The instant invention relates generally to methods and apparatus for the treatment of unstable pelvic fractures. More specifically the invention relates to a method and apparatus for minimally invasive treatment of unstable pelvic ring injuries using an internal posterior iliosacral screw and bone plate construct.
Unstable pelvic fractures typically occur as a result of high-energy injuries such as automobile accidents, falls and the like. Even in this age of modern polytrauma care, acute pelvic fractures are potentially lethal. In the past, such injuries were treated without surgery. However, recovery to completely normal functionality was the exception rather than the norm. In more modern times, unstable pelvic fractures are treated surgically with a number of techniques depending on the type and extent of the fracture(s).
The pelvis consists of three major bones (two ilium 1, 1′ and the sacrum 2, the sacroiliac joints 3, 3′ (being where the ilia attach to the sacrum) and some minor bones joined together in a ring shape and held by strong ligaments, See
Internal fixation is typically utilized when the patient exhibits unstable posterior pelvic fractures. Internal fixation refers to plates and screws applied directly onto the fracture sites after realignment. See, for example, U.S. Pat. Nos. 4,454,876; 5,108,397; 6,340,362 and 6,440,131. This type of fracture tends to be more complex, involving multiple bony structures. Internal fixation addresses these clinical issues through open reduction and correction of misaligned bone segments that are subsequently stabilized with a wide variety of plate and screw methods.
Anterior pelvic fractures or hemodynamically unstable patients are candidates for external fixation. Pelvic external fixation consists of pins usually inserted into the iliac bones and then connected together by clamps and bars. See, for example, U.S. Pat. Nos. 4,292,964; 4,361,144; 5,350,378 and 6,162,222. External fixation methods consists of stabilizing the pelvic ring with a rigid framework residing outside the patient's body that is connected to the patient's pelvis via multiple pins that penetrate through the patient's soft and hard tissues. Several frame types are currently utilized. Two of the more widely deployed devices for external pelvic stabilization are the Hoffmann 2 Inverted “A” Frame and the Ganz Pelvic C Clamp.
The application of external reduction and fixation for pelvic fractures is advantageous compared to internal reduction and fixation due to its speed of deployment and lower level of technical training required for utilization. The primary disadvantages of external fixation of pelvic fractures include high risk of pin tract infections, and general patient discomfort. Also, the external frame physically blocks subsequent surgery on the abdomen and they are frequently difficult to fit to obese patients.
The instant inventor has previously developed novel methods using the already established principles of anterior external fixation. See U.S. Pat. Nos. 8,900,278; 8,814,866; 8,398,635; and 8,177,785, the disclosures of which are herein incorporated by reference. By combining these principles with internal hardware placed in a minimally invasive fashion, this technique allows for definitive pelvic stabilization without having the issues and co-morbidities of an external fixator (i.e. interfering with other procedures, pin care, patient acceptance, later conversion to internal fixation, etc.) The present invention adds to the internal anterior fixation pelvic stabilization using a plate and screw structure on the posterior of the pelvis.
The present invention is a novel surgical method and apparatus for minimally invasive affixation of an ilium to the sacrum in an unstable pelvic ring injury. The method may comprise the step of providing a bone plate having at least two attachment holes therethrough, and two cannulated screws. The method may comprise the step of affixing the bone plate to the posterior of the ilium by the steps of: placing the bone plate on the ilium, adjacent to the sacroiliac joint; screwing the first of the two cannulated screws through a first of the attachment holes in the bone plate, through the ilium, through the sacroiliac joint, and into the S1 vertebral body; and screwing the second of the two cannulated screws through a second of the attachment holes in the bone plate, through the ilium, through the sacroiliac joint, and into the S2 vertebral body. The cannulated screws may be inserted far enough to hold the bone plate tightly against the ilium.
The step of placing the bone plate on the ilium, adjacent to the sacroiliac joint may comprise the steps of: inserting a first cannulation guide wire through the ilium, the sacroiliac joint, and into the S1 vertebral body; inserting a second cannulation guide wire through the ilium, the sacroiliac joint, and into the S2 vertebral body; sliding the first and second cannulation guide wires through the first and second attachment holes in the bone plate, respectively; and advancing the bone plate down along the guide wires to the surface of the ilium.
The step of screwing the first of the two cannulated screws through the first of the attachment holes in the bone plate may comprise: placing the first of the two cannulated screws onto the first cannulation guide wire; guiding the first of the two cannulated screws down the first cannulation guide wire to the surface of the ilium; and screwing the first of the two cannulated screws through the ilium, through the sacroiliac joint and into the S1 vertebral body. The first of the two cannulated screws may be of a length to reach from the bone plate to a medial position in the S1 vertebral body.
