CROSS-REFERENCE TO RELATED APPLICATIONSThis application is a continuation of U.S. patent application Ser. No. 13/290, 358, filed Nov. 7, 2011, which is a continuation of U.S. patent application Ser. No. 12/767,100, filed Apr. 26, 2010, now issued as U.S. Pat. No. 8,066,745, which is a continuation of U.S. patent application Ser. No. 11/193,523, filed Jul. 29, 2005, now issued as U.S. Pat. No. 7,717,943, which are incorporated herein by reference and made a part hereof.
BACKGROUND OF THE INVENTION1. Field of the Invention
This invention relates to a capless multiaxial screw and spinal fixation assembly and method, particularly useful for fixing and/or aligning vertebrae of the spine. The invention permits multiple angular orientations of an elongated member or rod with respect to a screw that is screwed into a vertebra.
2. Description of the Related Art
Various methods of spinal immobilization have been known and used in the past. The preferred treatment for spinal stabilization is immobilization of the joint by surgical fusion or anthrodesis. This method has been known since development in 1911 by Hibbs and Albe. However, in many cases, in particular cases involving fusion across the lumbosacral articulation and where there are many levels involved, pseudorarthrosis is a problem. It was discovered that immediate immobilization was necessary in order to allow a bony union to form. Post operative external immobilization, such as the use of splints and casts, was a favored method of treatment, however, as surgical techniques have become more sophisticated, various methods of internal and external fixation have been developed.
Internal fixation refers to therapeutic methods of stabilization which are wholly internal to the patient and include commonly known devices such as bone plates and pins. External fixation, in contrast, involves at least some portion of stabilization device which is external to the patient's body. Internal fixation is now the favored method of immobilization because the patient is allowed greater freedom with the elimination of the external portion of the device and the possibility of infection, such as a pin tract infection is reduced.
There have been numerous systems and methods developed in the past for correcting and stabilizing and aligning the spine for facilitating, for example, fusion at various levels or areas of the spine, such as those devices are shown in U.S. Pat. Nos. 4,085,744; 4,269,178; 4,805,602; 5,466,237; 5,474,555; 5,891,145; and 6,869,433 B2. Bone screws with a polyaxial head are commonly used in spine surgery today. They are used chiefly in the lumbar spine and screwed into bone (pedicle) posteriorly. The head of the screw is attached to the shaft of the screw by means of a ball and socket. The top of the screw is machined into a ball, and the head contains a socket into which the ball fits. The screw head further contains a receiver for receiving a separate rod. The rod is fastened to the screw head receiver via a threaded cap. The rod is then fastened to screws placed in adjacent vertebrae thus providing stabilization. The polyaxial head allows the rod to be placed in a variety of angles with respect to the screw allowing conformance to local anatomy.
When the threaded cap is tightened upon the rod, a frictional pressure is transmitted from the threaded cap to the rod thence to the top of the ball, thus locking the ball-in-socket and preventing motion after tightening has occurred. This concept is demonstrated in U.S. Pat. Nos. 5,466,237 and 5,474,555, which illustrate this type of screw.
U.S. Pat. No. 5,466,237 to Bird et al. discloses a bone screw having a spherical projection on the top of the bone screw. An externally threaded receiver member supports the bone screw and spinal rod on top of the spherical projection. An outer nut is tightened onto the receiver member to press the spinal rod against the spherical projection to accommodate various angular orientations of the bone screw relative to the rod.
In another approach shown in U.S. Pat. No. 4,946,458 to Harms, a spherical headed bone screw supported within separate halves of a receiving member. The bottom of the halves are held together by a retaining ring. The top of the receiver halves are compressed about the bone screw by nuts threaded onto a threaded spinal rod.
In still another approach taken by Harms et al. in U.S. Pat. No. 5,207,678, a receiver member is flexibly connected about a partially spherical head of a bone screw. Conical nuts on opposite sides of the receiver member threaded onto a threaded rod passing through the receiver. As the conical nuts are threaded toward each other, the receiver member flexibly compresses around the head of the bone screw to clamp the bone screw in its variable angular position. One detriment of the systems in the two Harms et al. patents is that the spinal rod must be threaded in order to accept the compression nuts.
U.S. Pat. No. 6,869,433 discloses the use of a pedicle screw assembly that comprises a screw having a head with a convex portion and a receiver that receives the head. The receiver also receives an elongated member, such as a spinal fixation rod. The receiver has a concave portion which has a radius of curvature which is less than the radius of curvature of the convex portion of the head whereby to create an interference fit between the convex portion of the head and the concave portion of the receiver. The device also includes an internal nut and external nut that compresses the rod against a pressure disc which in turn compresses the head convex portion of the screw into the receiver concave portion and locks the angular position of the receiver with respect to the screw.
One of the problems with the prior art devices is the number of parts and components, especially those components that utilize a threaded cap screw to secure the rod to the anchoring screw, whether internal or external, to fix the rod relative to the screw. Problems with the threaded fastener, that is, threaded cap or set screw, are numerous and include risk of cap loosening, loss of cap intra-operatively, cross threading, thread failure, failure of the cap in driving instrument and limitations upon torque application.
What is needed, therefore, is a system and method that provide a lock or connection between the rod and screw without the use of external nuts, screws, caps or threads of the type shown in the prior art.
These and other objects and advantages of the invention will be apparent from the following description, the accompanying drawing and the appended claims.
SUMMARY OF THE INVENTIONThe present invention improves the spinal fixation and the locking between an elongated member or rod and a screw.
One object of the invention is to provide a system and method that reduces or eliminates the need for external or internal caps or screws to lock the relative position of a rod to a screw.
Another object of the invention is to provide a simple bayonet-type connection that eliminates the fixation systems of the past and/or simplifies the spinal fixation procedure.
In one aspect, this invention discloses a capless multiaxial screw comprising a screw having a threaded portion and a screw head, a receiver having a bore for receiving the threaded portion and a receiving channel for receiving an elongated member, the channel further comprising a locking channel in communication with the channel, a compression member for situating in the bore, the compression member comprising a second receiving channel having a first end and a second end and further associated with a first end, and a receiving area associated with the second end for receiving and engaging the screw head, the elongated member cooperating with the compression member to lock the elongated member to the screw when the elongated member is received in the first and second receiving channels and the receiver is rotated from an unlocked position to a locked position.
