The present invention relates generally to the field of spinal surgery and more particularly to treatments for spinal stenosis and spinal fixation for fusion and non-fusion treatments of the spine.
Spinal stenosis is a disease involving narrowing of the spinal canal leading to compression of the spinal cord and/or nerve roots. Depending on the location and severity of the spinal stenosis, this condition may lead to neurologic dysfunction including weakness, numbness, balance problems, problems walking, loss of coordination and loss of hand function. In particular, spinal stenosis of the cervical region is a common cause of major neurologic dysfunction resulting from compression of the spinal cord.
Traditional treatments for spinal stenosis involve surgical decompression of the spinal cord from either an anterior, posterior or combined surgical approach. Due to the invasive nature of these operations, the risks and benefits of surgery for spinal stenosis must be carefully weighed by patients and physicians considering this form of intervention. A laminectomy is the most common type of surgery employed for multilevel spinal stenosis and this operation may produce major bleeding, scarring, muscle damage and/or spinal instability in some patients undergoing this type of surgery. Although minimally invasive options have been devised for many spinal conditions, no well accepted minimally invasive options have yet been described for the treatment of spinal stenosis affecting the cervical or thoracic area. For all these reasons, there is a strong need for a novel technique to treat spinal stenosis in a less invasive fashion, sparing the normal anatomic structures and lessening the risks of spinal surgery.
The present invention provides a method and a spinal canal expansion device to correct spinal stenosis by a minimally invasive technique that lessens the risk of bleeding, scarring, muscle damage and spinal instability inherent in current techniques. In one aspect of the invention, a spinal canal is expanded by establishing implant fixation of dorsal vertebral elements, cutting a vertebra in two locations to separate the dorsal vertebral elements from a remainder of the vertebra, establishing implant fixation of the remainder of the vertebra, and separating the dorsal spinal elements of the vertebra from the remainder of the vertebra, through use of the spinal canal expansion device, to expand the spinal canal. Separation involves use of a distracting mechanism, communicating with each of the fixated dorsal vertebral elements and the fixated remainder of the vertebra, to elevate the dorsal vertebral elements from the remainder of the vertebra.
Embodiments of the present invention will be seen variously to: lessen the size of the incisions necessary to perform spinal decompression;
avoid removing normal portions of the spinal column, such as the lamina and spinous process;
lessen the risk of bleeding or scarring inherent in traditional spinal decompression surgery;
lessen the risk of spinal instability following spinal decompression surgery; allow spinal decompression to be achieved by a minimally invasive technique;
improve lordosis of the cervical or lumbar region during the spinal decompression procedure; and
provide fixation for a spinal fusion procedure if needed during the spinal decompression procedure.
In one aspect of the invention, a method for correcting spinal stenosis involves expanding the spinal canal by cutting the spinal lamina bilaterally and using spinal implant(s) to elevate the spinous process and lamina away from the spinal cord and nerve sac, thus decompressing the spinal canal. In another aspect of the invention, the spinal canal expansion device used for correcting spinal stenosis includes expandable linkage to both elevate the lamina and spinous process, and to fixate the vertebra in the expanded state using a stabilizing bar attached to the spinous process. In another aspect, suboptimal lordosis of the spine can be corrected by the action of the spinal canal expansion device, which imparts an anteriorly-directed force vector to the vertebral body that improves lordosis of the treated spinal segment.
Generally, the spinal canal expansion device of the present invention includes a dorsal vertebral device connected to a dorsal vertebral element of the vertebra, a vertebral fixation device connected to a vertebral element more anterior than the dorsal vertebral element, and a connecting device. The connecting device generally provides communication between the dorsal vertebral device and the vertebral fixation device. In use, the connecting device spans a dorsal vertebral osteotomy, and includes a distracting mechanism operating to translate the dorsal vertebral element, via anteriorly-directed force, in a dorsal direction relative to the more anterior vertebral element. The dorsal vertebral osteotomy is thereby separated resulting in expansion of the spinal canal.
The present invention has multiple advantages over current known methods and implants for treating spinal stenosis:
(1) The maintenance of normal anatomic structures including the spinous process, lamina and muscles of the dorsal spine;
(2) The ability to correct spinal stenosis with a minimally invasive procedure;
(3) The ability to provide secure fixation for healing of the spine in the expanded state;
(4) The ability to provide secure fixation for treating coexistent spinal stenosis;
(5) The ability to minimize bleeding, scaring, muscle damage and risk of instability following surgery; and
(6) The ability to improve spinal lordosis.
The drawings herein are included for the purpose of illustrating preferred embodiments of the present inventions; however, it should be realized that the invention is not limited to the precise arrangements and/or sequence of steps shown.
a and 2b illustrate perspective views of an adjustable connector;
a and 3b illustrates perspective views of a jack component;
a and 4b illustrates perspective views of the assembly of the adjustable connector and the jack component;
a and 7b illustrate perspective views of the spinal canal expansion device in un-raised (
a and 9b illustrate the action of the spinal canal expansion device on the spinal lamina, showing expansion of the spinal canal by the dorsal movement of the spinal lamina through the action for the spinal canal expansion device.
