A bone screw that is a low-profile, uniplanar bone screw is provided. The bone screw is for adjusting a position of a rod. The bone screw includes a main body, a rocker and a rod-securing element. The main body has a shaft with a threaded part. The rocker is coupled to and moveable relative to the main body. The rocker is configured to at least partially receive the rod. The rod-securing element is configured to secure the rod between the rocker and the rod-securing element and relative to the main body. The rod-securing element includes a fulcrum serving as an axis of rotation about which the rod rotates.
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1. A uniplanar bone screw for adjusting a position of a rod, comprising: a main body having a shaft with a threaded part; a rocker coupled to and moveable relative to the main body, wherein the rocker is configured to at least partially receive the rod; a rod-securing element configured to secure the rod between the rocker and the rod-securing element and relative to the main body, wherein the rod-securing element includes a fulcrum serving as an axis of rotation about which the rod rotates, wherein the rod-securing element comprises a screw directly abuts the rod, wherein the main body includes a screw head coupled to the shaft, wherein the screw head includes a slot configured to at least partially receive the rod and the rocker; and a guide feature in one of the slot and the rocker and a guide channel in the other of the slot and the rocker, wherein the guide channel is configured to receive the guide feature to guide movement of the rocker relative to the main body.
2. The uniplanar bone screw of
4. The uniplanar bone screw of
6. The uniplanar bone screw of
7. The uniplanar bone screw of
wherein the bottom surface of the slot is one of:
(i) substantially flat in a first direction and in a second direction,
(ii) substantially curved in the first direction and in the second direction,
(ii) substantially flat in the first direction and substantially curved in the second direction, and
(iv) substantially curved in the first direction and substantially flat in the second direction, and
wherein the second direction is substantially perpendicular to the first direction.
8. The uniplanar bone screw of
10. The uniplanar bone screw of
11. The uniplanar bone screw of
wherein the rocker includes a substantially elliptic portion, a first wing extending from a first end of the substantially elliptic portion and a second wing extending from a second end of the substantially elliptic portion, and
wherein the substantially elliptic portion, the first wing and the second wing are configured to confine the rocker within the main body.
12. The uniplanar bone screw of
13. The uniplanar bone screw of
14. The uniplanar bone screw of
15. The uniplanar bone screw of
16. The uniplanar bone screw of
17. The uniplanar bone screw of
18. The uniplanar bone screw of
19. The uniplanar bone screw of
20. The uniplanar bone screw of
21. The uniplanar bone screw of
22. The uniplanar bone screw of
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The present application is a National Stage of International Application No. PCT/US2011/039760 filed on Jun. 9, 2011, which claims priority to U.S. Provisional Application No. 61/353,586, filed Jun. 10, 2010, and U.S. Provisional Application No. 61/394,274, filed Oct. 18, 2010, the disclosures of which are all incorporated herein by reference in their entireties.
1. Field of Embodiments
The present embodiments relate generally to orthopedic devices. More specifically, the present embodiments relate to screws for orthopedic devices that are typically placed within or adjacent to vertebrae (e.g., pedicles). It should be noted, however, that the screws disclosed herein may also be used in other orthopedic applications. For example, the screws may be used for repositioning fractured bones relative to one another, or used in an external fixator for trauma patients.
2. Description of Related Art
During spinal fusion surgery, bone screws may be fixed to adjacent vertebrae and interconnected with rods that span the screws to stabilize the spine during the healing process. The screw heads typically include a slot that is intended to receive a rod. The rod may be at least partially secured within the slot by a cap or set screw. The rods interconnecting the bone screws may span one or more vertebral levels (e.g., one to two vertebral levels for a spinal fusion of a degenerative condition, eight to twelve vertebral levels for scoliosis, etc.).
During an orthopedic surgical procedure, a number of factors can impact bone screw placement and alignment. These factors include, but are not limited to, spinal curvatures, variations in patient anatomy, and small imprecisions in screw placement by the surgeon. It is generally desirable for bone screws to be configured to be adjustable in order to achieve a desired alignment. However, with conventional bone screws, greater adjustability of the bone screw typically means the screw is relatively bulky (e.g., relative to its less adjustable counterparts). Bulky bone screws can cause pain and irritation to some patients.
