Case Reports

Intragrade Intramedullary Nailing of an Open Tibial Shaft Fracture in a Patient With Concomitant Ipsilateral Total Knee Arthroplasty

Am J Orthop. 2015 March;44(3):E81-E86

References

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7. Study to Prospectively Evaluate Reamed Intramedullary Nails in Patients with Tibial Fractures Investigators, Bhandari M, Guyatt G, Tornetta P 3rd, et al. Randomized trial of reamed and unreamed intramedullary nailing of tibial shaft fractures. J Bone Joint Surg Am. 2008;90(12):2567-2578.

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14. Georgiadis GM, Behrens FF, Joyce MJ, Earle AS, Simmons AL. Open tibial fractures with severe soft-tissue loss. Limb salvage compared with below-the-knee amputation. J Bone Joint Surg Am. 1993;75(10):1431-1441.

15. Hansen M, Mehler D, Hessmann MH, Blum J, Rommens PM. Intramedullary stabilization of extraarticular proximal tibial fractures: a biomechanical comparison of intramedullary and extramedullary implants including a new proximal tibia nail (PTN). J Orthop Trauma. 2007;21(10):701-709.

16. Hoegel FW, Hoffmann S, Weninger P, Bühren V, Augat P. Biomechanical comparison of locked plate osteosynthesis, reamed and unreamed nailing in conventional interlocking technique, and unreamed angle stable nailing in distal tibia fractures. J Trauma Acute Care Surg. 2012;73(4):933-938.

17. Brumback RJ, Reilly JP, Poka A, Lakatos RP, Bathon GH, Burgess AR. Intramedullary nailing of femoral shaft fractures. Part 1: Decision-making errors with interlocking fixation. J Bone Joint Surg Am. 1988;70(10):1441-1452.

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If circumstances warrant an attempt at limb salvage, IM nailing with static interlocking screws would typically be the standard of care for treatment of an open fracture of the tibia shaft. This provides stable internal fixation that controls tibial alignment in 6° of freedom and neutralizes bending forces with less strain on the implant because of the IM position.^15,16 In addition to superior neutralization of the biomechanical forces, IM nailing is also a minimally invasive approach that limits further trauma to the periosteum and soft-tissue envelope surrounding the fracture site. This optimizes biologic fracture healing and minimizes complications of malunion, infection, and nonunion.^17-19 Moreover, by limiting further damage to the surrounding soft tissue, there is a diminished need for a plastic surgery procedure to reestablish soft-tissue integrity overlying the fracture site. This is particularly advantageous in patients with medical comorbidities that make skin grafts and muscle flaps less likely to succeed. For these reasons, IM nailing was our preferred method of fixation in our patient; however, the presence of an ipsilateral TKA made this standard treatment through an antegrade approach impossible.

Consequently, we considered other methods of fixation, including internal fixation with plate application or external fixation with a multiplanar construct, such as an Ilizarov frame. Some orthopedists consider plate application a superior technique for achieving fracture union because it results in interfragmentary compression, which promotes primary healing. Interestingly, some would argue that the absolute stability provided by the plate may be too rigid a construct to enable optimal fracture healing biology if compression is not achieved.²⁰ However, to allow primary healing to complete fracture union, absolute stability with rigid and strong fixation must be provided. In the tibial shaft, with large bending forces and rotational moments, this is difficult to achieve with plate fixation alone.⁸ Furthermore, plate application often requires relatively extensive soft-tissue dissection and may impede biologic factors in healing of the bone and soft tissue, increasing the likelihood of infection.²¹ Finally, adequate plate fixation would significantly increase the soft-tissue volume at this location, further compromising the soft tissues and impeding our goal of primary wound closure.

A uniplanar or mutliplanar external fixator would be an appealing option for definitive fixation because of minimal additional soft-tissue damage that is created during its application. However, it is difficult to achieve adequate stability to encourage either primary, or more commonly, secondary healing in the adult or elderly population.²² An Ilizarov frame is a multiplanar external construct, which allows reconstructive applications because of multiple points of fixation in bone.²³ However, the multiple fixation points result in burdensome size of the implant for the patient and requires patient compliance to minimize risk of pin-site infection, which is magnified in a patient with multiple medical comorbid conditions. Furthermore, when comparing treatment options that aim to minimize additional soft-tissue trauma at the site of injury, there is little evidence to show a lower risk of infection at the open fracture site compared with IM nailing.^24,25 Thus, in our patient, customary treatment of an open tibial shaft fracture using antegrade IM nailing was not possible, while plate application and external fixation, though potential treatment options, would be relatively contraindicated due to a higher likelihood of failure.

Consequently, primary amputation may be the most appropriate treatment option in a patient with multiple comorbid medical conditions, including peripheral vascular disease. Primary amputation prevents morbidity and mortality associated with complications related to the aforementioned treatment options, as well as limiting risks associated with multiple reoperations.^14,25 Studies illustrate that patient functional outcomes after primary amputation are equal to and, in some cases, superior to those patients undergoing limb salvage procedures for open tibial shaft fractures.^26-28

Despite the appropriateness of primary amputation in this case, the patient requested limb salvage. Therefore, other innovative treatment options were explored to achieve our goals of primary wound closure and stable internal fixation. Previous case reports have examined retrograde IM nailing as a means of rigidly fixing tibial shaft fractures in the setting of poor soft tissues or ipsilateral knee arthroplasty.^29-31 However, the retrograde approach to IM nailing requires passage of reamers through the subtalar and ankle joints, leading to associated arthritis in these joints or, more commonly, rigidity because the final nail position often crosses these joints in addition to the fracture site. Therefore, a novel approach for IM nailing was performed using the large open-fracture wound. Through the traumatic wound, open-fracture débridement was first performed, followed by placement of a nail into the medullary canal with little additional disruption of the surrounding periosteum or soft tissue.