The present invention relates to a method and system for preparing a surgical site for receiving an implantable device. Specifically, the present invention relates to a method and system for preparing the interspinous space, including the spinous processes, for receiving an interspinous stabilization device.
Conventional methods for implanting interspinous devices provide little or no control over the exact positioning of the device in an implantation site. Typically, if the surgeon desires more surface contact between the device and the bony surface of the spinous processes, the surgeon can remove bone tissue using a cutting tool such as, for example, a chisel, luer plier, or power cutting tool. However, these freestyle methods do not allow precise shaping or contouring of the spinous processes, nor do they provide exact control over the positioning of the device. Improper or incorrect placement of the device may lead to less than optimal results, including failure of the device, resulting in detrimental effects to the patient. When using interspinous devices to treat multiple vertebral levels, proper alignment is even more critical to ensure a desirable outcome.
There is thus a need for a system and method for preparing the implantation site for receiving an implantable device. More importantly, there is a need for a system and method that allow precise control over the shaping or contouring of the interspinous space and proper insertion of the implantable device into that space.
A first aspect of the present invention includes a system for preparing an implantation space. The system may be used to guide a bone cutting tool to enable accurate and controlled shaping or contouring of the spinous processes defining an interspinous space. In one exemplary embodiment, a system is provided for preparing an interspinous space to receive an implantable device. The system may comprise a cutting tool guide having a guiding surface for directing a cutting tool therethrough and a holder for positioning the cutting tool guide relative to the interspinous space. The holder may be configured to adjustably attach to a bony structure of a patient's spine. In one exemplary embodiment, the holder may be attachable to at least one of a pair of spinous processes defining the interspinous space.
A second aspect of the present invention includes a method for preparing an implantation site. The method may allow preparation of an interspinous space for receiving an implantable device. In one exemplary embodiment, a method is provided which involves selecting an implantable device for placement in the interspinous space, positioning a cutting tool guide between a pair of spinous processes defining the interspinous space, shaping at least one of the pair of spinous processes, and inserting the implantable device into the shaped interspinous space.
A third aspect of the present invention provides a method for guided shaping of a spinous process. In one exemplary embodiment, a method is provided which involves positioning a cutting tool guide adjacent a spinous process, the cutting tool guide comprising a guiding surface for directing a cutting tool therethrough, and directing a cutting tool against the guiding surface and into the spinous process to shape the spinous process.
A forth aspect of the present invention includes a cutting tool guide. The cutting tool guide may be used to guide a bone cutting tool to enable accurate and controlled shaping or contouring of the spinous processes defining an interspinous space. In one exemplary embodiment, the cutting tool guide may comprise a main body portion having first and second side walls parallel to one another, each side wall having first and second ends, an inner surface, and an outer surface, and an end wall connecting the first ends of the first and second side walls to one another such that the inner surfaces of the side walls face one another. The cutting guide tool may further comprise at least one pair of guiding slots configured to receive side edges of a cutting tool, wherein one slot of the pair is on the inner surface of the first side wall and the other slot of the pair is on the inner surface of the second side wall.
A fifth aspect of the present invention provides a method for guided shaping of a spinous process. In one exemplary embodiment, a method is provided which involves positioning a cutting tool guide adjacent a spinous process, the cutting tool guide comprising a pair of parallel walls, each wall having first and second ends and at least one guiding slot for directing a cutting tool therethrough, and directing a cutting tool through one of the at least one guiding slots on each of the parallel walls and into the spinous process to shape the spinous process.
A sixth aspect of the present invention includes a bone cutting tool for preparing an implantation space. The bone cutting tool may be used accurately shape or contour the spinous processes defining an interspinous space. In one exemplary embodiment, a bone cutting tool is provided for preparing an interspinous space to receive an implantable device. The bone cutting tool may comprise a main body portion having first and second side walls and a front wall portion, the front wall portion configured to contact a bony surface to be shaped and a cutting element configured to shape the bony surface, the cutting element positioned between the first and second side walls on a front portion of the main body. In one exemplary embodiment, the front wall portion lies in a first plane and the cutting element lies in a second plane parallel to the first plane and spaced away from the first plane.
A seventh aspect of the present invention includes a bone cutting tool for preparing an implantation space. The bone cutting tool may be used accurately shape or contour the spinous processes defining an interspinous space. In one exemplary embodiment, a bone cutting tool is provided for preparing an interspinous space to receive an implantable device. The bone cutting tool may comprise a main body portion having first and second side walls, a rear wall, and a front wall portion, the front wall portion configured to contact a bony surface to be shaped and a cutting element configured to shape the bony surface, the cutting element positioned between the first and second side walls on a front portion of the main body. In one exemplary embodiment, the front wall portion is positioned a first distance from the rear wall and wherein the cutting element is positioned a second distance, greater than the first distance, from the rear wall.