In another aspect, this invention discloses a spinal fixation assembly comprising a receiver having a bore for receiving a screw having a screw head that is larger than a diameter of the bore, and a compression member dimensioned to be received in the bore and having a first end for receiving an elongated member and a second end for engaging the screw head, the receiver comprising a receiving channel for receiving the elongated member and a locking channel for locking the elongated member to the screw when the receiver is rotated from an unlocked to a locked position.
In yet another aspect, this invention relates to a spinal fixation assembly comprising a receiver having a bore for receiving a screw having a screw head that is larger than a diameter of the bore and a receiving channel for receiving an elongated member, and a compression member dimensioned to be received in the bore and having a first end for engaging the elongated member and a second end for engaging the screw head, the receiver comprising a rotary lock for locking the elongated member to the screw.
In still another aspect, this invention relates to a spinal fixation assembly comprising a receiver having a bore for receiving a screw having a screw head, and a compression member dimensioned to be received in the bore and having a first end for engagement with an elongated member and a second end for engagement with the screw head, the receiver comprising a locking channel and a receiving channel coupling the locking channels, the receiving channel receiving the elongated member and the locking channels cooperating to secure the elongated member to the screw when the receiver is rotated.
In another aspect, this invention discloses a receiver for use with a polyaxial screw comprising a body having a bore and a connection channel for receiving an elongated member and for locking it to the screw when the receiver is rotated.
In another aspect, this invention discloses a spinal fixation assembly comprising a receiver having a bore for receiving a screw having a screw head, and a compression member dimensioned to be received in the bore and having a first end and a second end, the receiver comprising an integral rotary lock for locking the elongated member to the screw when the receiver is rotated.
In another aspect, this invention relates to a method for securing an elongated member to a spinal column, comprising the steps of screwing a screw into a spinal bone, the screw having a head that is received in a seat of a receiver having a bore through which threads of the screw may pass, situating the rod into the receiver, and rotating the receiver to fasten the rod onto the screw.
In another aspect, this invention discloses a capless multiaxial screw comprising a screw having a threaded portion and a screw head and a receiver having a bore for receiving the threaded portion and a receiving channel for receiving an elongated member, the receiving channel further comprising a locking channel in communication with the receiving channel, the receiver locking the elongated member to the screw when the elongated member is received in the receiving channel and the receiver is rotated from an unlocked position to a locked position.
The above mentioned aspects and the embodiments shown and described herein could be used alone or together and/or in combination with one or more of the features covered by one or more of the claims set forth herein, including but not limited to one or more of the following features or steps:
The capless multiaxial screw fixation assembly wherein the receiver comprises a plurality of channels that capture the elongated member.
The capless multiaxial screw fixation assembly wherein each of the plurality of channels defines an intermediate area for capturing the elongated member to facilitate adjusting a position of the elongated member before it is locked in the receiver.
The capless multiaxial screw fixation assembly wherein the plurality of channels are defined by a first surface and a second surface, each of the plurality of channels having an intermediate step for defining the intermediate area.
The capless multiaxial screw fixation assembly wherein the screw, receiver and compression member are preassembled.
The capless multiaxial screw fixation assembly wherein the locking channel is a helical channel defined by at least one surface of the receiver.
The capless multiaxial screw fixation assembly wherein the seat area is generally concave, the screw head having a curvature that generally complements the concave receiving area.
The capless multiaxial screw fixation assembly wherein the receiving channel comprises a first axis and the second receiving channel comprises a second axis, the second axis and the first axis being generally parallel when the receiver is in the unlocked position and generally perpendicular when the receiver is actuated to the locked position.
The capless multiaxial screw fixation assembly wherein when the receiver is rotated, the receiver moves from a first position to a second position in response thereto, such that when the receiver is in the second position, the elongated member is closer to the screw head than when the elongated member is in the first position.
The capless multiaxial screw fixation assembly wherein the first position corresponds to the unlocked position and the second position corresponds to the locked position.
The capless multiaxial screw fixation assembly wherein the receiving channel is generally perpendicular to an elongated member axis of the elongated member when the receiver is in the locked position.
The capless multiaxial screw fixation assembly wherein the locking channel provides a bayonet connection between the elongated member and the screw.
The capless multiaxial screw fixation assembly wherein the receiving channel is generally parallel along an axis of the receiver and the locking channel spirals about the axis of the receiver when moving in an axial direction.
The capless multiaxial screw fixation assembly wherein the receiving channel extends from an end of the receiver in a direction that is generally parallel to an axis of the receiver and the locking channel extends in a direction that is generally not parallel to the axis of the receiver.
The capless multiaxial screw fixation assembly wherein when the compression member is received in the bore and the first channel becomes generally aligned with the second channel, the locking channel becomes situated at least partially around the compression member.
The capless multiaxial screw fixation assembly wherein the receiver comprises at least one camming surface that cooperates with an opposing surface for defining the locking channel, the at least one camming surface facilitates camming the elongated member urges the compression member to apply a compressive force against the compression member which, in turn, urges the compression member to apply a compressive force against the screw head in response thereto.
The capless multiaxial screw fixation assembly wherein the receiver comprises a plurality of camming surfaces that cooperate with a plurality of opposing surfaces, respectively, to define the locking channel, the plurality of camming surfaces camming against the elongated member to force the elongated member against the compression member which, in turn, applies a compressive force against the screw head when the receiver is rotated.
The capless multiaxial screw fixation assembly wherein the locking channel comprises a first locking channel area and a second locking channel area, the receiver comprises a first camming surface generally opposed to a first opposing surface to define the first locking channel area and a second camming surface generally opposed to a second opposing surface to define the second locking channel area, the first and second camming surfaces camming against the elongated member to force the elongated member against the compression member which, in turn, applies a compressive force against the screw head when the receiver is rotated.
The capless multiaxial screw fixation assembly wherein the locking channel comprises a lock member associated therewith for facilitating retaining the receiver in a locked position.
The capless multiaxial screw fixation assembly wherein the lock member comprises a detent in the receiver and associated with the locking channel.
The capless multiaxial screw fixation assembly wherein the lock member cooperates with an end wall of the locking channel to define a locking area at which the elongated member is locked when it is in the locked position.
The capless multiaxial screw fixation assembly wherein the receiving channel lies in a first plane that is generally planar and the locking channel lies in a second plane that is non-planar.
The capless multiaxial screw fixation assembly wherein the second plane spirals about an axis of the retainer.
The capless multiaxial screw fixation assembly wherein the locking channel spirals about an axis of the retainer.
The capless multiaxial screw fixation assembly wherein the screw head is generally spherical and the seat area is also generally spherical and dimensioned to receive and complement the screw head.