Bone screws can be classified as monoaxial, polyaxial or uniplanar based on their adjustability.
Monoaxial bone screws are the most simplistic and not particularly useful for accommodating screw placement and alignment. The screw head of a monoaxial screw allows adjustment to the rod only in the direction perpendicular to the longitudinal axis of the screw. When the rod is secured in the slot of the bone screw, the longitudinal axis of the rod is substantially perpendicular to (i.e., at a 90° angle to) to the longitudinal axis of the bone screw.
Polyaxial screws are commonly used to overcome the variations in screw placement and alignment. The relationship between the screw axis and the rod axis can be variable but still be locked solidly in place (e.g., the screw head of a polyaxial screw may be configured to swivel approximately 20° off the screw axis). This adjustability allows rods to be connected to multiple screws that may be placed medial or lateral to one another and to provide for lordotic and kyphotic spinal alignments. Conventional polyaxial screws are larger and bulkier than monoaxial screws (e.g., because of the structures that provide for the screw head of a polyaxial screw to swivel).
Uniplanar screws have screw heads that may deviate from the screw axis but only in the plane of the slot for the rod; they typically do not adjust to medial or lateral rod positions (like polyaxial screws). This type of screw is more commonly used in scoliosis surgery where there may be a degree of cranial or caudal angulation (such as the sagittal plane of the spine), but there is little medial lateral screw placement deviation and the surgeon additionally needs rigid control of the screw to manipulate it in the coronal and axial plane of the spine. Similar to polyaxial screws, conventional uniplanar screws are large and bulky because of the configuration of their single plane swivel mechanism.
Because many scoliosis patients are children or smaller-sized adults and because many scoliosis fusions are performed in the kyphotic thoracic spine with less soft tissue coverage, the larger, bulkier polyaxial and uniplanar screws are often prominent and may cause pain and irritation to the patient. In some cases, the pain and irritation may rise to the level where a second surgery to remove the screws and rods is necessary.
A need exists for improved uniplanar bone screws, including bone screws that may address one or more of the above described disadvantages.
One embodiment relates to a uniplanar bone screw for adjusting a position of a rod that comprises a main body, a rocker and a rod-securing element. The main body has a shaft with a threaded part. The rocker is coupled to and moveable relative to the main body. The rocker is configured to at least partially receive the rod. The rod-securing element is configured to secure the rod between the rocker and the rod-securing element and relative to the main body. The rod-securing element includes a fulcrum serving as an axis of rotation about which the rod rotates.
These and other features, aspects and advantages of the disclosed embodiments will become apparent from the following description, appended claims and the accompanying exemplary embodiments shown in the drawings, which are briefly described below.
Referring generally to the FIGURES, various embodiments of a bone screw that is a low-profile, uniplanar bone screw are shown. An effort has been made to use the same or like reference numbers throughout the drawings to refer to the same or like parts. The low-profile, uniplanar bone screw may be a reduction screw. The low-profile, uniplanar bone screw preferably includes a rocker. The rocker may be a swing or a sliding rod support where both the swing and the sliding rod support can translate and rotate around a common axis. The rocker is configured to be movable relative to the main body of the bone screw and, thereby, to provide for a rod disposed thereon to be adjustable at least within a single plane. Stated otherwise, by using the rocker, the head of the bone screw need not be movable in order to provide for uniplanar adjustment of the rod relative to the main body of the bone screw. Because the head of the bone screw does not need to be movable, the screw can be configured to be smaller and less bulky than a conventional uniplanar bone screw, thereby decreasing the likelihood of pain and irritation to a patient. As a result, the bone screw is low-profile. Accordingly, the rocker allows for the screw to be less bulky than conventional polyaxial and uniplanar bone screws, while still providing uniplanar movement of the rod relative to the bone screw (e.g., cranial or caudal angulation of the rod axis relative to the screw axis). In general, at least two low-profile, uniplanar bone screws are secured to the patient while a single rod is coupled to each bone screw.