The step of screwing the second of the two cannulated screws through the second of the attachment holes in the bone plate may comprise: placing the second of the two cannulated screws onto the second cannulation guide wire; guiding the second of the two cannulated screws down the second cannulation guide wire to the surface of the ilium; and screwing the second of the two cannulated screws through the ilium, through the sacroiliac joint and into the S2 vertebral body. The second of the two cannulated screws is of a length to reach from the bone plate to through the S2 vertebral body and into the opposite ilium. The surgical method may comprise the further step of removing the first and second cannulation guide wires from the pelvis after insertion of the first and second cannulated screws.
The surgical method may comprise the further steps of: placing a second bone plate having at least two attachment holes therethrough on the opposite ilium, adjacent to the opposite sacroiliac joint; screwing the a third cannulated screw through a first of the attachment holes in the second bone plate, through the opposite ilium, through the opposite sacroiliac joint, and into the S1 vertebral body; and passing the second cannulated screw through a second of the attachment holes in the second bone plate.
The surgical method may further comprise the step of screwing threads of the forward end of the second cannulated screw into matching threads in the second of the attachment holes in the second bone plate, thereby locking the second bone plate to the second cannulated screw. Alternatively, the surgical method may comprise the further steps of: passing the forward end of the second cannulated screw through the second of the attachment holes in the second bone plate such that it protrudes from the second of the attachment holes in the second bone plate; and placing a nut onto the threads of the forward end of the second cannulated screw and tightening the nut to thereby lock the second bone plate to the second cannulated screw.
The two cannulated screws may be cancellous screws, that are fully or partially threaded. The first of the two cannulated screws may be a partially threaded cancellous screw. The second of the two cannulated screws may be a fully threaded cancellous screw. The bone plate may have two attachment holes therethrough, one at either end thereof. The second bone plate may also have two attachment holes therethrough, one at either end thereof. The bone plate may be a variable-angle locking plate and the second bone plate may be a variable-angle locking plate. The bone plate and the cannulated screws may be formed from titanium. The cannulated screws may be between 7.0 and 8.5 mm in outer diameter, inclusive. The first and second cannulation guide wires may be about 3 mm in outer diameter.
The instant invention is a novel method for posterior pelvic stabilization. The method uses internal hardware placed in a minimally invasive fashion. Stabilization of pelvic ring injuries is most often indicated when the volume of the pelvis is increased and/or an unstable pattern of injury is present. This stabilization method must be applied in the operating room under sterile conditions with adequate fluoroscopic guidance. It can be utilized in an emergent setting following provisional stabilization in the emergency room with a pelvic binder, sheet or clamp.
To aid in the determination of utilizing internal fixation methods, we prefer the Tile classification since it is based on the concept of pelvic stability. In the Tile classification, type A fractures involve a stable pelvic ring. The partially stable type B lesions, such as “open-book” and “bucket-handle” fractures, are caused by external and internal rotation forces, respectively. In type C injuries, there is complete disruption of the posterior sacroiliac complex. These unstable fractures are almost always caused by high-energy severe trauma associated with motor vehicle accidents, falls from a height, or crushing injuries. Type A and type B fractures make up 70% to 80% of all pelvic injuries. Internal fixation methods are typically considered for Tile B and C type injuries. In many patients with partially stable injury patterns, the presence of significant pain with upright posture can be alleviated with the addition of internal fixation. If adequate reduction cannot be obtained in a closed manner, then more traditional open reduction techniques need to be employed.
The patient may be positioned in the supine position on a radiolucent table. The skin may be prepped and draped from above the umbilicus to the proximal thigh. The lower extremity may be prepped into the field as well to facilitate reduction techniques.
The posterior instability may be addressed first. The inventive procedure for placement of iliosacral screws and bone plate(s) for posterior pelvic instability will be described herein below, but first we need to describe the sacrum and sacroiliac joint in more detail.
The sacroiliac joint is a diarthrodial joint that joins the sacrum to the ilium bones of the pelvis. In the sacroiliac joint, the sacral surface has hyaline cartilage that moves against fibrocartilage of the iliac surface.
The method and apparatus for the minimally invasive treatment of unstable pelvic ring injuries with internal posterior iliosacral screw(s) and bone plate(s) will now be described with respect to the figures.
After stabilizing the posterior elements via the iliosacral screws and bone plate(s) method/construct of the present invention, the anterior pelvis may be addressed. Preferably the anterior fixation methods/apparatuses are those disclosed in U.S. Pat. Nos. 8,900,278; 8,814,866; 8,398,635; and 8,177,785, the disclosures of which are herein incorporated by reference.
It is to be expected that considerable variations may be made in the embodiments disclosed herein without departing from the spirit and scope of this invention. Accordingly, the significant improvements offered by this invention are to be limited only by the scope of the following claims.