Percutaneous Transverse Connector System
A system and method for stabilizing a spine of an animal subject involving a transverse rod installation instrument assembly for inserting a transverse rod on the spine of a subject percutaneously comprising: a first rod clamp extender mounted on a ipsilateral rod clamp and a second rod clamp extender mounted on a contralateral rod clamp wherein the ipsilateral rod clamp and the contralateral rod clamp are secured to a vertebra at the ipsilateral and contralateral pedicle; and a pivoting installation instrument pivotably mounted to the first rod clamp extender and the second rod clamp extender to pass a transverse rod percutaneously through a head portion of the ipsilateral side rod clamp and to the head portion of the contralateral rod clamp after passing through a spinous process of the vertebra through pivot axis “A” such that the transverse rod is secured at the head portion of the ipsilateral rod clamp and the head portion of the contralateral rod clamp.
This application is a division of U.S. patent application Ser. No. 15/141,745, entitled “Percutaneous Transverse Connector”, filed on Apr. 28, 2016, and issued on Oct. 1, 2019 as U.S. Pat. No. 10,426,528, which is a continuation of International Application PCT/US14/63152, entitled “Percutaneous Transverse Connector System”, filed Oct. 30, 2014, which claims priority to and the benefit of the filing of U.S. Provisional Patent Application No. 61/898,332, entitled “Percutaneous Transverse Connector System”, filed on Oct. 31, 2013, and the specification and claims thereof are incorporated herein by reference.
STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENTNot Applicable.
INCORPORATION BY REFERENCE OF MATERIAL SUBMITTED ON A COMPACT DISCNot Applicable.
COPYRIGHTED MATERIALNot Applicable.
BACKGROUNDThe system and method of this invention relates to an implantable spinal fixation system for the surgical treatment of spinal disorders and apparatus for implantation.
Spinal column disorders such as scoliosis, kyphosis, lordosis, spondylolisthesis, ruptured, broken, fractured or slipped discs are treated with spinal fixation. Spinal fixation uses surgical implants or constructs which mechanically immobilize the treated area of the spine with the goal of causing the fusion of the treated vertebrae. One type of spinal fixation utilizes a pair of longitudinal rods that run parallel or longitudinally along the spine and are affixed to pedicles of the appropriate vertebrae or to the sacrum and act as anchor points for the longitudinal rods. Bone screws are generally placed two per vertebrae with one at each pedicle on either side of the spinous process of the vertebrae. Clamp assemblies join the spine rods to the screws. When a pair of transverse rod/connectors are fastened in parallel on either side of the spinous process, the assembly can be significantly strengthened. However, the instrumentation with transverse rods described requires open surgery and a large incision. In doing so, the skin and tissue surrounding the surgical site must be cut, removed and or repositioned in order for the surgeon to access the location where the stabilization device is to be installed. This type of invasive surgery leads to risk of long recovery time, disruption of muscle, trauma damage and scarring to the tissue.
In recent years minimally invasive spinal (MIS) procedures have become more common. The advantages of MIS procedures compared with open surgery are less pain, faster recovery, less intra-operative blood loss, and generally greater patient satisfaction. With the advent of innovative devices and techniques, physicians now routinely perform MIS procedures that traditionally would require open surgery. One of the shortcomings of MIS procedure/surgery is the inability to place a transverse connector through a percutaneous route. Transverse connectors are used during spinal instrumentation procedures to add rigidity to the overall construct offered by longitudinal rods alone. Transverse rods add stability during axial rotation (twisting) and lateral bending (side to side bending) of the spine. During open procedures the placement of transverse connectors are straight forward but require muscle dissection as well as other downsides mentioned herein.
Minimally invasive surgery wherein a long incision through a muscle group such as those along the spine to expose multiple levels of vertebrae is not required. Minimally invasive surgery may be achieved with percutaneous minimally invasive spinal procedures where minimal if any muscle dissection is required. Currently minimally invasive surgery is not available to insert transverse rods into the spine, for example, to add rigidity to an instrumentation construct consisting of pedicle screws and longitudinal rods involving multiple levels of vertebrae.