Referring to
The main body 14, 1014 includes a shaft 22, 1022 and a screw head 24, 1024 coupled to the shaft 22, 1022. The main body 14, 1014 generally defines a longitudinal screw axis 26, 1026 of the bone screw 10, 1000. The main body 14, 1014 of the bone screw 10, 1000 is configured to be secured to a person's spine (e.g., at a pedicle) to help couple the rod 12, 1012 to the patient's spine. The shaft 22, 1022 includes a threaded portion having a plurality of threads (the threaded portion of the shaft is not shown in
The screw head 24, 1024 is shown located at or proximate to the second end 30, 1030 of the bone screw 10, 1000. The head 24, 1024 is shown including a front side 32 (
The slot 44, 1044 is further configured to at least partially receive the sliding rod support 16, 1016, 1026, 1036 and to allow for movement of the sliding rod support 16, 1016, 1026, 1036 relative to the main body 14, 1014 (
The distance of the center 1095 of the sliding rod support 1016, 1026, 1036 from the longitudinal axis 26, 1026 of the bone screw 1000 as the rod 1012 pivots about the fulcrum 1085 of the rod-securing element 1018 may determine the amount of rotation θ of the rod 1012. For example, when the sliding rod support 1016, 1026, 1036 is aligned with the longitudinal axis 1026 of the bone screw 1000 (
The amount of rotation of the rod 1012 also depends on the height of the sliding rod support 1016, 1026, 1036 relative to the bottom surface 1050 of the slot 1044. The greater the height of the sliding rod support 1016, 1026, 1036 relative to the bottom surface 1050 of the slot 1044 the less the rod 1012 rotates. The angle of rotation θ may range from substantially 0° to substantially 20° where the maximum angle of rotation θ ranges from substantially 12° to substantially 20°. Preferably, the maximum angle of rotation θ is substantially 15°.
Referring to
Referring to
Referring to FIGS. 8 and 10-12, the sliding rod support 16 includes a body 56 having an upper portion 58 generally above a lower portion 60. The sliding rod support 16 is configured to be coupled and movable relative to the main body 14 to provide for adjustment of the cranial or caudal angulation of the longitudinal rod axis 20 relative to the longitudinal screw axis 26 of the bone screw 10.
Referring in particular to
Referring in particular to
The concave portion 52 of the bottom surface 50 and the convex surface 64 of the sliding rod support 16 are both shown substantially elongated from front-to-back. This elongation facilitates translational movement of the sliding rod support 16 relative to the main body 14, allowing the sliding rod support 16 to function in a sled or cradle-like manner. This configuration also allows relatively large portions of the surface to remain in contact after an adjustment of the position of the sliding rod support 16 relative to the main body 14. This may be particularly beneficial once the rod 12 is secured relative to the bone screw 10 because the friction between the concave portion 52 and the convex surface 64 can help maintain the rod 12 in a desired position relative to the bone screw 10.
Referring further to
Alternatively, the sliding rod support 16 could include a groove instead of the open channel 66. The projections 54 could be a single pin extending into the open channel 66, or could be studs that extend from both interior side walls 46, 48 and sit in the grooves 66 on each side of the sliding rod support 16. The projections 54 could be friction fit pins or studs, screws, or a combination of both.
Alternatively, other features or structures that help guide the movement of the sliding rod support relative to the main body may be used. These features and structures may be included or integrated with the head, may be included or integrated with the sliding rod support or both. It should also be noted that the interaction of the projections and the guide channels also helps retain the sliding rod support at least partially within the head of the bone screw.
The projection may extend through the walls of the main body. Referring to
The position of the guide features may be switched. Referring to
Referring to
The fulcrum of the rod-securing element may be pointed or curved. As shown in
Referring back to
Referring further to
Referring further to
The rod-securing element 18 includes threads that are configured to mate with the threads, as mentioned above. Positioning a portion of the rod-securing element 18 into the slot 44 and rotating the rod-securing element 18 about an axis substantially corresponding to the longitudinal screw axis 26, threadably engages the rod-securing element 18 with the head 24.
The rod-securing element 18 further includes an upper portion 74 and a lower portion 76. Referring to
Further referring to
The position of the rocker and the pointed lower portion may be switched. Referring to
The rocker 516, 1516 is a sliding rod support. As shown in
The sliding rod support may include a flat or curved surface that abuts the connector.
As shown in
This “inverted embodiment” functions in substantially the same manner as bone screw 10, described above. The motion of the sliding rod support 516 may include a rotational component of motion and a translational component of motion. Accordingly, the movement of a rod that is coupled to the bone screw 510 as it is adjusted typically includes both a rotational and a translational component of motion.