The spinal fixation assembly wherein the rotary lock comprises at least one engaging surface for engaging the elongated member and for locking the elongated member to the screw when the receiver is rotated to a locked position.
The spinal fixation assembly wherein the receiver is generally cylindrical and the bore extends along an axis of the receiver, the receiver comprising a first locking aperture in communication with the bore and a second locking aperture in communication with the bore; the first and second locking apertures cooperating to define the rotary lock.
The spinal fixation assembly wherein the first locking aperture and the second locking aperture cooperate to define a locking channel for receiving the elongated member.
The spinal fixation assembly wherein the first locking aperture and the second locking aperture cooperate to define a generally s-shaped channel when viewed in cross-section for receiving the elongated member.
The spinal fixation assembly wherein the rotary lock comprises a locking channel in the receiver that is in communication with the receiving channel.
The spinal fixation assembly wherein the locking channel is defined by a first channel in a wall of the receiver and a second channel in the wall of the receiver, the first and second channels being generally opposed.
The spinal fixation assembly wherein the first channel and the second channel extend away from the receiving channel about a receiver axis of the receiver such that rotation of the receiver will move from an unlocked position to a locked position.
The spinal fixation assembly wherein the first channel and the second channel spiral in a common direction about a receiver axis of the receiver.
The spinal fixation assembly wherein the locking channel and the receiving channel cooperate to provide a bayonet connection between the elongated member and the screw.
The spinal fixation assembly wherein the receiving channel lies in a plane that is generally planar and the locking channel lies in a plane that is generally curved.
The spinal fixation assembly wherein the receiver comprises a wall that lies in an arcuate plane about a receiver axis of the receiver and the locking channel also lie in the arcuate plane.
The spinal fixation assembly wherein a starting area of the locking channel is situated at a different radial position and a different axial position relative to the receiver axis when compared to an end position of the locking channel when the elongated member is locked to the screw.
The spinal fixation system wherein the receiver comprises a first engaging surface, the first engaging surface engaging the elongated member and forcing it against the compression member which, in turn, engages the screw head with a compressive force when the receiver is rotated.
The spinal fixation system wherein the locking channels comprise a first camming surface and a second camming surface, respectively, that engages the elongated member and forces it against the compression member until the elongated member becomes fixed relative to the screw.
The spinal fixation system wherein the locking channel lies in a plane that is at predetermined angle relative to the receiving channel.
The spinal fixation system wherein the predetermined angle is approximately 90 degrees.
The spinal fixation system wherein the predetermined angle is an acute angle that extends toward a vertebrae when the screw is screwed into the vertebrae.
The receiver wherein the connection channel defines a bayonet connection channel.
The receiver wherein the connection channel comprises a plurality of channels that cooperate to define the bayonet connection channel.
The receiver wherein the plurality of channels spiral about an axis of the receiver.
The spinal fixation system wherein the integral rotary lock comprises a continuous channel for receiving the elongated member and for urging the elongated member toward the screw head when the receiver is rotated.
The spinal fixation system wherein the integral rotary lock comprises a first channel that extends about a receiver axis in a first direction and a second channel that extends about the receiver axis in a second direction and a receiver channel coupling the first and second channels.
The spinal fixation system wherein the first and second directions extend away from the receiving channel about a receiver axis of the receiver such that rotation of the receiver will move from an unlocked position to a locked position.
The spinal fixation system wherein the receiver channel lies in a plane that generally extends along an axis of the receiver.
The spinal fixation system wherein the first and second channels spiral about the receiver axis.
The spinal fixation system wherein the first and second channels lie in imaginary planes that intersect an axis of the receiver at acute angles.
The spinal fixation system wherein the receiver channel lies in a receiver plane, the first channel lies in a first plane and the second channel lies in a second plane, first and second planes intersecting the receiver plane at an acute angle that extends toward a vertebrae when the screw is screwed into the vertebra.
The method wherein the method further comprises the step of situating the elongated member against a compression member which engages the screw head to fasten the elongated member to the screw when the receiver is rotated.
The method wherein the method comprises the step of aligning a receiving channel of the compression member with a receiving channel of the receiver before the situating step.
The method wherein the method comprises the step of providing the compression member and receiver pre-aligned prior to the screwing step.
The method wherein the retainer comprises a receiving channel and a locking channel, the method further comprising the steps of situating the elongated member in the receiving channel and rotating the receiver so that the elongated member becomes situated in the locking channel.
The method wherein the method further comprises the step of aligning the receiver before the rotating step.
The method wherein the method further comprises the steps of screwing a second screw into a second spinal bone, the second screw having a head that is received in a seat of a second receiver having a bore through which threads of the second screw may pass, situating the elongated member into the second receiver and rotating the second receiver to fasten the elongated member onto the second screw after performing the first rotating step, thereby fixing the relative positions of the first and second spinal bones.
The method wherein the method further comprises the step of aligning a first receiving channel of the first receiver with a second receiving channel of the second receiver before the second rotating step.
The method wherein the method further comprises the step of repeating the method using a plurality of screws having a plurality of retainers, respectively, and the elongated member to secure a plurality of vertebrae together in a fixed relationship.
The capless multiaxial screw wherein the receiver comprises a plurality of channels that capture the elongated member.
The capless multiaxial screw wherein each of the plurality of channels defines an intermediate area for capturing the elongated member to facilitate adjusting a position of the elongated member before it is locked in the receiver.
The capless multiaxial screw wherein the plurality of channels are defined by a first surface and a second surface, each of the plurality of channels having an intermediate step for defining the intermediate area.
The capless multiaxial screw wherein at least one of the first and second surfaces is not planar.
The capless multiaxial screw wherein the locking channel is a helical channel defined by at least one surface of the receiver.
The capless multiaxial screw wherein the capless multiaxial screw further comprises a compression member for situating in the bore, the compression member comprising a generally concave seat, the screw head having a curvature that generally complements the generally concave seat.
The capless multiaxial screw wherein the receiving channel comprises a first axis, the elongated member axis of the elongated member being generally parallel to the first axis when the elongated member is in the unlocked position and generally perpendicular when the receiver is actuated to the locked position.
The capless multiaxial screw wherein when the receiver is rotated, the receiver moves the elongated member from a first position to a second position in response thereto, such that when the receiver is in the second position, the elongated member is locked to the screw head.
The capless multiaxial screw wherein when the receiver is rotated, the receiver moves the elongated member from a first position, through an intermediate position, to a second position.
