This application claims the benefit of US Provisional Application No. 61/234,245, filed on 14 Aug. 2009, which is incorporated in its entirety by this reference.
This invention relates generally to the surgical field, and more specifically to an improved implantable prosthetic cage in the medical implant field.
Back pain is one of the most common afflictions among people, and contributes to a significant portion of physician visits. Treatments for back pain include medication, therapy, exercises, and one aggressive treatment method called spinal fusion. Spinal fusion is a surgical procedure in which two or more vertebrae (bones of the spine) are combined and fused together. Spinal fusion is typically used to treat patients with spinal abnormalities and/or severe chronic pain, such as patients with degenerative disc disease, spinal disc herniation, vertebral fracture, and scoliosis (curvature of the spine). Conventional methods of performing spinal fusion involve bone grafting, in which a bone tissue graft is typically placed inside a hollow intervertebral “cage” that is inserted between vertebrae to be fused, and allows the bone graft to act as a bridge to promote bone growth that fuses the vertebrae. The intervertebral cage includes holes that allow bone tissue to form around and through the cage to connect the vertebrae.
However, a relatively recent development in spinal fusion is the use of bone morphogenetic proteins (BMPs), a group of proteins that induce the formation of bone and cartilage. BMPs can be manipulated into a carrier such as a sponge, putty, fluid, powder, or other matrix that can be used to enhance or replace bone grafts in intervertebral cages in spinal fusion procedures. Use of BMPs in spinal fusion increases the speed and reliability of bone fusion, and induces quicker patient recovery. However, even with careful surgical technique, the BMP carrier may become displaced during insertion of the intervertebral cage. BMP displacement through the holes of the intervertebral cage is difficult to remove and can cause significant complications, such as unintended extension of the spinal fusion, spinal deformities, and pain or paralysis-inducing compression of the spinal cord. Thus, there is a need in the medical implant field to create an improved implantable prosthetic cage. This invention provides such an improved prosthetic cage.
The following description of the preferred embodiments of the invention is not intended to limit the invention to these preferred embodiments, but rather to enable any person skilled in the art to make and use this invention.
1. Implantable Prosthetic Cage
As shown in
The hollow body 110 functions to hold a bone-growth promoting substance 140 and to selectively retain and direct the substance 140 in a controlled manner during implantation of the prosthetic cage. The shape of the hollow body 110 preferably approximates a rectangular prism and is adapted to be positioned on an anterior, posterior, and/or lateral side of the spinal cord between two vertebrae, but may alternatively be cylindrical, U-shaped, or any other suitable shape and size. The hollow body 110 is preferably rigid and made of PEEK or titanium, but may also be of varying stiffness and made of any suitable biocompatible material. The hollow body 110 may include features such as ridges, bumps, or spines that help retain the position of the prosthetic cage between two vertebrae after the prosthetic cage is implanted. Intervertebral cages are known and used by those skilled in the art, such as that described in U.S. Pat. No. 7,135,043 entitled “Intervertebral cage”, which is incorporated in its entirety by this reference.
The hollow body 110 preferably includes an open receptacle 120 that functions to contain and direct a substance 140 that promotes bone growth. The receptacle 120 is preferably a through hole with two openings 122, but may alternatively be a well with one opening, a porous enclosure with multiple openings 122, or any number of suitable receptacles 120 with any number of openings 122. The receptacle 120 is preferably configured to hold a viscous fluid, but may alternatively be adapted to hold solids such as bone chips or any suitable matter that accompanies implantation of the prosthetic cage.
The bone-growth promoting substance 140 that is contained in the receptacle 120 functions to promote directed bone growth. The substance 140 is preferably composed of a bone growth promoter and a carrier matrix. The bone growth promoter is preferably bone morphogenic protein (BMP), but may alternately be bone chips or activated stem cells. Use of BMP in intervertebral spacers is known to one skilled in the art, such as that described in U.S. Pat. No. 7,534,265 entitled “Intervertebral spacers with side wall accessible interior cavity”, which is incorporated in its entirety by this reference. The carrier matrix is preferably putty, but may alternately be a sponge or a fluid. The bone growth promoting substance 140 is preferably comprised of BMP in a putty matrix, such as OP-1 putty manufactured by Stryker. However, the bone growth promoting substance 140 may additionally be activated stem cells in a fluid or bone chips embedded in a polymer sponge.