An eighth aspect of the present invention provides a method for guided shaping of a spinous process. In one exemplary embodiment, a method is provided which involves providing a cutting tool having a cutting guide surface, determining an amount of thickness T to remove from a spinous process, positioning a cutting tool cutting element relative to the cutting tool guide surface such that there is a distance T between a plane in which the guide surface lies and a plane in which the cutting element lies, positioning the cutting tool guide surface adjacent a spinous process, and moving the cutting tool guide surface and the cutting tool cutting element over the spinous process such that the cutting tool cutting element engages any bony material that extends within the distance T between the cutting guide surface and the cutting tool cutting element
It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only, and are not restrictive of the invention, as claimed.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate several embodiments of the invention and together with the description, serve to explain the principles of the invention.
Additional objects and advantages of the invention will be set forth in part in the description which follows or may be learned by practice of the invention. The objects and advantages of the invention will be realized and attained by means of the elements and combinations particularly pointed out in the appended claims.
The cutting tool guide 20 may also include handles 28 for manipulating the guide 20 during use. The handles 28 may be shaped for easy gripping with fingers. The main body 22 may also include a depressible tab 30 formed on a side thereof. The depressible tab 30 may be defined by a pair of slots 32 located on the main body 22. A notch 34 may be included on the depressible tab 30 to allow the cutting tool guide 20 to latch onto a guide holder 60, shown in
The main body 22 of cutting tool guide 20 may also include an opening 36 for insertion of a radiopaque marker 38. As shown in
The guide holder 60 may further include a pair of clamps 64. As shown in greater detail in
It is contemplated that the clamps 64 of the guide holder 60 may have a different configuration so long as the function of securing the guide holder 60 to a bony structure of the spine is preserved. For example, the clamps 64 may be configured as a wrench-like device, with a locking nut element for securing the wrench-like device onto bone. Other mechanisms for securing the holder to bone may be implemented without departing from the spirit of the invention. For example, jaws 66 may include various surface modifications that facilitate secure attachment to bone. Such surface modifications may include, for example, barbs, teeth 80 (as shown in
The cutting tool guide and holder system of
To use the cutting tool guide and holder system, a surgeon may first select one or more vertebral levels to be treated. Based on patient characteristics and the surgeon's preference, the surgeon will then select the implant to be used. Before implanting the device, the surgeon may wish to determine the dimensions of the interspinous space where the device is to be placed and compare that to the size of the device to be implanted. To do so, the surgeon may elect to place a series of trials 90 into the interspinous space, as is conventionally known to be done, until the proper size and device orientation has been determined, as shown in
Next, the surgeon may place a cutting tool guide 20 having an aperture 24 corresponding in size and shape to the trial 90 onto a guide holder 60, and slip the two over the trial 90, as shown in
Removing the trial 90 and then the cutting tool guide 20, as shown in
The cutting tool guide and holder system of the present invention enables accurate and controlled shaping or contouring of the spinous processes defining an interspinous space for receiving an implantable device. The cutting tool guide 20, 40 enables the cutting tool to be directed into bone in a specific and controlled manner, while the radiopaque markers 38 also allow visual confirmation of the proper cutting line and depth when used under fluoroscopy. Further, the guide holder 60 is flexibly configured to be adjustable in position, cutting height, and angle relative to the interspinous space in order to optimize the ability of the guide holder 60 to be applied to different levels of the spine for multi-level or multi-segmental applications of the interspinous implantable device.
It is contemplated that the cutting tool guide and holder system of the present invention may be applied using other methods to shape the spinous process. For instance, it is understood that the guide holder 60 may be attached to other patient anatomies rather than the spinous processes defining the interspinous space. The guide holder 60 may be configured to attach to, for example, the lamina or transverse processes of the patient. In addition, it is possible to use the cutting tool guide 20, 40 to direct the angle, depth, and/or position of the cutting tool without attaching the cutting tool guide 20, 40 to the patient. If desired, the surgeon may simply use the cutting tool guide 20, 40 alone to align and direct the cutting line of the bone cutting tool.
Further, although a system and method for preparing an interspinous space is described for use with an interspinous implant, it is contemplated that the system of the present invention can also be utilized in any application where exact shaping or contouring of the spinous process is desired. For example, it is possible to use the cutting tool guide 20, 40 and guide holder 60 to direct shaping and/or contouring of the spinous process for decompression.