The capless multiaxial screw wherein the first position corresponds to the unlocked position and the second position corresponds to the locked position.
The capless multiaxial screw wherein the receiving channel is generally perpendicular to an elongated member axis of the elongated member when the receiver is in the locked position.
The capless multiaxial screw wherein the locking channel provides a bayonet connection.
The capless multiaxial screw wherein the receiving channel is generally parallel along an axis of the receiver and the locking channel spirals about the axis of the receiver when moving in an axial direction.
The capless multiaxial screw wherein the receiving channel extends from an end of the receiver in a direction that is generally parallel to an axis of the receiver and the locking channel extends in a direction that is generally not parallel to the axis of the receiver.
The capless multiaxial screw wherein the receiver comprises at least one camming surface that cooperates with an opposing surface for defining the locking channel, the at least one camming surface facilitates compressing the elongated member against the screw.
The capless multiaxial screw wherein the receiver comprises a plurality of camming surfaces that cooperate with a plurality of opposing surfaces, respectively, to define the locking channel, the a plurality of camming surfaces for camming against the elongated member to lock the receiver to the screw.
The capless multiaxial screw wherein the locking channel comprises a first locking channel area and a second locking channel area, the receiver comprises a first camming surface generally opposed to a first opposing surface to define the first locking channel area and a second camming surface generally opposed to a second opposing surface to define the second locking channel area, the first and second camming surfaces camming against the elongated member to force the elongated member against the compression member which, in turn, applies a compressive force against the screw head when the receiver is rotated.
The capless multiaxial screw wherein the locking channel comprises a lock member associated therewith for facilitating retaining the receiver in a locked position.
The capless multiaxial screw wherein the lock member comprises a detent in the receiver and associated with the locking channel.
The capless multiaxial screw wherein the lock member cooperates with an end wall of the locking channel to define a locking area at which the receiving member is locked when it is in the locked position.
The capless multiaxial screw wherein the receiving channel lies in a first plane that is generally planar and the locking channel lies in a second plane that is non-planar.
The capless multiaxial screw wherein the second plane spirals about an axis of the retainer.
The capless multiaxial screw wherein the locking channel spirals about an axis of the retainer.
The capless multiaxial screw wherein the receiver comprises a seat, the screw head is being generally spherical and the seat is also generally spherical and dimensioned to receive and complement the screw head.
These and other objects and advantages of the invention will be apparent from the following description, the accompanying drawing and the appended claims.
BRIEF DESCRIPTION OF THE DRAWINGSFIG. 1 is a fragmentary perspective view of a capless multiaxial screw and fixation assembly mounted on a spinal column having a plurality of vertebrae;
FIG. 2 is a perspective view of the system shown inFIG. 1;
FIG. 3 is an exploded fragmentary perspective view of the system shown inFIGS. 1 and 2;
FIG. 4 is a fragmentary perspective view illustrating a rod received in a receiving channel of a receiver;
FIG. 5 is a fragmentary plan view of the illustration shown inFIG. 4;
FIG. 6 is a fragmentary view similar toFIG. 4, but showing the receiver rotated approximately 30 degrees about its axis relative to the rod;
FIG. 7 is a fragmentary plan view similar toFIG. 5 and showing the receiver in the position illustrated inFIG. 6;
FIG. 8 is fragmentary perspective view showing the receiver in a fully locked position;
FIG. 9 is a plan view similar toFIGS. 5 and 7 showing the receiver in a fully locked position;
FIG. 10 is a view taken along the line10-10 inFIG. 4;
FIG. 11 is a view illustrating the rod after it has been received in the channel of the receiver and supported above a bottom surface of a compression member;
FIG. 12 is a sectional view taken along the line12-12 inFIG. 8;
FIG. 13 is a fragmentary view showing the rod in cross-section and in a fully locked position;
FIG. 14 is a fragmentary view illustrating various features of the locking channels;
FIG. 15 is a plan view showing a compression member received in a bore of the receiver and illustrating the aperture through which a tool may be inserted to rotate the screw head before the rod is positioned in a channel of both the receiver and the compression member;
FIG. 16A-16E are various views of the receiver in accordance with one illustration of the invention;
FIG. 17 is a sectional view of a compression member in accordance with one illustration of the invention;
FIG. 18 is a fragmentary sectional view of another illustration of the invention, showing a channel having walls that are generally non-planar to define an intermediate area for loosely capturing the rod;
FIG. 19 is a side elevation view of the embodiment shown inFIG. 18;
FIG. 20 is a fragmentary sectional view that has been rotated relative toFIGS. 18 and 19;
FIG. 21 is an elevational view rotated relative toFIG. 19;
FIGS. 22-24 are plan views illustrating rotational movement of the receiver relative to the rod;
FIGS. 25-27 are side elevation views that generally correspond toFIGS. 22-24, respectively, illustrating the receiver in various positions, but with the rod removed for ease of illustration and understanding;
FIGS. 28-30 are views similar toFIGS. 25-27, respectively, illustrating the receiver in various rotational positions relative to the rod as the rod is moved from a receiving position to a locked position;
FIGS. 31-33 are fragmentary sectional views somewhat enlarged and diagrammatic to simply illustrate the intermediate capturing step of receiving area for loosely capturing the rod in the receiver; and
FIG. 34 is a diagrammatic view which is presented for purposes of illustrating various dimensions of the channels in the receiver or the second illustrative embodiment.
DETAILED DESCRIPTION OF THE INVENTIONReferring now toFIGS. 1-3, a capless multi-axial screw andspinal fixation assembly10 and method are shown. Thespinal fixation assembly10 comprises ascrew12 having a threadedportion12aand ascrew head12bthat in the embodiment being described, has a rounded profile or curvature, as best illustrated in FIGS.3 and10-13. Thescrew head12bcomprises a hex female opening orslot12cfor receiving a tool (not shown) for screwing thescrew12 into an aperture14aof aspinal bone14, such as a vertebra of a spine.
As illustrated inFIGS. 1 and 2, one feature of the invention is that it enables a user to fix a relative position of a plurality of vertebrae, such asvertebrae14,16 and18 inFIG. 1, in a fixed and stabilized position.