BRIEF DESCRIPTION OF THE INVENTIONOne embodiment of the present invention provides a transverse rod installation instrument assembly for inserting a transverse rod on the spine of a subject percutaneously. A first rod clamp extender is mounted on an ipsilateral rod clamp and a second rod clamp extender is mounted on a contralateral rod clamp wherein the ipsilateral rod clamp and the contralateral rod clamp are secured to a vertebra at the ipsilateral and contralateral pedicle. A pivoting installation instrument is pivotably mounted to the first rod clamp extender and the second rod clamp extender to pass a transverse rod percutaneously through a head portion of the ipsilateral side rod clamp and to the head portion of the contralateral rod clamp after passing through a spinous process of the vertebra through pivot axis “A” path such that the transverse rod is secured at the head portion of the ipsilateral rod clamp and the head portion of the contralateral rod clamp. Further, the first rod clamp extender has a cylinder with a pair of opposing arms that extends superior to the cylinder wherein at the bottom of the cylinder is a docking ring for engaging with the bolts on a pair of opposing wings of the ipsilateral rod clamp assembly when the cylinder of the first rod clamp extender is positioned over the pair of opposing wings. The pair of opposing arms on the first rod clamp extender includes a hole in each arm of the pair wherein the hole in each arm of the pair of opposing arms aligns. The second rod clamp extender has a cylinder with a pair of opposing arms that extends superior to the cylinder wherein at the bottom of the cylinder is a docking ring for engaging with the bolts on a pair of opposing wings of the contralateral rod clamp assembly when the cylinder of the second rod clamp extender is positioned over the pair of opposing wings. The docking ring has an internal grove for securing the bolt on the side of the wing of the rod clamp assembly when the rod clamp assembly is in use to stabilize the extender onto the rod clamp assembly. The pair of opposing arms on the second rod clamp extender includes a hole in each arm of the pair wherein the hole in each arm of the pair aligns. The first rod clamp extender and the second rod clamp extender are secured together with a bolt that fits through each hole in each arm of the pair of opposing arms of the first rod clamp extender and each hole in each arm of the pair of opposing arms of the second rod clamp extender such that the bolt passes first through an arm of a first rod clamp extender and then through an arm of the second rod clamp extender before passing through the opposing arm of the first rod clamp extender and then the opposing arm of the second rod clamp extender. The pivoting installation instrument pivotably mounted to the first rod clamp extender and the second rod clamp extender is secured to the first rod clamp extender and the second rod clamp extender via the bolt.
Another embodiment of the present invention provides for an orthopedic clamp system for use with a rod for immobilizing bone comprising a rod clamp assembly having a clamp with an upper surface and a lower surface and a rod receiving section positioned superior to the clamp the rod receiving section having a pair of opposing wings that extend from the rod receiving section. The clamp includes a tightening screw through its upper surface for securing the clamp to a longitudinal rod immobilized to the bone and a polyaxial head that is positioned between the rod receiving section and the clamp. The polyaxial head allows for freedom of movement when positioning a transverse rod passer in the rod receiving section. The rod receiving section is threaded to mate with a set screw to tighten a transverse rod positioned in the rod receiving section. The pair of opposing wings include a bolt on an outer surface of the pair of opposing wings used to secure a docking ring of a rod clamp extender when the rod clamp extender is positioned over the pair of opposing wings. The pair of opposing wings create an open space along the length “L” of the rod clamp assembly which space permits a transverse rod receiving section to be observed from above. The wings above the rod receiving section are releaseably attached to the rod receiving section.
