 is an alternative embodiment of the implant of the

present invention; and

Fig. 15 is a view taken from line 15-15 of Figure 14.

Fig. 16 is a detailed view taken from Fig. 1 of an alternative

implant system of the present invention.

Fig. 17 is a side elevational view of alternative embodiment

depicted in Fig. 16.

Fig. 18 is a top plan view taken along line 18-18 of Fig. 17.

Fig. 19 is a sectional view taken along line 19-19 of Fig. 18.

Fig. 20 is a sectional view of a lipless embodiment of the

present invention.

<> Fig. 21 is a sectional view taken along line 21-21 of Fig. 20.

Fig. 22 is a posterior view of a screw shell embodiment of the

present invention.

Fig. 23 is a sectional view taken along line 23-23 of Fig. 22.

Fig. 24 is a detailed view of one of the supports depicted in

Fig. 22.

Fig. 25 is a view taken along line 25-25 of Fig. 24. Fig. 26 is a view taken along line 26-26 of Fig. 24. Fig. 27 is a detailed view of the offset lip of one of the inferior supports. Fig. 28 is an end view of one of the screws employed in the

screw shell embodiment.

Fig. 29 is a side elevational view of the screw of Fig. 28.

Fig. 30 is a detailed view of the screw shell depicted in Fig.

23.

Fig. 31 is an end view of the screw shell taken along line 31-

31 of Fig. 30.

Fig. 32 is an exploded view illustrating the screw prior to

insertion into the screw shell.

Fig. 33 is a posterior view of yet another alternative screw

shell embodiment.

Fig. 34 is a sectional view taken along line 34-34 of Fig. 33.

Fig. 35 is posterior view of a rocker embodiment of the

present invention.

Fig. 36 is a sectional view taken along line 36-36 of Fig. 35.

Fig. 37 is a detailed view of one of the superior bearing surfaces of the embodiment depicted in Fig. 35.

Fig. 38 is a side elevational view taken along line 38-38 of

Fig. 37.

Fig. 39 is a detailed view of one of the inferior cups of the rocker embodiment depicted in Fig. 35. Fig. 40 is a side elevational view of the cup taken along line

40-40 of Fig. 39.

Similar reference characters refer to similar parts throughout

the several views of the drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The present invention relates to an endoprosthetic implant for a

human spinal disc. The structure of the implant allows it to be inserted

posteriorly. This insertion is accomplished by performing a partial

discectomy in the affected region. An intervertebral space is then created

by removing the fibrocartilage between the facing surfaces of adjacent vertebrae. The implant is then inserted into the intervertebral space. The

implant is thus adapted to replace damaged or worn intervertebral discs.

Furthermore, the structure of the implant, and its posterior insertion,

alleviate most spinal pathologies. The implant of the present invention,

and the manner in which it is employed, are described in fuller detail hereinafter.

With reference now to Figure 1, a posterior view of the lumbar

region of a human spine is depicted. The implant of the present invention 20 is specifically adapted for insertion between adjacent vertebrae in this lumbar region, specifically vertebrae L3 through SI. Figure 1 illustrates some spinal anatomy including: the spinous process 22; the superior and inferior articular process (24 and 26, respectively); the transverse process

28; pedicals 32 and facet joints 34. Figure 1 also illustrates a dissected

area with the spinous process 22 and superior and inferior articular

processes (24 and 26) removed. This discectomy allows for the insertion of the implant 20 of the present invention in a manner more fully described

hereinafter.

Figure 2 illustrates the implant 20 positioned between facing

surfaces of adjacent superior and inferior lumbar vertebrae (36 and 38,

respectively). The implant 20 includes: an upper, or superior, pair of

supports 44; a lower, or inferior, pair of supports 46; and two springs 48.

As illustrated, each spring 48 is positioned between aligned opposing

superior and inferior supports (44 and 46). Thus, an individual support

column 50 is defined by a superior and inferior support (44 and 46)

interconnected by a spring 48. The preferred form of the implant includes two support columns 50. However, the use of other numbers of columns,

such as one or three, is within the scope of the present invention.