Thespinal fixation assembly10 comprises a retainer orreceiver20 having a generallycylindrical receiver wall20c(FIG. 4) that defines an aperture or bore22 that traverses or extends along a receiver axis A (FIG. 11) the entire length of thereceiver20, as best illustrated inFIGS. 4,10, and12. Thereceiver20 comprises afirst end20aand asecond end20b, and although not shown, may comprise a chamfer21 of about 45 degrees. It should be understood that thereceiver wall20cdefines areceiver seat20dtoward the bottom of the receiver20 (as viewed inFIGS. 10 and 15) that is arcuate or curved in cross section. Thereceiver seat20dhas a radius or curved surface R1 (FIG. 10). Note that a diameter or distance D1 (FIG. 10) ofbore22 at thesecond end20bof the retainer orreceiver20 is slightly smaller than both a diameter or distance D2 (FIGS. 7 and 10) of thebore22 atfirst end20aand a diameter D3 (FIG. 12) of therounded screw head12bso that it defines thereceiver seat20d(FIGS. 10 and 15) for receiving or capturing thescrew head12b. In this regard, thescrew head12bhas anend12b1 that is configured and dimensioned to be received or captured in theseat20dand that can be rotated or screwed while in the bore22 (FIGS. 10 and 15). Theend12b2 has a curved or arcuate shape that generally complements the shape of theseat20dto permit polyaxial and relative movement between thereceiver20 andscrew12.
As shown in FIGS.3 and11-13, thebore22 receives the threadedportion12aof thescrew12 until thescrew head12bis received in theseat20d(as illustrated inFIGS. 10-13). It should be understood that theseat20dcooperates with theend12b1 ofscrew head12band permits the retainer orreceiver20 to move polyaxially about a center ofscrew head12bso that position of thereceiver20 may be altered relative to thescrew head12bofscrew12. This allows a user, such as a surgeon or physician, to change the polyaxial position of thereceiver20 relative to thescrew12 in order to adjust an angular position of an elongated member orrod24 relative to, for example, thevertebrae14,16 and18 illustrated inFIG. 1. Therod24 may be any suitable shape in cross section, such as circular, hexagonal, octagonal, polygonal or the like.
Note that thereceiver20 comprises a receiving channel26 (FIG. 15) defined bywall surfaces21a,21b,21cand21d(FIG. 4). Thereceiver20 further comprises a lock, locking means, locking channel, or rotary lock28 (FIGS. 11 and 12) which is integral with thereceiver20. In the embodiment being described, thereceiver20 is manufactured of titanium and is machined to provide the receivingchannel26,rotary lock28 and thebore22 using conventional machining techniques. Other potential materials include biocompatible load bearing material, such as metals, metal alloys, carbon fibers, composites, plastics or hybrid materials.
In one embodiment, thelock28 cooperates and is in communication with the receivingchannel26 to provide acontinuous channel30 for receiving the elongated member orrod24. Thelock28 cooperates with the receivingchannel26 and urgesrod24 toward thescrew head12band vertebra, such as one of the vertebra14-18 inFIG. 1, when thereceiver20 is rotated in a clockwise direction (as viewed inFIG. 3). Thecontinuous channel30 comprises afirst channel32, thechannel26, and thesecond channel34. Thelock28 andcontinuous channel30 provides a bayonet-type connection for coupling or fixing thereceiver20, therod24 and screw12 together in the manner described herein.
Note that thelock28 comprises thefirst channel32 and a second channel34 (FIGS. 12 and 13) that extend or spiral, as illustrated inFIGS. 16A-16E, about the receiver axis A (FIG. 11) ofreceiver20. The first andsecond channels32 and34 generally spiral or revolve from thefirst end20aofreceiver20 toward thesecond end20b, as shown inFIGS. 10-13 and16A-16D. Thus, in the embodiment being described, the first andsecond channels32 and34 are non-linear and spiral or revolve in a general helix about the axis A of thereceiver20. In the illustration, thechannels32 and34 spiral or revolve in the same direction about the axis A, as shown inFIGS. 16A-16D. Note that thechannels32 and34 are in communication with both the receiver bore22 and receivingchannel26 ofreceiver20. During operation, the channels32 (FIG. 11) and 34 (FIG. 12) receive therod24 after it has been received inchannel26 and urge or force therod24 toward thescrew head12band vertebra, such asvertebra14 inFIG. 1, when thereceiver20 is rotated in a clockwise direction in the illustration being described.
As illustrated inFIGS. 11 and 16A, thefirst channel32 is defined by a first surface orwall20e, a generally opposing second surface or wall20g, and athird surface wall20fthat joins thewalls20eand20gin thereceiver20. A fourth surface orwall20h, a generally opposing fifth surface or wall20i, and a sixth surface orwall20jthat joinswalls20hand20icooperate to define the second channel34 (FIGS. 12 and 16D). Note that thewalls20eand20gare generally parallel andwalls20hand20iare generally parallel. In the illustration being described, thewalls20eand20gand20hand20iare generally planar and have generally constant distance D4 (FIG. 13) and D5 (FIGS. 11 and 12) therebetween. However, in the illustration described later herein relative toFIGS. 18-32, the opposingwalls20e,20g,20hand20imay be non-planar so that the distance or dimensions D9 and D10 vary along the length of thechannels32 and34.
Thechannels32 and34 generally lay in planes P1 and P2 that are at the angles C (FIG. 14) and D, respectively, relative to the axis A of thereceiver20. As described later herein, thewalls20eand20hengage and cam against therod24 and force or urge it downward (as viewed inFIGS. 10-15) in response to the rotary movement of thereceiver20. In another embodiment described later herein, thewalls20eand20gandwalls20hand20imay comprise a curved or arcuate area and may cooperate to define an intermediate rod capturing area, as described below relative toFIGS. 18-34.
As illustrated inFIGS. 4 and 11, note that thechannel32 is defined by thewalls20e,20f,20gand generally curved orarcuate wall portion50 that couples second surface or wall20gtowall surface21b(FIGS. 4 and 16A) ofchannel26. The generally curvedarcuate wall portion50 also generally defines an intersection or transition from the receivingchannel26 to thefirst channel32 oflock28. Thechannel34 is defined bywalls20h,20iand20jand a third generally curved orarcuate wall52 that joins the wall20ito wallsurface21d(FIGS. 4 and 16C). Thewall52 provides an intersection or transition betweenchannel26 and thesecond channel34. Notice that thewall portions20f(FIG. 11) and 20j(FIG. 12) also each have a radius of curvature that generally complements the radius of curvature or circumference of therod24 so that when therod24 is moved from the unlocked position (illustrated inFIGS. 4,5,10 and11) to a locked position (illustrated inFIGS. 8,9,12 and13), therod24 is received and positioned against the wall surfaces20fand20jas shown.
