Key points

Introduction

In regards to operative fixation of tibial plateau fractures, classical Arbeitsgemeinschaft für Osteosynthesefragen (AO) teaching emphasized the importance of anatomic articular restoration and stable fixation to allow for early range of knee motion. However, early results, secondary to excessive soft tissue stripping and overly rigid fixation, led to undesirable high nonunion rates and failure. However, the paradigm and strategy in the operative treatment of tibial plateau fractures has evolved dramatically in recent years. Nuances in anatomic approaches, advances in implant technology, and an improved respect and understanding for surgical technique and the surrounding soft tissue envelope have allowed for improved short- and long-term results.

Tibial plateau fractures occur in all age groups, but generally have a bimodal distribution within a given population occurring in young adults as a result of high-energy trauma, and in the elderly as a result of low-energy injuries. There is a spectrum of injury, with the severity of each fracture dependent on the mechanism of injury, the associated energy, and the quality of the host bone. However, despite the variety in which these fracture patterns can occur, the goals and principles remain the same: restoration of the articular surface and maintenance of the mechanical axis. However, depending on the specific type of fracture pattern, implementing the proper planning, surgical technique, and management can help to maximize clinical outcomes, while avoiding complications.

This article helps the reader achieve those goals by summarizing the pertinent principles, strategies, and techniques for some of the most commonly presenting tibial plateau fractures. This is achieved via a case-based platform in hopes of providing a more individualized approach that can be readily implemented across a wide audience.

Introduction

In regards to operative fixation of tibial plateau fractures, classical Arbeitsgemeinschaft für Osteosynthesefragen (AO) teaching emphasized the importance of anatomic articular restoration and stable fixation to allow for early range of knee motion. However, early results, secondary to excessive soft tissue stripping and overly rigid fixation, led to undesirable high nonunion rates and failure. However, the paradigm and strategy in the operative treatment of tibial plateau fractures has evolved dramatically in recent years. Nuances in anatomic approaches, advances in implant technology, and an improved respect and understanding for surgical technique and the surrounding soft tissue envelope have allowed for improved short- and long-term results.

Tibial plateau fractures occur in all age groups, but generally have a bimodal distribution within a given population occurring in young adults as a result of high-energy trauma, and in the elderly as a result of low-energy injuries. There is a spectrum of injury, with the severity of each fracture dependent on the mechanism of injury, the associated energy, and the quality of the host bone. However, despite the variety in which these fracture patterns can occur, the goals and principles remain the same: restoration of the articular surface and maintenance of the mechanical axis. However, depending on the specific type of fracture pattern, implementing the proper planning, surgical technique, and management can help to maximize clinical outcomes, while avoiding complications.

This article helps the reader achieve those goals by summarizing the pertinent principles, strategies, and techniques for some of the most commonly presenting tibial plateau fractures. This is achieved via a case-based platform in hopes of providing a more individualized approach that can be readily implemented across a wide audience.

Important considerations before surgery

Arguably, once appropriately indicated, the most important stage of treating tibial plateau fractures occurs before entering the operating room. Preoperative planning, which includes evaluation and decision for surgery, diagnostic and advanced imaging, along with timing and formulation of a surgical plan not only help to achieve a desired clinical result, but aid the surgeon in execution of the procedure.

Surgical planning begins with the initial evaluation and interview. Assessing the mechanism and energy of the sustained injury along with a thorough medical history can provide a general outline of the underlying fracture pattern, and the fixation and management strategy that may ultimately be required. For example, the injury pattern for a 24-year-old man who presents after a high-energy motorcycle crash differs from that of a 78-year-old woman who sustained a low-energy valgus load to the knee while grocery shopping. Coinciding with obtaining a thorough history is a complete physical examination. Neurovascular assessment, including measuring ankle-brachial indices (ABI), should be performed if there is any suspicion for vascular compromise that could be a hard sign, such as diminished pulses, or a soft sign, such as fracture pattern. Furthermore, initial assessment of the surrounding soft tissue envelope can indicate not only the severity of the fracture, but may also provide an approximate timeline to definitive fixation. Ligamentous assessment, although important in high-energy plateau fracture-dislocations, may be difficult to assess on initial presentation because of pain and swelling.

No matter how thorough a history and physical examination is performed, diagnosis and operative planning cannot start without obtaining appropriate imaging. Anteroposterior (AP), lateral, and oblique views should be initially obtained. Tibial plateau views, directed in line with the anatomic 10-degree slope of the tibia, can also be helpful, although with the advent of more advanced imaging modalities (ie, computed tomography [CT]), it is rarely obtained. Initial diagnosis via plain radiographs, combined with knowing the mechanism and energy of the injury, is of paramount importance because it dictates the next stage in management. For low-energy injuries with relatively simple fracture patterns, immobilization with plaster or a knee immobilizer and an immediate CT should be the next step. However, for higher-energy injuries with associated complex fracture patterns and significant soft tissue damage, the decision to temporarily stabilize with external fixation is made.