Each superior support 44 is defined by: first and second ends (52

and 54); a cantilevered plate portion 56; and a lip portion 58. The plate portion 56 is cantilevered with the first end 52 being integral with the lip portion 58 and the second end 54 being free. This arrangement allows the plate 56 to pivot with respect to the sides of the support. With reference now to Figure 4, the relationship between the lip and plate portion (58 and 56) of a superior support 44 is depicted. Specifically, in the preferred

embodiment, the lip portion 58 is formed at generally a right angle to the

plate portion 56 at a first end 52 of the support 44. However, the exact

angle between the lip portion 58 and the plate portion 56 varies due to the

cantilevered nature of the plate. With continuing reference to Figure 4,

the teeth 62 of the plate portion 56 are depicted. These teeth 62 are

formed by partially perforating the plate 56 to create protrusions which rise above the planer surface of the surrounding support 44. The teeth are

preferably formed a 90 degree angle with the plate portion 56. The teeth

62 enable support 44 to engage the vertebral body in a manner more fully

described hereinafter. Thus, although the teeth 62 have been described as

perforations, they could be formed in a variety of different ways. For example, the teeth 62 could take the form of sharpened protrubences that

are fixed to an outer surface of the plate 56, such as by welding. Additionally, the teeth 62 can be arranged in a number of different

positions, other than the aligned orientation depicted. In the unbiased

state of plate 56, the bottom of teeth 62 are flush with the bottom edge of

the support 44 (note Figure 6). The plate 56 further includes a retainer 64

formed in a manner similar to the teeth 62. Again, the retainer 64 is formed by perforating the plate portion 56 to create a raised protrusion. The retainer 64 functions in constraining the spring 48 positioned between the facing supports (44 and 46). Thus, the teeth 62 are raised in a direction opposite to the direction in which the retainer 64 is raised. That

is, the teeth 62 are raised in the same direction of the lip 58, and the

retainer 64 is raised in the opposite direction.

Figures 5 through 7 are more detailed showings of the superior supports 44. As can be appreciated from these figures, the superior

supports 44 further include raised side edges 66 which taper along the

length of the support 44. That is, the side edges 66 are taller at the second

end 54 of the support and taper toward the first end 52 of the support until the edges are planar with the plate portion 56. The raised side edges

66, along with the retainer 64, function in locking the spring 48 into

position between opposing supports (44 and 46). Furthermore, due to the

cantilevered nature of the plate 56, the side edges 66 are not connected with the edges of the plate 56.

With reference now to Figure 4, the lower, or inferior supports 46,

are described. In most respects, the inferior supports 46 are identical to

the superior supports 44. That is, the inferior supports 46 are each

defined by a first and second end (68 and 72), a cantilevered plate portion

74, and a lip portion 76. Again, the lip portion 76 is generally formed at a right angle to the plate portion 74 at the first end 68 of the support 46. Furthermore,¹ the plate portion 74 includes a plurality of teeth 78 and a retainer 82, both of which are formed in the manner described in association with the superior support 44. Each of the inferior supports 46 similarly include raised side edges 84 which taper from the second 72 to

the first end 68 of the support 46.

With reference now to Figures 9 through 10, the primary difference

between the superior and inferior supports (44 and 46) will be described.

That is, the lip 76 of the inferior support 46 is offset. More specifically, the lip portion 76 extends over only a portion of the width of the support 46.

In the preferred embodiment depicted, the lip 76 extends over

approximately half of the width of the support 46. As such, the lip portion

76 is offset to one side. Furthermore, with the support 46 positioned on

the vertebrae, the adjacent lips 76 are preferably oriented toward the

medial portion of the vertebrae. This offset lip portion 76 is contrasted to

the lips 58 of the superior supports 44 which extend across the entire

width of the support 44 (note Figure 8). Thus, the lips 58 of the superior

supports 44 are not offset.

The exact manner in which the supports (44 and 46) are positioned

upon the facing surfaces of the opposing vertebrae is next described in

conjunction with the exploded view of Figure 13. As illustrated, the two superior supports 44 are secured to the surface 86 of the superior

vertebrae 36, and the inferior supports 46 are secured to the facing surface 88 of the inferior vertebrae 38. More specifically, the two superior supports 44 are received within channels 92 that are formed within the inferior surface 86 of the superior vertebrae 36. These channels 92 are preferably formed after the medical practitioner has conducted the partial

discectomy. The channels 92 are ideally dimensioned to specifically receive the width of the supports 44 and are relatively shallow when

compared to the overall height of the support 44. The channels 92 aid in

orienting the supports 44 and limiting their movement once positioned. After the channels 92 are formed the superior supports 44 are inserted

over the surface 86 of the superior vertebrae 36. This is done with the

teeth 62 and lips 58 directed toward the vertebral body. However, at this

stage the teeth 62 do not engage the vertebral body 36, insomuch as the

plate 56 is unbiased and the teeth 62 are flush with the lower surface of

the support. As the supports 44 are pushed forward, the lip 58 of each support 44 will abut the posterior edge 94 of the vertebrae 36, which

functions to properly orient the supports 44 relative to the vertebral body

36. That is, each lip 58 ensures that its corresponding support 44 does not

extend too far onto the vertebral body 36.