Referring to
Similar to main body 14, the main body 114 includes a shaft 122 and a head 124. The shaft 122 includes a threaded portion 127 including a plurality of threads 129. The head 124 includes a slot 144 having a first interior sidewall 146 generally opposite a second interior sidewall 148 and a bottom surface 150. The sidewalls 146, 148 are shaped to accommodate the rocker 116 and help retain the rocker 116 within the head 124, as will be discussed in more detail below. The bottom surface 150 includes a curved portion 152 in which the rocker may glide but also retains the rocker from displacing outside of the slot or recess for a dome 157 of the rocker 116.
Referring in particular to
Similar to sliding rod support 16, the upper portion 158 of the rocker 116 includes a surface 162 that is configured to at least partially support the rod 12, and the lower portion 160 is configured to at least partially interface with the bottom surface 150 of the slot 144 to facilitate movement of the rocker 116 relative to the main body 114. Also similar to the sliding rod support 16, the lower portion 160 includes a curved portion.
However, unlike the convex surface 64 of the sliding rod support 16, the curved portion is shown as a convex portion 164 that is substantially dome-shaped. The interaction between the concave portion 152 (e.g., recess, etc.) of the bottom surface 150 of the slot 144 and the convex portion 164 of the rocker 116 is configured to provide for substantially rotational movement of the rocker 116 relative to the main body 114. The concave portion 152 of the bottom surface 150 of the slot 144 and the convex portion 164 of the rocker 116 is in contact with concave portion 152 of the bottom surface 150. The dome-shaped convex surface 164 is substantially configured to raise a portion of the rocker 116 a distance above the bottom surface 150 of the slot 144 when in contact therewith. This distance facilitates rod rotation in addition to the rocker 116 gliding back-and-forth within the slot 144 substantially. It should be noted that, the concave portion of the bottom surface may be larger (e.g., larger than shown in
Further, the rocker 116 does not rely on guide channels and projections to guide it and retain it within the head 124. Rather, the rocker 116 is retained in the head because the slot 144 is shaped to substantially confine the rocker 116. That is, the upper portion 158 of the rocker includes a substantially elliptical portion 182 and wings 184 (i.e. a first wing and a second wing) that are configured to confine the rocker 116 within the screw head 124 of the main body 114. While the wings 184 extend substantially from front-to-back or a first end to a second end of the substantially elliptic portion 182 within the slot 144, the size and shape of the elliptical portion 182 substantially prevents the rocker 116 from falling out of the head 124.
Referring to
Referring to
Referring to
The first member 306 of the outrigger 300 is configured to be received in a slot 312 of the bone screw 304 and secured to a main body 314 of the bone screw 304 in a manner that is substantially similar to how rod 12 is coupled to the main body 14 of bone screw 10. When the first member 306 of the outrigger 300 is received within the slot 312, the second member 308 extends a distance outward to a side of the bone screw 304.
The rod-coupling portion 310 is shown as a clamp. The rod 302 may be positioned in a hook-shaped portion 316 of the clamp 310 and then secured thereto with a screw 318 before or after the first member 306 of the outrigger 300 is at least partially received in the slot 312. As mentioned above, the rod coupling portion 310 is shown disposed at the end of the second member 308 distal to where the second member 308 and the first member 306 meet or coincide. Thus, when the rod 302 is coupled to the outrigger 300 by the rod coupling portion 310, it is offset a distance from the longitudinal screw axis. Alternatively, the rod-coupling portion may be any combination of elements suitable for securing the rod relative to the first and second members.
The bone screw 304 further includes a rocker 320. The rocker 320 is configured to provide for adjustment of the outrigger 300, and, thus, the rod 302, relative to the bone screw 304 in a plane corresponding to or parallel to the plane generally defined by the slot 312. The rocker may be configured in any suitable manner providing for at least rotational (e.g., pivotal, rocking, etc.) motion of the rod relative to the bone screw, as described in more detail above.
