The natural intervertebral disc contains a jelly-like nucleus pulposus surrounded by a fibrous annulus fibrosus. Under an axial load, the nucleus pulposus compresses and radially transfers that load to the annulus fibrosus. The laminated nature of the annulus fibrosus provides it with a high tensile strength and so allows it to expand radially in response to this transferred load.
In a healthy intervertebral disc, cells within the nucleus pulposus produce an extracellular matrix (ECM) containing a high percentage of proteoglycans. These proteoglycans contain sulfated functional groups that retain water, thereby providing the nucleus pulposus within its cushioning qualities. These nucleus pulposus cells may also secrete small amounts of cytokines such as interleukin-1β and TNF-α as well as matrix metalloproteinases (“MMPs”). These cytokines and MMPs help regulate the metabolism of the nucleus pulposus cells.
In some instances of disc degeneration disease (DDD), gradual degeneration of the intervetebral disc is caused by mechanical instabilities in other portions of the spine. In these instances, increased loads and pressures on the nucleus pulposus cause the cells within the disc (or invading macrophases) to emit larger than normal amounts of the above-mentioned cytokines. In other instances of DDD, genetic factors or apoptosis can also cause the cells within the nucleus pulposus to emit toxic amounts of these cytokines and MMPs. In some instances, the pumping action of the disc may malfunction (due to, for example, a decrease in the proteoglycan concentration within the nucleus pulposus), thereby retarding the flow of nutrients into the disc as well as the flow of waste products out of the disc. This reduced capacity to eliminate waste may result in the accumulation of high levels of toxins that may cause nerve irritation and pain.
As DDD progresses, toxic levels of the cytokines and MMPs present in the nucleus pulposus begin to degrade the extracellular matrix, in particular, the MMPs (as mediated by the cytokines) begin cleaving the water-retaining portions of the proteoglycans, thereby reducing its water-retaining capabilities. This degradation leads to a less flexible nucleus pulposus, and so changes the loading pattern within the disc, thereby possibly causing delamination of the annulus fibrosus. These changes cause more mechanical instability, thereby causing the cells to emit even more cytokines, thereby upregulating MMPs. As this destructive cascade continues and DDD further progresses, the disc begins to bulge (“a herniated disc”), and then ultimately ruptures, causing the nucleus pulposus to contact the spinal cord and produce pain.
One proposed method of managing these problems is to remove the problematic disc and replace it with a porous device that restores disc height and allows for bone growth therethrough for the fusion of the adjacent vertebrae. These devices are commonly called “fusion devices”, or “interbody fusion devices”.
Current spinal fusion procedures include approaches such as transforaminal lumbar interbody fusion (TLIF), posterior lumbar interbody fusion (PLIF), and extreme lateral interbody fusion (XLIF). TLIF and PLIF spinal fusion surgeries require refraction of neural tissues including the spinal cord and/or exiting nerve roots. Retraction is typically performed with hand held dural retractors that are manually placed and secured by an operative assistant who is standing on the contralateral side of the patient.
This position across from the surgeon greatly reduces visibility of the neural retraction for the operative assistant, increasing the risk of neural damage. Frequent adjustment of the retractor is required to ensure proper positioning, distance and the amount of dural retraction force applied. Significant patient risk, including dural tears, can be incurred if excessive retraction is applied or if the spinal cord is inadvertently released during the procedure.
In addition, the presence of the neural retractor crowds or obscures the surgical site, thereby minimizing visibility and access to the disc space for the operating surgeon.
Cloward, “A Self-Retaining Spinal Dural Retractor” J Neurosurg., 1952 March; 9(2):230-2, discloses a modified Hoen laminectomy retractor having a retraction spatula.
U.S. Pat. No. 7,569,054 (Michelson) discloses a tubular member having a passage and opposing bone penetrating extensions adapted to piece opposed vertebral bodies.
