Operative Techniques in Orthopaedic Surgery (4 Volume Set) 1st Edition

99. Revision Total Knee Arthroplasty With Femoral Bone Loss: Metal Augments

Gwo-Chin Lee

DEFINITION

images The number of revision TKA procedures performed is projected to increase at an annual rate of 19.3%.8

images Femoral bone defects are uncommon in primary TKA but are very common in revision knee surgery.

images Modular femoral augments are useful for moderate-sized bony defects, allowing the surgeon to maximize bone–prosthesis contact while restoring the joint line or posterior condylar offset.

images Improvements in prosthesis design and biomaterials have increased the usefulness and versatility of metal augments in addressing larger bone defects.

images A systematic approach to preoperative planning, intraoperative evaluation, and reconstruction is essential in addressing femoral defects using augments.

ANATOMY

images The most common form of bone defect encountered at the time of revision surgery is bone loss from the distal and posterior femur (Table 1).

images Aside from “filling the defect,” it is important to restore the femorotibial joint line and the posterior condylar offset. Significant alterations in either or both will be detrimental to the function of the prosthesis.

images The joint line typically lies 25 mm distal to the femoral epicondyles, and the posterior femoral condyles are offset an average of 25.8 mm from the posterior cortex of the femur.2

PATHOGENESIS

images In unoperated knees, bone loss on the femoral side can be caused by previous osteochondral defects, avascular necrosis, severe valgus or varus deformity, posttraumatic arthritis, and Charcot arthropathy (FIG 1A).

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FIG 1  A. AP radiograph of a knee with severe deformity that has resulted in severe bone loss. B. Massive bone loss was encountered during revision surgery with severe osteolysis.

images During revision surgery, osteolysis secondary to wear debris and bone loss secondary to removal of well-fixed components or a cement mantle are the most common causes of femoral bone defects (FIG 1B).

images Rarely, earlier trauma resulting in severe angular deformity may require the use of augments for joint reconstruction and restoration of limb alignment.

NATURAL HISTORY

images Untreated bone defects in the native knee can lead to progressive joint collapse, ligamentous laxity, and progressive bone loss.

images Osteolytic lesions caused by wear debris can progress and lead to loss of implant support and eventual component loosening.

images Intraoperative mismanagement of defects can lead to suboptimal fixation, significant alterations in knee kinematics, instability, and early implant failure.

PATIENT HISTORY AND PHYSICAL FINDINGS

images A complete history and physical examination must be performed before any revision knee surgery is undertaken. The details of the index arthroplasty with regard to pain relief and the interval to failure should be recorded. In addition, problems during the postoperative period such as falls or operative wound complications should be probed.

images Patients with loose femoral components often present with painful TKAs. Pain often occurs at start-up, arising from the seated position, and with stair climbing. These patients often may complain of swelling and effusions within the knees.

images An AP radiograph of the pelvis and a careful back and hip examination should be performed to rule out coexistent spinal or hip disorder as the cause of the patient's knee pain.

IMAGING AND OTHER DIAGNOSTIC STUDIES

images Plain radiographs of the knee, including standing AP, lateral, and Merchant views of the affected knee, should be reviewed. For patients with deformity, the entire length of the affected bone should be visualized.

images In revision cases, serial radiographs may help assess the progression of osteolysis, radiolucent lines, and implant migration.

images CT scans of the knee permit assessment of component rotation and can assess the size and location of osteolysis more accurately.4 Recently, MRI also has been shown to be effective in quantifying osteolytic defects.9

images Blood studies, including a complete blood count with differential, sedimentation rate, and C-reactive protein, should be obtained to rule out infection.

images Nuclear medicine studies including bone scan (to detect a loose prosthesis) and indium and sulfur colloid scans (to detect the presence of infection) also can be helpful in the preoperative workup.

images Aspiration should be done when there is any suspicion of infection. The synovial fluid should be evaluated and cultured for the presence of microoorganisms.

DIFFERENTIAL DIAGNOSIS

images Infection

images Arthritis of the hip and spine

images Flexion instability

images Patellar maltracking and extensor mechanism dysfunction

images Tibial component loosening

images Periprosthetic fractures

NONOPERATIVE MANAGEMENT

images Unless the patient has obvious signs of component malpositioning, loosening, fracture, or infection, a trial of conservative treatment aimed at strengthening the quadriceps musculature with emphasis on the vastus medialis oblique muscle should be the cornerstone of nonoperative treatment.

images Patients who have evidence of early osteolysis on plain radiographs but have no clinical symptoms or pain should be encouraged to obtain serial radiographs annually to check for progression of the lesion(s).

images No consensus has been reached regarding when it is appropriate to revise or perform bone grafting in an asymptomatic knee with radiographic evidence of osteolysis.

SURGICAL MANAGEMENT

images A systematic approach is required to reconstruct bone defects successfully during revision surgery.

Preoperative Planning

images Thorough preoperative planning is the key to a successful reconstruction.

images Review of radiographs and CT scans and careful templating allow anticipation of problems that could be encountered during surgery (FIG 2A,B).

images Most bone loss can be addressed by the use of metal augments and a long-stem prosthesis (FIG 2C).

images For larger osteolytic lesions, special wedges, femoral heads, and allografts must be ordered in advance so they are available during reconstruction.

images In all cases of revision, stemmed and constrained implants (or sometimes a hinged prosthesis) must be considered and must be available.

Positioning

images The standard position for patients undergoing revision TKA is supine.

images Care is taken to drape out a wide surgical field in case a more extensile approach is necessary. A sterile tourniquet applied on the surgical field may be helpful.