Ideally, classification systems should not only have high agreement between observers, but should also provide consistent reliable agreement on treatment and prognosis. However, most classification systems fall short on each of those ideals, and tibial plateau fractures are no different. Most commonly, the Schatzker, the Moore, and the AO/Orthopaedic Trauma Association (OTA) classifications have been used. Using radiographs alone, Maripuri and colleagues reported moderate agreement between observers, the best agreement exhibited with the Schatzker classification. Adding CT, however, improves observer agreement from moderate to good. If observers are provided with three-dimensional reconstructions, agreement improves to excellent for the Schatzker classification.

The role of CT in regards to operative planning cannot be understated. Close analysis of CT reconstructions in the axial, coronal, and sagittal planes can offer key insight into the degree of injury by revealing entrance and exiting locations of major fracture lines, extent and location of column involvement and articular depression, degree of comminution, and any distal extension into the meta-diaphyseal junction.

In turn, understanding these key components of any tibial plateau fracture helps plan for specific approaches and implant and bone void filler selection. Additionally, for those patterns with increasing levels of articular depression and higher-energy fracture patterns, meniscal injury and/or associated ligamentous injury can be expected.

Definitive fixation should follow soft tissue resolution

Tibial plateau fractures can often present with significant soft tissue injury not amenable to acute, definitive fixation. Ignoring soft tissue quality can lead to high rates of infection and complications, especially during the first 7 days after injury. Complications arise from the underlying inflammatory cascade that leads to venous congestion, hypoxia, and subsequent necrosis creating the least ideal operative environment.

Drawing from the staged protocol used for pilon fracture management, the same can be applied to tibial plateau fractures to allow for optimum soft tissue status before definitive fixation. Egol and colleagues, using spanning external fixation for high-energy proximal tibial fractures, reported low wound complication rates. With minimal soft tissue complications, the group recommended staged fixation for all high-energy fractures of the proximal tibia. Temporary (or in some cases, definitive) external fixation not only provides skeletal stabilization to maintain length, alignment, and rotation, but also allows for easy access for wound and blister management ( Fig. 1 ).

Tibial plateau fractures often present with significant soft tissue injury that requires external stabilization. ( A ) A 37-year-old man with high-energy tibial plateau fracture after motorcycle crash with significant soft tissue injury. ( B ) A 46-year-old man after high-energy fall, with significant blistering with underlying tibial plateau fracture.

Finally, although still controversial, one must be cognizant of pin-site placement in regards to future plate placement. Although classic teaching recommends placement of pin-sites outside of the zone of future plate placement, there is a paucity of literature to suggest if it truly holds an increased infection rate. Recent studies, in an effort to provide objective data to find an answer, reported conflicting results. In a small cohort comparison study, Laible and colleagues did not find an increased infection rate in tibial plateau fractures fixed with plates that overlapped with pin-sites. Shah and colleagues found the opposite, finding an increased infection rate with plate, pin-site overlap. However, the authors had a more heterogeneous study cohort, including both tibial plafond and plateau fractures. While we await larger studies for a definitive answer based on objective data, we recommend trying to place pin-sites outside of the zone of fixation. However, that goal should not outweigh achieving stability, length, and alignment.

Definitive fixation: case-based strategies and techniques

Goals for definitive fixation for tibial plateau fractures revolve around implementing basic principles to achieve good outcomes ( Box 1 ). Certain techniques and strategies can be implemented for specific fracture patterns to achieve desired goals. The following scenarios represent some of the more commonly presenting fracture patterns, from the simple to the complex, with the specific techniques and strategies that can be applied to maximize outcomes.

Scenario 1: Simple Split Fractures

For simple split fracture patterns, Koval and colleagues showed that excellent results could be achieved with indirect reduction techniques and percutaneous fixation. This has become a reproducible, reliable technique, but in the correct patient with the correct fracture pattern. Either tibial plateau views or a CT should be obtained to rule out any significant joint depression. If slight joint depression exists along with the split, percutaneous techniques and methods of elevating the joint line have also been developed. However, we prefer to reserve the truly percutaneous and indirect reduction techniques for the pure split fractures. For split-depression fracture patterns, we typically formally open the fracture to visualize and assess and confirm anatomic articular reduction (Scenario 2).

Here we illustrate a 57-year-old woman who was struck by a bicyclist. Radiographs revealed an isolated split tibial plateau fracture ( Fig. 2 A), which we confirmed to be without depression via tibial plateau view (see Fig. 2 B). Patient positioning and setup is the same setup used for all tibial plateau fractures. The patients should be supine on a radiolucent table, with a bump placed under the ischial tuberosity on the ipsilateral side along with fluoroscopic imaging placed on the contralateral side; placing the affected limb on a radiolucent knee triangle also helps to eliminate the uninjured leg, allowing for easily obtained images (see Fig. 2 C).

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