As further shown in
The cutting tool guide 120 may be held in place or moved to a different position through use of a handle 134. Handle 134 is connected to lip portion 132. As shown in
The cutting tool guide of
To use the cutting tool guide 120 a surgeon may first select one or more vertebral levels to be treated as described previously with respect to
Next, the surgeon may place a cutting tool guide 120 into the interspinous spaced defined by a pair of spinous processes 10, 12. As shown in
When the cutting tool guide 120 is held in position with third wall 126 aligned with spinous process 12, the spinous process 10 may be contoured. The surgeon may then insert a cutting tool matching the shape and/or size of the implantable device, such as for example, the chisel 150 shown in
If desired, the chisel 150 may be removed from a first set of guiding slots 130a, 130b, the cutting tool guide 120 removed from the interspinous space (or left in place) and the trial 90 may be reinserted to judge fit. If necessary, the cutting tool guide can be reinserted into the interspinous space and another pair of guiding slots 130a, 130b used with blade 154 to remove additional bone as needed. Subsequently, if desired, the cutting tool guide 120 may be rotated 180 degrees within the interspinous space to permit shaping or contouring of the other spinous process 12 of the pair. It is understood that a plurality of cutting tool guides 120 having differently sized and/or shaped spaces 127 may be provided in order to accommodate variously sized and/or shaped patient anatomies. Additionally, different cutting tool guides 120 having differently spaced guiding slots 130a, 130b, or having guiding slots 130a, 130b that are provided in parallel to one another or at an angle to one another may also be used.
It is contemplated that the cutting tool guide 120 of the present invention may be applied using other methods to shape the spinous process. For instance, it is understood that the cutting guide tool 120 may be used with portions of the method described with respect to cutting guides 20, 40. In addition, it is possible to use the cutting tool guide 120 to direct the angle, depth, and/or position of the cutting tool while attaching the cutting tool guide 120 to the patient, for example with guide holder 60.
Further, although a system and method for preparing an interspinous space is described for use with an interspinous implant, it is contemplated that the system of the present invention can also be utilized in any application where exact shaping or contouring of the spinous process is desired. For example, it is possible to use the cutting tool guide 120 to direct shaping and/or contouring of the spinous process for decompression.
As shown in
As shown in
Alternatively, the position of blade 220 may not be adjustable and thus the distance T between the surface of the partial front wall 208 and the blade 220 would be fixed for the cutting tool. In such an embodiment, blade 220 may be removable from the main body 202 and replaceable with an alternative blade 220a, 220b, 220c (not shown) having a different geometry and providing a different distance T between the surface of the partial front wall 208 and the blade 220a, 220b, 220c. It is also envisioned that a surgeon could be provided with a plurality of main bodies 202, each having a blade with a different blade geometry and thus a different distance T between the surface of the partial front wall and the blade 220. The surgeon could then choose the main body having the desired cutting thickness T. In such a case, each main body could have a handle permanently attached, or a detachable handle could be provided for use with any main body 202.
As also shown in
The bone cutting tool with cutting guide 200 also includes a handle 230. As shown in
To use the bone cutting tool with cutting guide 200, a surgeon may first select one or more vertebral levels to be treated. Based on patient characteristics and the surgeon's preference, the surgeon will then select the implant to be used. Before implanting the device, the surgeon may wish to determine the dimensions of the interspinous space where the device is to be placed and compare that to the size of the device to be implanted. To do so, the surgeon may elect to place a series of trials 90 into the interspinous space, as is conventionally known to be done, until the proper size and device orientation has been determined, as was discussed with regard to
Once the desired dimensions of the interspinous space are known, the surgeon may select a surface of the interspinous space for shaping or contouring. As shown in
The surgeon then positions the tool with the front side facing and in contact with the bone surface to be shaped and at a lowermost point of the bone surface to be shaped (e.g., the most anterior portion of a spinous process to be shaped). The tool is drawn upward (e.g., posteriorly along the spinous process) along the bone surface and away from the patient's body, and any bone extending above the cutting guide (partial front wall 208) is cut by blade 220 and passes through opening 210 in the front of the tool and into cavity 226. The surgeon can repeat the process of drawing the tool upward and along the bone surface until the desired shape of the bone surface is achieved. If necessary, the back panel 212 may be removed and the bone chips emptied from the cavity 226. The process then may be repeated as necessary for the other spinous process forming the interspinous space.
Although both the blade 220 and the partial front wall 208 are disclosed as being planar surfaces, it is contemplated that one or both of the surfaces may be provided with a slight curve or contour to permit a variety of shaping and contouring of the bone surface of the interspinous space.
Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.
This application is a divisional of U.S. patent application Ser. No. 11/676,141, filed Feb. 16, 2007, now U.S. Pat. No. 9,011,441, which claims priority to 35 U.S.C. §119 based on U.S. Provisional Application No. 60/774,571, filed Feb. 17, 2006, the complete disclosures of which are incorporated herein by reference.
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Child | 14691522 | US |