The above described insertion is repeated for the inferior supports

46. That is, the inferior supports 46 are inserted within channels 96

formed within the facing superior surface 88 of the inferior vertebrae 38. Again, with the supports 46 inserted, the teeth 78 do not engage the vertebral body 38. After the discectomy, the inferior vertebrae 38 will have remaining pedicles 32 preventing insertion of a support with a full

lip. Thus, the lower supports 46 include the offset lip 76 that accommodates the vertebral pedicle 32. Nonetheless, each offset lip 76

still functions in limiting the insertion of its corresponding support 46 into

the corresponding channel 96.

The implant further includes springs 48 which are engaged between

the facing superior and inferior supports (44 and 46) as illustrated clearly

in Figure 13. Each support column 50 includes one spring 48, with two

springs 48 being employed when two support columns 50 are used. In preferred embodiment, each of these springs 48 is a coil spring formed

from a plurality of oblong coils. It has been found that the use of coil

springs increases the life of the implant over elastomeric spring members.

Preferably, each spring 48 is tapered from a second to a first end. This spring geometry is illustrated in Figure 11. Furthermore, Figure 12 is a

plan view of the spring 48 showing its oblong or elongated shape. The

resulting free-standing orientation of the spring provides a narrower

posterior profile 98 and a wider anterior profile 102. This, in turn, insures

that the spring 48, when inserted, provides proper spinal curvature.

With reference again to Figure 13, the positioning of the springs 48

between the supports (44 and 46) is described. Specifically, each spring 48

is positioned such that the narrower end is adjacent the posterior edge of the spine and the wider end is adjacent the anterior edge of the spine. As indicated, this provides for proper spinal curvature with the implant fully inserted. Each of the springs 48 is held in place by opposing superior and inferior supports (44 and 46), and further by the upstanding side walls of

such supports (66 and 84) and their retainer portions (64 and 82). More

specifically, the side walls prevent the lateral movement of the spring 48

and the retainer (64 or 82) precludes the spring from moving longitudinally. When properly positioned, the springs 48 are under

compression and generate an axial force that serves to pivot the

cantilevered plates 56 and 74 away from their corresponding supports 44

and 46. As a consequence, the teeth 62 and 78 are forced into the

vertebral bodies (36 and 38). This prevents any lateral migration of the supports. When fully positioned the springs absorb the forces between the

superior and inferior vertebrae (36 and 38) and take the place of the otherwise existing fibrocartilage.

Method of Insertion

The method by which the implant of the present invention is

inserted is next described. In the first step a partial discectomy is

performed in order to gain posterior access to the damaged area. This

discectomy involves removing the spinous process 22 and inferior articular

process 26 from the superior vertebrae 36. The superior articular process

24 is also removed from the inferior vertebrae 38. This exposes the thecal sac, which is moved to gain access to the fibrocartilage. Next, the damaged fibrocartilage is removed to create an intervertebral space. This space provides access to the opposing vertebrae surfaces (86 and 88). Once the space is created the upper and lower channels (92 and 96) can be

formed. Specifically, two oblong channels 92 are formed within the

surface 86 of the superior vertebrae 36, and two oblong channels 96 are

formed within the face 88 of the inferior vertebrae 38. These channels (92 and 96) are formed in facing relation to one another. Thereafter, the two

superior supports 44 are inserted into the channels 92 with the lips 58 functioning to limit the insertion and otherwise properly orient the

supports 44. The inferior supports 46 are then likewise positioned with

the offset lips 76 engaging the remaining pedicles 32 on the inferior

vertebrae 38. Lastly, the two springs 48 are inserted. More specifically,

the first spring 48 is inserted intermediate the opposing superior and

inferior supports (44 and 46) and the second spring 48 is inserted between

the remaining opposing superior and inferior supports (44 and 46). In each instance, insertion of the spring causes the teeth to engage the vertebral body via action of the cantilevered plate.