The cover 130 functions to seal, close, obstruct, or otherwise block the receptacle opening 122 and enclose the bone-growth promoting substance 140 within the receptacle 120 during implantation. The cover 130 is preferably a sheet, but may alternatively be a pouch or a container the shape of the receptacle 120, and is preferably semi-rigid, but may alternatively be rigid or flexible. The cover 130 is preferably made of a biocompatible polymer such as PEEK, but may alternately be made of any biocompatible material such as titanium or silk, be made of a material that is dissolvable by solvent or be made of a bioresorbable material. The implantable prosthetic cage 100 preferably includes two covers 130, but may include one cover 130, multiple covers 130, or as many covers 130 as needed to cover the openings 122 of the body 110.
The coupling mechanism allows the cover 130 to selectively achieve a sealed (or “closed”) mode, wherein the cover 130 cooperates with the body 110 to form a seal that confines at least a portion of the substance 140 within the receptacle 120 of the body 110. The coupling mechanism preferably utilizes complimentary structures on the cover 130 and body 110 to mechanically connect the cover 130 with the body 110, but may also leverage material properties of the cover 130 and body 110, such as chemical or magnetic properties, to create a seal. The coupling mechanism preferably operates like a drawer, as shown in
The decoupling mechanism allows the cover 130 to achieve an unsealed (or “open”) mode by creating an opening 122 in the seal that is formed between the cover 130 and body 110, thereby to allowing access to the substance 140 within the receptacle 120 after implantation of the prosthetic cage. The decoupling mechanism is preferably mechanical, but may be chemical as well, such as a solvent that solubilizes the cover 130, UV light that catalyzes a reaction to separate the cover 130 and the body 110, or naturally occurring enzymes that degrade the cover 130. The decoupling mechanism is preferably a tab 132 coupled to the cover 130, as shown in
In a first preferred embodiment, as shown in
In a variation of the first embodiment, as shown in
In a second preferred embodiment, as shown in
In a third preferred embodiment, as shown in
2. Method of Utilizing an Implantable Prosthetic Cage
The method of utilizing an implantable prosthetic cage, as shown in
Step S110, which includes substantially sealing a bone-growth promoting substance within an implantable body, functions to form a seal that prevents migration of the substance out of the body during implantation. This step preferably includes fastening any number of covers over any number of openings in the body, thereby sealing the body and containing any substance introduced into the body before this sealing step within the body. As shown in
Step S120, which includes implanting the body between two bones while maintaining the seal and preventing contact between the substance and a bone, functions to implant the prosthetic cage without undesired migration of the substance out of the prosthetic cage. This step is preferably performed after Step S110. The first portion of this step, which includes inserting the prosthetic cage between two bones, is known and used by those skilled in the art, as described in U.S. Pat. No. 6,648,915 entitled “Intervertebral cage and method of use”, which is incorporated in its entirety by this reference. However, the step of implanting the prosthetic cage may alternatively include any suitable step that depends on the specific application of the prosthetic cage. The second portion of this step, which includes maintaining the seal and preventing contact between the substance and a bone, is preferably accomplished by leaving the covers intact over the openings of the body during implantation.
Step S130, which includes disabling the seal, thereby allowing contact between the substance and a bone, functions to control when the substance is allowed to contact the bone. Step S130 is preferably performed after the implantation of the body between two bones S120, but may be performed before Step S120 as well. Step 130 preferably includes uncovering any openings on the body by pulling covers off of said openings S132, but may alternately include applying an external solvent to dissolve any covers over any openings in the body, perforating any covers over any openings in the body S134 (shown in
The method of using an implantable prosthetic cage may additionally include the step of introducing a bone-growth promoting substance into the implantable body S100. This step is preferably performed before the step of “substantially sealing a bone-growth promoting substance within an implantable body,” and functions to enable the implantable body to better direct bone growth. Introducing a bone-growth promoting substance is preferably accomplished by packing a BMP-containing putty into a receptacle of the body, as shown in Step S102 in
In a first preferred method of using the implantable prosthetic cage, as shown in
In a second preferred method of using the implantable prosthetic cage, as shown in
As a person skilled in the art will recognize from the previous detailed description and from the figures and claims, modifications and changes can be made to the preferred embodiments of the invention without departing from the scope of this invention defined in the following claims.
Number | Date | Country | |
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61234245 | Aug 2009 | US |