Another embodiment of the present invention provides for a method for inserting a transverse spinal rod into a patient comprising attaching a first rod clamp assembly onto a first longitudinal rod that is secured to a first vertebrae having a first side of a spinous process of the patient wherein the first rod clamp assembly is introduced to the longitudinal rod through a first minimally invasive incision on the back of the patient at the level of the first vertebrae. A second rod clamp is attached to the assembly onto a second longitudinal rod that is secured to the first vertebrae on a second side of the spinous process of the patient wherein the second rod clamp assembly is introduced to the longitudinal rod through a second minimally invasive incision on the back of the patient at the level of the first vertebrae. A first rod clamp extender is placed onto a pair of opposing wings of the first rod clamp assembly. A clamp of the first rod clamp assembly is secured to the first longitudinal rod with a screw on the upper surface of the clamp of the first rod clamp assembly. A second rod clamp extender is secured onto a pair of opposing wing of the second rod clamp assembly. A clamp of the second rod clamp assembly is secured to the second longitudinal rod with a screw on the upper surface of the clamp of the second rod clamp assembly. An extracorporeal portion of the first rod clamp extender is secured to an extracorporeal portion of the second rod clamp extender via a transverse rod passer pivotably mounted to the first rod clamp extender and the second rod clamp extender about a pivot axis “A” whose pivot axis passes through the head of the first rod clamp assembly, the spinous process, and the head of the second rod clamp assembly. A transverse rod opening is created in the spinous process by piercing the spinous process with an awl that is directed to the spinous process via the transverse rod passer as the transverse rod passer is moved through pivot axis “A” path percutaneously. The transverse rod connector is inserted into the head of the second rod clamp assembly after passing through the spinous process and through the head of the first rod clamp assembly via the transverse rod connector guiding the transverse rod through pivot axis “A” path. The transverse rod is secured to the first rod clamp assembly.
Further still, the transverse rod is connected to a handle with a flexible section that is removable from the transverse rod for allowing the transverse rod to be positioned in a guide tube of the transverse rod passer. An awl for creating an opening in the spinous process includes a handle having a flexible shaft and a sharp tip portion that is inserted through the guide tube of the transverse rod passer. The first rod clamp assembly and the second rod clamp assembly is disconnected from the transverse rod passer. The screw on the upper surface of the clamp of the first rod clamp assembly is tightened with a screw driver inserted percutaneously. The pair of opposing wings of the first rod clamp assembly is detached from the head portion leaving the head portion secured to the transverse rod.
Further scope of applicability of the present invention will be set forth in part in the detailed description to follow, taken in conjunction with the accompanying drawings, and in part will become apparent to those skilled in the art upon examination of the following, or may be learned by practice of the invention. The objects and advantages of the invention may be realized and attained by means of the instrumentalities and combinations particularly pointed out in the appended claims.
The accompanying drawings in the attachment, which are incorporated into and form a part of the specification, illustrate one or more embodiments of the present invention and, together with the description, serve to explain the principles of the invention. The drawings are only for the purpose of illustrating one or more preferred embodiments of the invention and are not to be construed as limiting the invention. In the drawings:
As used herein “a” or “an” means one or more.
One aspect of one embedment of a present invention provides for a system and method for placement of a transverse connector on the spine of an animal subject (e.g. human) wherein minimal if any muscle dissection is required.
A set of innovative instruments and method of using the same that allow precise placement of a transverse rod across the vertebrae to a transverse rod connector through a percutaneous route.
According to one embodiment of the present invention a method for spinal fusion of adjacent vertebral bodies is provided wherein an installation instrument for guiding a transverse rod to connect with a rod clamp through a minimally invasive incision is discussed. The method further provides that the transverse rod is passed through the head of an ipsilateral rod clamp and inserted through spinous process before connecting with the head of a contralateral rod clamp.
An aspect of the present invention provides a transverse rod installation instrument for transcutaneous placement of a transverse rod wherein the installation instrument is mounted to rod clamp extensions whose position is secured in an animal subject.
One aspect of one embodiment of the present invention is a minimally invasive method to stabilize bony structures.
One aspect provides for a method to connect two (2) or more rod clamps with a connecting element.
A method to attach a transverse rod inserter on an installation instrument to the extensions and guiding the transverse rod into a desired position relative to the rod clamps.