Figures 14 and 15 illustrate yet another embodiment of the present

invention. This embodiment is similar in most respects to the previously

described embodiment. However, the two inferior supports 46 are each provided with a channel 104 formed along an interior edge. These channels 104 are adapted to receive the sides of a spacer 106. That is, the opposing edges 108 of the spacer 106 are inserted within the facing channels 104 of the inferior supports 46. This spacer 106 operates to absorb any forces that would tend to operate individually on the supports

46. Consequently, the spacer 106 functions in tying the two supports 46

together such that they operate as an integral unit. The spacer 106 is

preferably positioned intermediate the channels 104 prior to insertion over

the vertebral body.

All of the components of the above-described invention, that is the

superior and inferior supports (44 and 46), and the springs 48 as well as the spacer 106, are preferably formed from a titanium alloy or a stainless

steel. Furthermore, each of these components is preferably coated with a

hydroxyapatite to promote bone growth about the components when in

place.

Dampening Matrices (Figures 16-19)

An alternative embodiment of the present invention is depicted in

Figs. 16-19. This alternative embodiment employs many of the same components discussed with reference to Figs. 1 through 15, as such similar

reference numerals are used to note similar components. However this alternative embodiment further includes two dampening matrices 120.

Each matrix 120 utilizes an identical construction and is positioned between the superior and inferior supports (44 and 46) of the implant. The dampening matrices each act as a cushion between the adjacent superior and inferior lumbar vertebrae (36 and 38, respectively.) Accordingly, when the opposing vertebrae are compressed the matrices slow the rate of compression and absorb the forces and loads encountered

by the spinal tract. As noted below, this is achieved by the hydrogel core

122 contained within each matrix.

Once the load is removed, resilient columns (or springs) provide a

return energy to reposition the adjacent vertebrae. This repositioning is achieved in the absence of loads upon the vertebral tract. In the preferred

embodiment, each of the resilient columns is positioned over and

surrounds an associated dampening matrix. This arrangement is depicted

in Fig. 17.

In the preferred embodiment the dampening matrix is constructed

from a hydrogel core positioned within a constraining jacket. This construction is similar to the prosthetic spinal disc nucleus disclosed in

U.S. Patent 5,824,093 to Ray, the contents of which are incorporated

herein by reference. As noted in Ray '093, the hydrogel core is formed as a

mixture of hydrogel polyacrylonitrile. In particular, acrylamide and

acrylonitrile are used. Furthermore the constraining jacket is preferably a closed sack of a tightly woven high molecular weight high tenacity

polymerac fabric. The jacket preferably contains openings that are large enough to allow bodily fluids to react with the hydrogel core, but are small enough to prevent the hydrogel from escaping. Thus the hydrogel, which

has an affinity for imbibing water, will deform and reform as necessary in order to accommodate and alleviate stresses and loads placed on the spinal tract. Figure 19 is a cross sectional view illustrating the hydrogel core of

the present invention.

After any loads applied to the hydrogel core are removed the

resilient columns then return the opposing vertebrae to their proper orientation. In this regard, the preferred resilient column has been

disclosed as a spring 48. However any other resilient tensioning devices

known in the art can be employed. For example, the column can be

formed from a leaf spring, coil spring, resilient coiled polymer or a

continuous polymer sleeve.

Lipless Embodiment (Figures 20-21)

The embodiment depicted in Figures 20-21 is the same in most

respects to the implant described in conjunction with Figs. 2 through 13. The notable difference, however, is that the superior and inferior supports

(132 and 134) have no lip portions hanging over the posterior end of the

upper and lower vertebral bodies. Consequently, as illustrated in Fig. 21,

the first ends 136 of the superior and inferior supports (132 and 134) terminate adjacent the respective vertebral bodies. This "lipless"

embodiment is advantageous because when the implants are fully inserted

the supports are unexposed. This embodiment also weighs less than the embodiment of Figs. 2-13.

Nonetheless, in this lipless embodiment there are no portions of the supports that overhang to prevent the supports from extending too far towards the anterior end of the vertebral bodies. That is, there are no lips

to prevent the over insertion of the support. Rather, the correct orientation between an individual support and its corresponding vertebral

surface is achieved via channels 138 formed within the vertebral surfaces and teeth 142 formed within each support. These features ensure a

positive fit between vertebrae and prevent over insertion.