Referring now to the drawings, wherein like numerals indicate like elements, there is shown in
a and 2b illustrate one embodiment of a component of a connecting device of the present invention. The embodiment of
a and 3b illustrate prospective views of one embodiment of another component of the connecting device of the present invention. The embodiment of
a and 4b illustrate prospective views of an assembled adjustable connector 10 and jack component 30, together illustrating one embodiment of a distracting mechanism of the connecting device of the present invention. Note that the sliding section 20 of the adjustable connector 10 fits into the elevation slot 34 of the jack component 30. Jack screw 32 threadably engages the internally threaded grooves 22 of the sliding section 20 such that rotation of the jack screw 32 via the driver mechanism 31 will result in up or down (translational) movement of the sliding section 20 within the elevation slot 34. Also, note the location of the connecting tube 18, designed to attach to the transosseous fixation component 2 (of
More specifically, in one embodiment, the elongated locking bolt 50 threads down (internally) into the bone screw 53, via tightening mechanism 51, to secure the rod 58 within a hole in the head 54 of the bone screw 53. Otherwise, the rod 58 is capable of sliding within the hole in the head 54 of the bone screw 53. The bore 40 of the fixation tab 38 fits over the locking bolt 50 with a slightly loose connection. The locking nut 52 then threads onto the locking bolt 50 and is tightened to compress against, and thus secure, the fixation tab 38 to the bone screw 53.
a and 7b illustrate perspective views of an embodiment of the spinal canal expansion device, with distracting mechanism in an un-raised (
a and 9b illustrate the action of an embodiment of the spinal canal expansion device to expand the spinal canal 74. The transosseous fixation member 2 is seen traversing a bone bore 65 at the base of the spinous process 68. Bone screws 53 are seen anchored into the lateral masses 62, bilaterally. Osteotomies (bone cuts) 66 are seen dividing the lamina 60 bilaterally. In
Methods of the present invention involve establishing implant fixation of dorsal vertebral elements. In one specific embodiment, a bore 65 is drilled across a ventral portion of the spinous process 68, followed by placement of the transosseous fixation member 2 into and through the bore 65.
An osteotomy (bone cut) 66 is made, preferably in two locations, to separate the dorsal vertebral elements from a remainder of the vertebra. In one specific embodiment, osteotomies 66 are made in two locations, each along a lamina 60, on both sides of the vertebra, using techniques well known in the art of spinal surgery. The osteotomies (bone cuts) 66 are preferably made substantially along the lateral margins of the spinal cord.
Vertebral fixation devices are connected to vertebral elements more anterior than the dorsal vertebral element above. In one specific embodiment, bone fixation screws 53 are placed (threaded) into lateral masses 62 on each side of a vertebra, using techniques well known in the art of spinal surgery. Note that the bone screws 53 may be connected to one another by rods 58, when a spinal fusion is desired, or may be used without rods 58 when no fusion is desired.
A size of the connecting device and/or distracting mechanism can be adapted to the size of the patient. In a specific embodiment, the jack component 30 and the sliding section 20 size is preferably selected by measuring a distance between the end of the transosseous fixation rod 2 and the respective screw head 54. An appropriately sized jack component 30 and sliding section 20 are selected to accommodate this distance.
The various components are connected; that is, the dorsal vertebral device, the vertebral fixation device, and the connecting device. In one specific embodiment, the assembled jack component 30 and adjustable connector 10 are preferably attached to a respective head 54 of the bone screw 53 by placing the fixation bore 40 of the fixation tab 38 over an elongated locking bolt 50, then threadably attaching and tightening a locking nut 52 to the locking bolt 50 of each bone screw 53. In addition, the connecting tube 18 is fit over the connection member 6 of the transosseous fixation rod 2; then the fixation bolt 14 is tightened to secure the connection of the adjustable connector 10 to the transosseous fixation rod 2. Recall that the connecting member 6 has rounded ends to allow angulation between the transosseous fixation member 2 and the adjustable connector 10, when connected (see
To expand the spinal canal, in this embodiment, the jack screw 32 is turned (via driver mechanism 31) to elevate (raise) the sliding section 20 within the elevation slot 34 of the jack component 30. By this action, the transosseous fixation rod 2 moves in a dorsal direction, and elevates the attached spinous process 68 and lamina 60 portion, resulting in expansion of the spinal canal 72 (see
The application claims benefit of priority of U.S. Provisional Application No. 61/301,809, filed Feb. 5, 2010. U.S. Provisional Application No. 61/301,809, is incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
61301809 | Feb 2010 | US |