Thespinal fixation assembly10 may further comprise a compression member40 (FIGS. 3 and 17). Thecompression member40 comprises awall40athat defines a second generally U-shaped receivingchannel42. Thecompression member40 also comprises a frusto-conical seat or concave area41 (FIGS. 10 and 17), defined by a tapered wall orsurface40b, that engages the rounded shape of theend12b1 (FIG. 3) ofscrew head12b. Although not shown, thespinal fixation assembly10 could be provided without thecompression member40, so that therod24 would engage thescrew head12bdirectly, for example, when thereceiver20 is rotated as described later herein.
Thecompression member40 comprises a length D6 (FIGS. 3 and 17) and a diameter D7 (FIG. 17) dimensioned to be received in thebore22 as shown. Thesecond channel42 defined bywall40acomprises abottom surface40c. Thesecond channel42 is generally U-shaped in cross section and has a width or dimension D8 (FIGS. 3,7 and17) andbottom surface40ccomprises a radius of curvature R5 (FIG. 17) that generally complements or is slightly larger than the circumference D9 (FIG. 3) of therod24.
During operation, thecompression member40 is urged downward (as shown inFIGS. 10-13) in response to the rotary movement of thereceiver20. Therod24 engages thebottom surface40c(FIGS. 12 and 17) of thesecond channel42 ofcompression member40. This in turn causes surface40bto engage and apply a compressive force against theend12b1 ofscrew head12bas therod24 is driven in the downward direction (as viewed inFIGS. 10-13) and into thesecond channel42. This movement forces and compresses theseat20dagainst theend12b2 ofscrew head12bof thereceiver20, thereby locking thescrew head12bto therod24 and fixing the relationship of thereceiver20 relative to thescrew head12b.
Note that the compression member40 (FIG. 17) also comprises a bore oraperture43 defined bywall40d. Thebore43 has a dimension or diameter D10 (FIG. 17). A surgeon or physician may insert a tool, such as a hex head screwdriver (not shown), throughchannel26, through bore22 ofreceiver20 and through thebore43 and into the hex female opening orslot12c(FIG. 15), for example, to tighten or loosen thescrew12. Thus, it should be understood, as illustrated inFIG. 15, that the hexfemale opening12cofscrew head12bis accessible after thescrew12 is inserted through thevertebra14 andcompression member40 is situated in thebore22.
Referring back toFIGS. 10-16E, the receiving channel26 (FIG. 11) ofreceiver20 extends from afirst end20aofreceiver20 in an axial direction and lies in a plane P3 (FIG. 15) that is generally planar and extends downward along the axis A (as viewed inFIG. 14). In contrast, thelock28 defined by thechannels32 and34 revolve, spiral or extend laterally or radially at distances that are generally constant relative to axis A and that vary, such as increase, relative to thefirst end20aofreceiver20. As mentioned earlier, each of thechannels32 and34 spiral in a general helix downward from the receivingchannel26 and about the axis A of thereceiver20 as shown inFIGS. 10-13 and16A-16D. Note that thechannels32 and34 lay in the planes P1 and P2 (FIG. 14), respectively, that intersect axis A at the predetermined angles indicated by double arrows C and D. The predetermined angles C and D are acute angles in the embodiment being described.
As shown inFIGS. 16A and 16B, thechannel32 is inclined relative to a radial line ofreceiver20 at a third angle (indicated by double arrow E inFIG. 16A) relative to thefirst end20a.Channel34 is also inclined relative to a radial line at a fourth angle F (FIG. 16B). Although not shown, it is contemplated that other designs, configurations or arrangements ofchannels32 and34 and thelock28 may be provided, such as channels (not shown) that extend about axis A, but that do not spiral and/or that are not at the inclined angles E and F, such as channels that extend at distances that are generally constant relative to thefirst end20a.
An operation or method regarding this illustration will now be described. As illustrated inFIGS. 3-9 and15, thescrew12, together withreceiver20 are screwed intovertebra14 during which a physician or surgeon screws the threadedportion12aofscrew12 in the aperture14aof thevertebra14 using a tool (not shown), such as a hex wrench or screwdriver (not shown), that is inserted throughchannel26, bore22 and bore43. In one embodiment, thereceiver20,screw12 andcompression member40 may be provided in a pre-assembled unit prior to surgery, so no assembly is required by the physician. Thescrew12 is screwed substantially all the way intovertebrae14, but is left with space between thereceiver20 andvertebrae14 so that an angular or polyaxial position of thereceiver20 may be adjusted or changed during the operation.
Thechannel26 ofreceiver20 andsecond channel42 ofcompression member40 are provided or arranged in a common plane P3, as shown inFIGS. 4,5 and15. The surgeon then places therod24 into thechannels26 and42 and adjusts the multi-axial or polyaxial position of thereceiver20 relative to therod24. As mentioned earlier, thechannel26 and bores22 (FIG. 10) and 43 (FIG. 17) provide a continuous opening or area49 through which the physician or surgeon may insert a tool, such as a hex tool, to turn, rotate and/or tighten or loosen thescrew12 in the desired direction prior to placing therod24 intochannel26. At this point, therod24 remains in an unlocked position.
Note that therod24 is supported by and between the arcuate orcurved wall portions50 and52, which causes therod24 to be situated above thebottom surface40cof thesecond channel42 ofcompression member40, as illustrated inFIGS. 10 and 11. Note that the arcuate orcurved wall portions50 and52 each comprise a radius of curvatures R2 (FIGS. 11,14 and16a) and R3 (FIGS. 13 and 14), respectively, that generally complements or is larger than a radius of curvature or circumference of therod24, as illustrated inFIGS. 11 and 13.
The camming or bayonet type action of therotary lock28 onreceiver20 forces therod24 in an axial direction parallel with axis A ofreceiver20 when thereceiver20 is turned or rotated with a tool, such as a screwdriver (not shown), placed inchannel26, as illustrated inFIGS. 6 and 7. This rotary movement or action forces therod24 downward (as viewed inFIG. 10) and into thechannels32 and34. As thereceiver20 is rotated further, as shown inFIGS. 8 and 9, thewalls20eand20g(FIG. 11) ofchannel32 andwalls20hand20i(FIG. 12) ofchannel34 act upon, force or urge therod24 downward (as viewed inFIGS. 10-13) and into thesecond channel42 ofcompression member40 until it engages thesurface40cofcompression member40. As thereceiver20 is rotated further, therod24 urges thecompression member40 toward thescrew head12band forces wall40bof thecompression member40 against thescrew head12bofscrew12 with a compressive force which causes thescrew head12bto become fastened or locked to therod24, thereby fixing thereceiver20 androd24 to thescrew12.