The objective of this device is to reduce operative site crowding to enhance disc access while providing for consistent and stable dural retraction.
The present inventors have developed a device and a method for neural tissue retraction for spinal surgery that overcomes the disadvantages associated with conventional spinal cord retraction.
In particular, the device is a self-retaining retractor clip. When used in spinal surgery, the self-retaining nature of the clip eliminates the need to continuously manually retract the neural structures.
Preferred devices of the present invention include a) a self-retaining neural retraction clip, b) a neural retraction clip with controlled refraction level, and c) a neural retraction clip with off-set retraction means.
Therefore, in accordance with the present invention, there is provided a neural tissue retractor comprising:
Now referring to
Therefore, in accordance with the present invention, there is provided a neural tissue retractor 10 comprising:
In some embodiments, the curved intermediate portion comprises a portion of substantially a circle. Preferably, the portion of the circle defines an arc of at least about 270 degrees, more preferably at least 300 degrees.
In some embodiments, each foot has at least two teeth extending therefrom. Preferably, each foot extends substantially perpendicularly from its respective leg.
In some embodiments, the two legs of the present invention are substantially parallel to define a plane. In some embodiments, thereof, the curved intermediate portion lies substantially in the plane formed by the two legs. In other embodiments, the curved intermediate portion extends out of the plane formed by the two legs. This curve can lie in a multitude of planes. In some embodiments, (as in
In some embodiments, the interior of the curved intermediate portion of the clip is substantially open (as in
Also in accordance with the present invention, there is provided a method of preserving retraction of a neural tissue (such as a spinal cord), comprising the steps of:
Now referring to
Therefore, in accordance with the present invention, there is provided a neural tissue retractor 20 comprising:
In some embodiments (as in
In some embodiments (as in
Now referring to
Therefore, in accordance with the present invention, there is provided a neural tissue retractor 40 comprising:
In some embodiments, the retractor shield is curved. In some embodiments, the retractor shield is connected to the curved intermediate portion substantially at the apex 48 of the curved intermediate portion (i.e., the portion opposite the legs). In some embodiments, the shield is connected to the curved intermediate section to form a substantially V-shaped clip (as shown in
In some embodiments, insertion of the clip of the present invention is accomplished by using clamping forceps to secure the legs of the clip and squeeze them into a compressed configuration. Now referring to
Preferably, the inserter can be shielded to minimize inadvertent damage to soft tissue or neural tissue. Also preferably, the inserter device can be used to extract the clip from the patient after the operation is completed.
Therefore, now referring to
Preferably, the inserter receptor is a loop.
Now referring to
Therefore, in some embodiments, the retractor clip 90 of the present invention has a tether 91 attached thereto. In some embodiments, the tether is attached to the shield 93. In some embodiments, the tether is attached to the curved intermediate portion. In some embodiments, the tether is attached to at least one leg.
Now referring to
The neural retraction clip of the present invention can be produced from a variety of biocompatible metals or plastics. Suitable metals include stainless steel, titanium, nitinol or cobalt-chrome. Selection of these materials will allow the clip to be first squeezed to produce elastic compression for insertion and then released to produce expansion for vertebral body securement. A semi-rigid to rigid polymer with shape memory properties such as PEEK, polypropylene, polyethylene can also be utilized. These materials would allow multiple compression cycles without structural fatigue as well as radio-lucency to enable intra-operative imaging of the surgical site. Hybrid components can also be selected , and include producing the spikes and clip from TiN for expansion and the shield from a conformable polymer (like polypropylene) to maximize conformance to the neural tissues. The material selection can provide either elastic or plastic deformation.
This application claims priority from co-pending U.S. Ser. No. 12/641,476, filed Dec. 18, 2009,(Tannoury et al.) (DEP6277USNP), the specification of which is incorporated by reference in its entirety.
Number | Date | Country | |
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Parent | 12641476 | Dec 2009 | US |
Child | 13925145 | US |