Referring to
The swing 716 includes an upper surface 762 on which a rod would contact or interface and a bottom convex surface 764. The bottom convex surface contacts or interfaces with a flat or curved bottom surface 750 of the slot 744. The swing 716 is configured to swing freely without a load or seat firmly against the base or bottom surface 750 of the slot 744 when under a load, such as from a rod. The tolerances at the projection 754 enable the swing 716 to swing freely without the load. In other words, the projection 754 may be smaller than the receiving hole that the projection 754 fits into so that the projection 754 and receiving hole have a loose fit. The rod rotates about the tip of the tapered fixation screw which coincides with the projection or hinge.
As shown in
The screw head 1324 includes a bottom surface 1350. The bottom surface 1350 of the slot 1344 of the bone screw 1310 may be substantially curved in a first direction (
The bottom surface of the bone screw may not be curved. As shown in
The bottom surface of the bone screw may be curved in one direction and flat in another direction. As shown in
The fulcrum of the bone screw may be spaced a distance from a top surface of the swing hole or may be in line with a top surface of the swing hole. As shown in
Referring to
The sliding rod support 816 for bone screw 810 includes an upper surface 862 and a bottom curved surface 864. The upper surface 862 is arranged to contact or interface with a rod. The bottom curved surface 864 contacts or interfaces with the bottom surface 850 of the slot 844. The sliding rod support 816 includes a projection 854 that is configured to be received within a corresponding guide feature (e.g., guide channel) (not shown) in the bone screw 810. The sliding rod support 816 may also have a groove or channel (e.g., guide channel) (not shown) to accept a projection 854 from the interior wall of the screw head 844.
Referring to
The main body 914 includes a shaft 922 and a screw head 924 coupled to the shaft 922. The screw head 924 includes a top portion 972, a bottom portion 973 and a slot 944. The top portion 972 is detachably coupled to the bottom portion 973. The shaft 922 includes a threaded portion having a plurality of threads (not shown). The threaded portion is configured to be at least partially received within a bore (hole, cavity, etc.) formed in a person's spine. The threads of the threaded portion are configured to threadably engage the bore to secure the main body 14 to the spine.
The rod 912 may be placed into the slot 944 of the main body 914 and the rod-securing element 918 may be reduced into the head 924 until the rod 912 is seated in the rocker 916. Once the rod 912 is seated in the rocker 916, the top portion 972 may be decoupled from the bottom portion 973 by any suitable mechanism. For example, the top portion 972 may be manually detached from the bottom portion 973. Alternatively, the top portion 972 may be detached from the bottom portion 973 by any suitable instrument.
In all embodiments, the surface of the rocker can be textured to increase friction and thus prevent the rod from sliding in the direction of the rod axis. The surfaces of the rocker may be textured by etching or grit blasting.
As utilized herein, the terms “approximately,” “about,” “substantially,” and similar terms are intended to have a broad meaning in harmony with the common and accepted usage by those of ordinary skill in the art to which the subject matter of this disclosure pertains. It should be understood by those of skill in the art who review this disclosure that these terms are intended to allow a description of certain features described and claimed without restricting the scope of these features to the precise numerical ranges provided. Accordingly, these terms should be interpreted as indicating that insubstantial or inconsequential modifications or alterations of the subject matter described and are considered to be within the scope of the disclosure.
It should be noted that the term “exemplary” as used herein to describe various embodiments is intended to indicate that such embodiments are possible examples, representations, and/or illustrations of possible embodiments (and such term is not intended to connote that such embodiments are necessarily extraordinary or superlative examples).
For the purpose of this disclosure, the term “coupled” means the joining of two members directly or indirectly to one another. Such joining may be stationary or moveable in nature. Such joining may be achieved with the two members or the two members and any additional intermediate members being integrally formed as a single unitary body with one another or with the two members or the two members and any additional intermediate members being attached to one another. Such joining may be permanent in nature or may be removable or releasable in nature. For the purpose of this disclosure, the term “between” does not require direct connect between surfaces.
It should be noted that the orientation of various elements may differ according to other exemplary embodiments, and that such variations are intended to be encompassed by the present disclosure. It is recognized that features of the disclosed embodiments can be incorporated into other disclosed embodiments.
It is important to note that the constructions and arrangements of the low-profile uniplanar bone screw or components thereof as shown in the various exemplary embodiments are illustrative only. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters, mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter recited in the claims. For example, elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. Other substitutions, modifications, changes and omissions may also be made in the design, operating conditions and arrangement of the various exemplary embodiments without departing from the scope of the present disclosure.
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