It should be appreciated that when therod24 is in the locked position shown inFIGS. 8,9,12 and13, therod24 engageswalls20e,20f, and20gofchannel32 andwalls20h,20iand20jofchannel34 andsurface40cofsecond channel42. The wall orseat40dofcompression member40 engagesscrew head12b. These surfaces cooperate to retainrod24 in the locked position. Thewalls20fand20jcomprise a radius of curvature R4 of about φ.100-φ.130 inch. A raised detent portion or bump59 (which is only shown inFIG. 13 for ease of illustration) may be provided in eachchannel32 and34, as shown inFIG. 13 relative to channel32. Thedetent59 is provided to facilitate retaining therod24 in the locked position.
Thus, as illustrated inFIGS. 1,2 and4-9, a surgeon may use one or a plurality ofspinal fixation assemblies10 during a spinal fixation procedure. For example, the surgeon may use a plurality ofreceivers20 and screws12 with onerod24, as illustrated inFIGS. 1 and 2. In the illustration, the surgeon screws thescrews12 into a plurality of vertebrae, such asvertebrae14,16 and18 illustrated inFIG. 1, and generally aligns thechannels26 ofreceivers20. The surgeon then inserts the tool, such as a hex tool (not shown), throughbores22 and43 and into hex female opening orslot12cinscrew head12band screws thescrew12 until the bottom20bof thereceiver20 engages or is proximately located against its respective vertebra.
If thecompression member40 is being used,compression member40 is located in each bore22 of eachreceiver20 and generally aligns thechannels42 and26, as illustrated inFIGS. 4,10 and15. It should be understood that when thespinal fixation assembly10 is in the unlocked position, thechannels26 and42 are generally parallel or lie in the common plane P3 as shown inFIG. 15. Therod24 is then placed inchannel26, whereupon it becomes supported bywalls50 and52 (FIG. 11). This causesrod24 to be supported slightly above the bottom40cof thesecond channel42 ofreceiver20, as mentioned earlier and as illustrated inFIGS. 10 and 11.
At this point in the procedure, the surgeon aligns therod24 in thereceiver20 to the desired position relative to the spine, vertebrae andother receivers20 that are being used. He positions therod24 and polyaxial or angular position of each receiver(s)20 relative thereto. It should be understood that the screws and position of the vertebrae, such as vertebrae14-18, relative to each other may also be adjusted. Once the bones14-18 are adjusted and angular or polyaxial position of eachreceiver20 is adjusted, the surgeon locks eachreceiver20 torod24 by rotating or turning thereceiver20 with a tool, such as a screwdriver (not shown), placed inchannel26. This causes thereceivers20 to become fixed or locked onto theirrespective screws12 and the spinal bones or vertebrae14-18 (FIG. 1) to become aligned and fixed into the desired position.
It should be understood that before therod24 is placed in the receivingchannel26 and thereceiver20 is rotated, the surgeon may tighten one ormore screws12 to a tighter or fixed seated position by situating the tool, such as a hex wrench (not shown), through the aperture43 (FIG. 15) defined by the wall orseat40dof thecompression member40 and into the hexagonalfemale slot12cin thescrew head12b. After thescrew12 is tightened to the desired tightness or torque, the surgeon places therod24 into thechannels26 and42 (FIGS. 4,5,10 and11) of the one or more of thereceivers20 being used.
As mentioned, the surgeon rotates thereceiver20 about its axis, as illustrated inFIGS. 3,6 and7 using a tool, such as a screwdriver (not shown), in the clockwise direction, as illustrated inFIGS. 6 and 7. During this rotation ofreceiver20, thecompression member40 androd24 do not rotate. As alluded to earlier,walls20eand20g(FIG. 11) andwalls20hand20i(FIG. 12) urge therod24 toward the bottom ofchannels32 and34 and urge therod24 to move downward (as viewed inFIGS. 10 and 12) toward thesurface40cor bottom of thesecond channel42 where it engages thesurface40c, as illustrated inFIGS. 4-9 and10-13. Therod24 is also supported by and compresses against thesurface40cofcompression member40. Thewall40dis caused to engage theend portion12b2.
Thus, when it is desired to lock thereceiver20 and thescrew12 to therod24, the surgeon rotates thereceiver20 in the clockwise direction, as illustrated inFIGS. 6 and 7, using the conventional tool, such as a regular screwdriver. Thereceiver20 is rotated until it is moved from the unlocked to the locked position, as illustrated inFIGS. 8,9,12 and13. Note that in the locked position, therod24 is received and engages thewalls20fand20jassociated with the ends ofchannels32 and34, respectively.
Thus, it should be understood that whenreceiver20 is rotated, thewalls20eand20hprovide the camming force necessary to cam and urge therod24 against thecompression member40. This, in turn, causes the surface orwall40bofcompression member40 to compress and lock against theend portion12b2 (FIG. 3) ofscrew head12b. Thewall40bofcompression member40 cooperates with the curved seat defined bywall40d(FIG. 10) and traps or locks thescrew head12bto therod24.
As illustrated inFIGS. 8,9,12 and13, notice that thechannel26 lies in an imaginary plane that is generally perpendicular to the imaginary plane in which thesecond channel42 and an axis ofrod24 when thereceiver20 is in the locked position.
It should be appreciated from the foregoing that the receivingchannel26 is in communication with thechannels32 and34 oflock28 and that thelock28 cooperates with therod24 to not only lock therod24 to thescrew12, but also to fix a position of thevertebrae14,16 and18.
When it is desired to unlock therod24 from thescrew12, the surgeon simply rotates thereceiver20 in a counterclockwise direction in the illustration and reverses the procedure.
Referring now toFIGS. 18-34, another illustrative embodiment is shown. Those parts that are the same as the parts relative toFIGS. 1-17 have been labeled with the same part number, except that the part numbers in the embodiment described inFIGS. 18-34 have a prime mark (“′”) associated therewith. TheFIGS. 31-34 are diagrammatic enlarged sectional views for ease of illustration.