A fixed geometric relationship to guide the transverse rod into a position proximate to the rod clamps.
According to one embodiment of the present invention an installation instrument is mounted to the rod clamp extension element in spatial relation to the anchors about a pivot point. The instrument is rotated about the pivot point to guide the transverse rod to the desired location.
According to another embodiment of the present invention an installation instrument assembly is provided having an ispilateral rod clamp extension designed to slide onto the wings of an ipsilateral rod clamp and a contralateral rod clamp extension designed to slide onto the wings of a contralateral rod clamp. The rod clamp extensions each have an arm with a hole at the end of the arm through which the two rod clamp extensions are secured together. The installation instrument mounts to the ipsilateral and contralateral rod clamp extension arms when the rod clamp extensions are mounted to rod clamps positioned on either side of the spinous process of a vertebra. In this position, the two arms will overlap slightly when the rod clamp extensions are properly positioned on the rod clamps to allow the holes at the end of each arm to overlap. The installation assembly is held together with a fastener that passes through all four holes of the arms including the holes of the arms and the holes at the attachment ends of the installation instrument which sandwich the two holes of the arms to connect the installation instrument assembly together. The rod clamps to which the rod clamp extension are mounted are positioned on either side of spinous process and the rod clamps are secured to a pedicle of a vertebra structure with pedicle screws. The installation instrument is pivotable about a pivot axis that is formed by a line that runs through the holes of the side arms and holes of the attachment ends when assembled. The installation instrument is moveable with respect to the rod clamps to position a transverse brace through the spinous process of the vertebra and secure the ends of the transverse rod to the head of the ipsilateral and contralateral rod clamps.
Referring now to
Facial openings are made is the skin and muscle and a standard nasal speculum is used to visualize the rod clamp 100 and longitudinal rod 102.
Referring now to
The stabilizing tower is removed from the rod clamp wings. Referring now to
Referring now to
A skin and facial incision is made for when the awl 329 enters the skin on the Ipsilateral side of the body and the guide tube 309 is advanced until the spinous process is encountered. Referring now to
Referring now to
Referring now to
Although the invention has been described in detail with particular reference to these preferred embodiments, other embodiments can achieve the same results. Variations and modifications of the present invention will be obvious to those skilled in the art and it is intended to cover in the appended claims all such modifications and equivalents. The entire disclosures of all references, applications, patents, and publications cited above are hereby incorporated by reference
Claims
1. An orthopedic clamp system for use with a rod for immobilizing bone comprising:
- a rod clamp assembly having a clamp with an upper surface and a lower surface and a rod receiving section positioned superior to the clamp the rod receiving section having a pair of opposing wings that extend from the rod receiving section, the clamp including a tightening screw through its upper surface for securing the clamp to a longitudinal rod immobilized to the bone and a polyaxial head that is positioned between the rod receiving section and the clamp.
2. The orthopedic clamp system of claim 1 wherein the polyaxial head allows for freedom of movement when positioning a transverse rod passer in the rod receiving section.
3. The orthopedic clamp system of claim 1 wherein the rod receiving section is threaded to mate with a set screw to tighten a transverse rod positioned in the rod receiving section.
4. The orthopedic clamp system of claim 1 wherein the pair of opposing wings include a bolt on an outer surface of the pair of opposing wings used to secure a docking ring of a rod clamp extender when the rod clamp extender is positioned over the pair of opposing wings.
5. The orthopedic clamp system of claim 1 wherein the pair of opposing wings create an open space along the length “L” of the rod clamp assembly which space permits a transverse rod receiving section to be observed from above.
6. The orthopedic clamp system of claim 1 wherein the wings above the rod receiving section are releaseably attached to the rod receiving section.
Type: Application
Filed: Oct 1, 2019
Publication Date: Feb 6, 2020
Inventors: Stephanus V. Viljoen (North Liberty, IA), Andrew Grossbach (Iowa City, IA)
Application Number: 16/589,911