In all other respects, the lipless embodiment is the same as the

embodiment depicted in Figs. 2-13. That is, both the superior and inferior

supports (132 and 134) include a cantilevered lower surface 144 into which

a retainer 146 and a series of teeth 142 are formed. Each support further

includes tapering side edges 148. Insertion is achieved by performing a

discectomy to create an intervertebral space as noted in conjunction with

the primary embodiment. Thereafter, upper and lower channels 138 are

formed in the surfaces of the vertebral body, with the supports being positioned within these channels. Thereafter, springs 152 are inserted

bilaterally between the pair of superior and inferior supports (132 and

134). Again, as noted in conjunction with the primary embodiment, each

retainer 146 functions in preventing the movement of the spring 152. Screw Shell Embodiment (Figures 22-34)

The next embodiment is described in conjunction with Figs. 22-34. As with the primary embodiment, this embodiment includes two superior

supports and two inferior supports (154 and 156, respectively) that are positioned bilaterally in an intervertebral space. In this embodiment, two

rounded inserts are secured between the supports. These inserts are

interconnected by way of a screw. Thus, each pair of inserts takes on a

"screw shell" configuration.

The intervertebral space is again created in the manner described

in conjunction with the primary embodiment. Namely, a discectomy is

performed and two superior channels and two inferior channels are formed in the opposing faces of the intervertebral space. After the space is

created, the superior and inferior supports (154 and 156) are inserted into

these channels. As with the supports in the primary embodiment, the

supports in the screw shell embodiment preferably include lips to limit their insertion into the intervertebral space. Specifically, the superior

supports 154 include full-width lips 158 that are dimensioned to engage

the entire corresponding edge, of the superior vertebrae. The inferior

supports 156 likewise include offset lips 162 as depicted in Fig. 22. These

lips 162 encompass only a portion of the support width. In the preferred embodiment, the lips 162 extend over approximately one-half of the width

of the support and are oriented towards the medial portion of the

vertebrae. With this configuration, the inferior lips 162 accommodate the pedicles (which may be partially dissected) extending from the posterior face of the vertebrae. Furthermore, as noted in Fig. 23, both the superior and inferior supports (154 and 156) can further include interior lips located at the second ends of each support that prevent over insertion of

the screw shell.

The supports of this embodiment differ from the primary

embodiment in that they each include a trough 164 formed along their

lengths. This trough, which is illustrated in Fig. 24, takes the form of an

arcuate segment, which is removed from the body of the support.

Additionally, unlike the primary embodiment, the supports of the screw-

shell embodiment have neither a cantilevered floor or teeth. These arcuate portions of the supports permit proper placement of the screw

shell inserts. That is, with the supports properly positioned in facing

relation, adjacent upper and lower troughs 164 form opposing arcuate

surfaces that are dimensioned to accommodate the upper and lower

inserts (166 and 168, respectively)(note Fig. 23). The arcuate upper and lower inserts (166 and 168), in turn, form a single shell 172. Two such

shells 172 are bilaterally positioned within the intervertebral space (note

Fig. 22).

The upper and lower inserts (166 and 168) are preferably interconnected by way of a screw 174. The interconnection is achieved by

threading the internal surfaces of the inserts in a manner that permits a screw to be threadably positioned between the upper and lower inserts. This configuration allows for the lateral movement of the screw 174 between either end of the screw shell 172 upon screw rotation. To enable the screw 174 to be threaded into and out of the screw shell 172, each

includes a hexagonal opening 176 at its end to facilitate physician rotation

of the screw via a matching key.

With continuing reference to Fig. 23, the arcuate upper and lower

portions of the screw shell are depicted. This cross-sectional view

illustrates the threaded internal surfaces of the inserts (166 and 168) and

how they cooperate with a screw 174. The cross-section further illustrates

how the arcuate portions of the inserts conform to the troughs 164 of the

superior and inferior supports (154 and 156). In the preferred

embodiment, the inserts are not permanently affixed to the corresponding

support, but rather simply rest within the corresponding trough.

With reference now to Fig. 30, it can be seen that the anterior end 178 of each insert is enlarged with respect to the posterior end.

Accordingly, when the inserts (166 and 168) are positioned between the

supports (154 and 156) prior to screw insertion, the enlarged anterior

portions promote a lordosis of the spine. This configuration also provides

for an enlarged posterior opening of the resulting screw shell and a

narrowed anterior opening. This "steady state" configuration can be subsequently overcome by inserting a screw into the threaded interior of the screw shell. Specifically, by driving a screw 174 from the posterior to

the anterior region of the screw shell 172 the narrowed anterior opening of the screw shell is widened to thereby correct the lordosis (note Fig. 23). Proper spinal curvature is promoted by full insertion of the screw shell.