Note in the embodiment inFIGS. 18-34, thereceiver20′ compriseschannels32′ and34′ that each have a cross-sectional dimension that varies over the length of thechannels32′ and34′ to provide an introducingarea60awhere therod24′ is loosely captured in thechannels32′ and34′. Thechannels32′ and34′ each have an introducingarea60a, an intermediate holding or receivingarea60band a lockingarea60c. For ease of illustration and description, the receivingarea60bwill be described relative to channel32′; however, it should be understood that thechannel34′ in the second illustration comprises substantially the same configuration.
It should be appreciated that theintermediate holding area60bin thechannels32′ and34′ enable an intermediate step betweeninitial rod24′ insertion andfinal rod24′ locking. In other words, this is arod24′ capturing step during which therod24′ is loosely captured in thereceiver20′, but it is not rigidly locked into place againstscrew12′ yet. This allows the surgeon greater ease and flexibility when he adjusts thescrews12′ position with respect to therod24′ while therod24′ is in place. For example, the surgeon may move thescrews12′ closer together (compression) or In the illustration being described, the intermediate capturing step is accomplished by rotating thereceiver20′ partially, such as approximately 30 degrees in the illustration as shown inFIGS. 23,26 and29, which forces therod24′ from the introducingarea60ainto theintermediate holding area60b.
The introduction area comprises an associated dimension D13 (FIG. 34) and the lockingarea60chas an associated dimension D14 (FIG. 34). Theintermediate holding area60bhas an associated intermediate dimension D15 (FIG. 34) between thewall62 andsecond wall64 that is slightly larger than the diameter of therod24′ and the dimensions D13 and D14 associated with theintroduction area60aand lockingarea60c, respectively. It is dimensioned to accommodate therod24′ and to capture therod24′ loosely so that therod24′ can easily slide between thewalls62 and64 and is not locked. This facilitates the surgeon adjusting a position of thescrews12′ in vertebrae, such asvertebrae14′-18′, relative to a position of therod24. Once thescrews12′ are adjusted to the desired position, the physician or surgeon may then lock thereceiver20′ onto thescrew12′ by inserting a tool, such as a screwdriver (not shown), into theslot26′ and rotate thereceiver20′ in the clockwise direction as illustrated inFIGS. 22-30.
In the illustration shown inFIGS. 31-34, thechannel32′ is defined by awall62, a generally opposingsecond wall64 and a joiningwall63 that joinswalls62 and64 as shown. Note that unlike the embodiment described relative toFIGS. 1-17, thewall62 has a first wall portion62a, a second wall portion62band anintermediate wall portion62cthat couples the wall portions62aand62bas shown. The opposingchannel wall64 comprises the first wall portion64a, a second wall portion64band an intermediate wall portion64cthat couples the first and second wall portions64aand64bas shown. In this regard, note that anintersection66 is defined between the wall portions64aand64c. Asecond intersection68 is defined between thewall portion62band62cas shown. Theintersections66 and68 generally define an entrance to theintermediate holding area60b. Theintermediate wall portions62cand64ccooperate to define theintermediate holding area60bwhich receives therod24′ and loosely captures therod24′ in thereceiver20′.
Thechannels32′ and34′ are configured such that they comprise or define theintroduction area60afor receiving therod24′ in thereceiver20′, as illustrated inFIGS. 22,25 and28. The first wall portion64aprovides a ramp64a1 for directing therod24′ into theintermediate holding area60bwhen thereceiver20′ is rotated about 20-40 degrees as shown inFIGS. 23,26 and29. As shown in the illustration, thewalls62 and64 are not generally planar and have areas, such asintermediate wall portions62cand64cthat are curved or recessed to facilitate defining theintermediate holding area60b.
During a surgical procedure, the surgeon may make the desired adjustments of therod24′ relative to thescrews12′ andvertebrae14′-18′ while therod24′ is loosely captured in theintermediate holding area60b. The surgeon then uses the tool, such as a screwdriver (not shown), to rotate thereceiver20′ to the locked position shown inFIGS. 24,27 and29. Similar to the embodiment described earlier herein relative toFIGS. 1-17, thereceiver20′ urges or forces therod24′ from theintermediate holding area60bto the lockingarea60c. Therod24′ becomes situated in the lockingarea60c, whereupon therod24′ becomes locked therein. Note that the distance or dimension D12 (FIG. 8) between the second wall portions64band62bis substantially the same or may be smaller than the diameter of therod24′. As thereceiver20′ is rotated in the clockwise direction in the illustration being described, thewall62 slightly deflects upward (as viewed inFIG. 31, for example) to permit therod24 to be captured and locked in the lockingarea60c. Note that a portion ofwalls62,63 and64 comprises various radii of curvature R5-R9. For example, the radius of curvature R8 generally corresponds to the cross sectional circumference of therod24′ so that therod24′ becomes captured in the lockingarea60c. As in the prior illustration, the detent59 (FIG. 33) may be provided inchannels32′ and34′ to further facilitate retaining therod24′ in the lockingarea60c.
Advantageously, this system and method facilitates providing a lockingreceiver20 that reduces or eliminates the need for threading, internally or externally.
Advantageously, theimmediate holding areas60bofchannels32′ and34′ of the second embodiment are dimensioned and configured to facilitate locking therod24′ onto thescrews12′ while permitting ease of adjustment between thereceiver20′ and therod24′ when therod24′ andreceiver20′ are situated in theintermediate holding area60b′, as illustrated inFIGS. 23,26 and29.
In the embodiments being described, therod24,screw12,receiver20 andcompression member40 are all made of titanium alloy. Other materials may be used such as metals, metal alloys, carbon fibers, composites, plastics or hybrid materials.
For example, thescrew12 may have a length D11 (FIG. 3) ranging from 10 mm-60 mm, and thereceiver20 may have a diameter D12 (FIG. 8) ranging between 2 mm-10 mm. Thecompression member40 may define thesecond channel42 having the width D8 ranging between 2 mm-12 mm. Thechannels32 and34 may comprise dimensions D5, D6 (FIGS. 3 and 17) ranging between 2 mm-10 mm. It should be understood, however, the other shapes and dimensions may be used without departing from the true spirit and scope of the invention.
Advantageously, this system and method provide a capless multiaxial screw which eliminates the need for caps or screws or threads of the type used in the prior art. This system and method combine a very simplified yet effective means for locking an elongated member orrod24 to ascrew12 and spinal bone in the manner described and shown herein.
While the apparatus, system and method herein described, and the form of apparatus for carrying this method into effect, constitute several illustrative embodiments of this invention, it is to be understood that the invention is not limited to this precise method and form of apparatus, and that changes may be made in either without departing from the scope of the inventions, which is defined in the appended claims.