Full screw insertion represents the final surgical step.

In an alternative embodiment of the screw shell, the lips of the

superior and inferior supports (154 and 156) are removed. In this embodiment, depicted in Figs. 33-34, when the supports are inserted in the intervertebral space, their posterior edges are flush with the adjacent

vertebral bodies. Yet in another alternative construction, the screw

positioned between adjacent inserts is replaced by a helical spring 182.

This is similar to the prior embodiment, however, the spring has the

advantage of both interconnecting the facing inserts and providing

resistance. As with the prior embodiment, each support would have an

interior surface that accommodates the periphery of the spring 182.

Rocker Embodiment (Figures 35-40)

The final embodiment is depicted in conjunction with Figs. 35-40. This embodiment again includes superior and inferior supports 186, which

are positioned within the opposing surfaces in the intervertebral space.

However, in this embodiment, the supports 186 are fitted into channels

184 that are both deepened and made more narrow. These channels 184 accommodate a rail 188 running along the lower surface of each support 186. It has been found that this rail 188 promotes a stable interconnection

between the support and vertebral surface. Also, as is known in the art, the supports may include a hydroxoyappetite coating to facilitate bone

growth.

Upon each of the superior supports, an arcuate bearing surface 192

is secured. This interconnection can be achieved via a suitable adhesive or mechanical fastener. This bearing surface 192 is preferably formed from a

suitable metallic or polyethylene material. Concave receptacles 194, which are also formed from a metallic or polyethylene material, are

similarly secured to the inferior supports. The receptacles 194 are

dimensioned to accommodate each of the superior bearing surfaces 192.

In this manner, once these supports are secured, the interaction between

the bearing surfaces and the cups allows for a limited posterior and anterior range of motion, while at the same time limiting lateral motion.

The present disclosure includes that contained in the appended

claims, as well as that of the foregoing description. Although this

invention has been described in its preferred form with a certain degree of particularity, it is understood that the present disclosure of the preferred

form has been made only by way of example and that numerous changes

in the details of construction and the combination and arrangement of

parts may be resorted to without departing from the spirit and scope of the invention.

Now that the invention has been described,

Claims

WHAT IS CLAIMED IS

1. A vertebral implant for insertion between adjacent vertebrae

having anterior and posterior faces comprising:

a superior support positioned upon a vertebral surface, the superior

support having a posterior edge which is flush with a posterior vertebral

face, the superior support having an arcuate trough formed therein;

an inferior support positioned upon a vertebral surface in facing

relation to the superior support such that a posterior edge of the inferior

support is flush with a posterior vertebral face, the interior support^' having an arcuate trough formed therein;

a two part shell positioned intermediate the superior and inferior supports, the two part shell having arcuate upper and lower surfaces that

correspond to the arcuate troughs formed within the superior and inferior supports;

a threaded screw positioned within the two part shell, rotation of

the screw causing its lateral movement to thereby adjust the spacing between the two parts of the shell.

2. A vertebral implant for insertion into an intervertebral space

having anterior and posterior areas comprising: superior and inferior supports positioned upon a vertebral surface

in facing relation to one another, both supports being positioned in the

posterior area of the intervertabral space;

an insert positioned intermediate the superior and inferior

supports, the insert adapted to absorb forces generated in the intervertebral space.

3. The implant as described in claim 2 wherein the insert is

formed from upper and lower portions.

4. The implant as described in claim 3 wherein the upper and

lower portions are interconnected via a threaded element, wherein

movement of the threaded element causes relative movement of the upper

and lower portions.

5. The implant as described in claim 2 wherein the superior and inferior supports each include lips that are adapted to hang over an edge of the vertebral body.

6. A vertebral implant specifically adapted for posterior

insertion comprising: a superior support positioned upon a vertebral surface, the superior

support having a posterior edge which is flush with a posterior vertebral

face; an inferior support positioned upon a vertebral surface in facing

relation to the superior support such that a posterior edge of the inferior

support is flush with a posterior vertebral face;

a member positioned intermediate the superior and inferior

supports.

7. The vertebral implant as described in claim 6 wherein the member is in the form of a shell with arcuate upper and lower portions.

8. The vertebral implant as described in claim 6 wherein the

member is a dampening matrix.

9. The vertebral implant as described in claim 6 wherein the

superior and inferior supports include an overhanging lip portion.

10. The vertebral implant as described in claim 6 wherein a spring is positioned between the superior and inferior supports.