Approach

images The knee is approached via the standard medial parapatellar approach.

images Protection of the patellar tendon during this phase of the operation is crucial.

images An extensive synovectomy and débridement of the medial and lateral gutters are critical for decompression of the joint.

images The patella usually is not everted during revision TKA.

images In knees with severe ankylosis, techniques such as the quadriceps snip, lateral release, and tibial turbercle osteotomy are helpful for exposure. The surgeon must know the implications of each of these releases and repair or reconstruct them properly at the end of the procedure.

images The bone defect is addressed by the use of cement (smaller lesions), metal augments, or structural grafts. The critical issues are to restore joint line, achieve appropriate alignment, and attain ligamentous balancing. Reconstruction also aims at restoring a stable platform for positioning and fixation of the components.

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FIG 2  A,B. AP and lateral radiographs of the knee before revision surgery. Large osteolytic defects involving both the femur and the tibia are visible. Careful preoperative planning is required to be able to address bone loss encountered at the time of arthroplasty. C. Most cases of knee revision with bone loss can be addressed with the use of a long-stem prosthesis and metal augments.

TECHNIQUES

METAL AUGMENTS

images Modular metal augments allow for restoration of distal, posterior, and even metaphyseal femoral defects.

images For most systems, the largest femoral augments allow for restoration of 8 to 10 mm of bone defect. The use of cemented stacked augments for filling defects up to 30 mm has been reported.5

images Most revision systems have intramedullary systems that allow bone cuts to be made relative to a press-fit intramedullary rod.

images The distal femoral cut is freshened to provide a stable platform for the new prosthesis.

images Next, the size of the femoral component is selected. Preoperative templating can give clues to the proper component size. Traditionally, the femoral component is upsized to better fill the flexion gap (TECH FIG 1A).

images Determining proper femoral component rotation is critical to a successful reconstruction. The femoral component should be set parallel to the transepicondylar axis of the femur (TECH FIG 1B). Other secondary guides include the proximal tibia and the femoral intercondylar line.

images Malrotation of the femoral component also can exaggerate the severity of bone loss.

images The rest of the reconstruction varies according to the revision knee system being used, but should follow a systematic approach. In some systems, the trial components have slots that allow bone cuts to be made for more precise fitting of the modular augment (TECH FIG 1C).

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TECH FIG 1  A. Sizing the femoral component is an important part of the revision process. B. Assessing the appropriate rotation using transepicondylar axis and Whiteside's line. Note the distortion of the posterior condylar line as a result of bone loss. C. Some implants have trials with slots, which allows for more precise sizing and preparation for modular augments. D. Femoral trial with augments and stem in place.

images A stemmed trial femoral component with the necessary augments is assembled and inserted. Trialing should focus on the overall stability of the knee in extension and flexion, and also on patellofemoral tracking (TECH FIG 1D).

images The definitive prosthesis is assembled and cemented into place in the standard fashion.

BONE CEMENT

images Indicated for use in small, preferably contained, bony defects up to 5 mm in depth

images Limitations include its low modulus of elasticity and that it does not restore bone stock

images Following removal of the existing prosthesis, all surfaces are thoroughly débrided. There is a membrane that often forms between the old bone–cement interface. Areas of bony sclerosis should be débrided to punctate bleeding with the aid of a high-speed burr.

images The femur is prepared with the revision instrumentation specific to the implant system, paying attention to joint line restoration, rotation, and restoration of the posterior condylar offset. The use of stemmed implants allows for distribution of joint stresses and almost always is required in cases of revision surgery with bone loss.

images The new femoral component is cemented into place separately, and the cement is allowed to harden under direct vision.

MORSELIZED AUTOGRAFT OR ALLOGRAFT

images Indicated for use in larger contained defects, especially in younger patients. The main advantage of this technique is that it allows for restoration of bone stock.

images Limitations: cannot be used for uncontained defects, and does not restore a stable platform capable of supporting the prosthesis

images Using a curette or a high-speed burr, the host bone is débrided to create a favorable environment for graft incorporation.

images Visible defects are packed with morselized auto- or allograft.

images A bone tamp may be used to pack the bone chips tightly.

images Prepare the femur using the revision instrumentation particular to the system being used.

images Once the femur is prepared, insert a stemmed trial femoral component, with or without wedges, onto the femur.

images Before final impaction of the trial component, tightly pack the bone chips around the stems and the posterior condyles. Impacting the trial prosthesis into place will effectively shape the new distal femur.

images The new stemmed femoral component is cemented separately to minimize the chance of component malposition.

STRUCTURAL ALLOGRAFTS (FEMORAL HEMICONDYLE)

images Structural allografts are indicated for large, uncontained defects involving one femoral condyle. The attachments of the collateral ligaments are preserved by a thin shell of bone following removal of the femoral implant.

images The host bone–allograft interface is prepared as previously described.

images Gently, using a hemispherical acetabular reamer, the bony defect is reamed to accept a femoral head (TECH FIG 2A).

images Using the corresponding female resurfacing reamer, a femoral head allograft is reamed to remove all cartilaginous debris (TECH FIG 2B).

images The femoral head is coupled to the bony defect and secured using two threaded Steinmann pins inserted from proximal to distal (TECH FIG 2C).

images The distal femur then is prepared using the instrumentation particular to the system being used.

images The femoral head allograft is fixed to the host bone using 4.5-mm short-thread cancellous screws inserted from proximal to distal (TECH FIG 2D).

images Finally, a stemmed femoral component is cemented into place.

images

TECH FIG 2  A. A hemispherical reamer is used to prepare the host surface. B. Using the matching female reamer, the cartilage of the femoral head allograft is denuded to cancellous bone. C. The graft is provisionally fixed using two threaded Steinmann pins. D. The allograft is fixed definitively using two short-thread 4.5-mm cancellous screws from proximal to distal before implantation of the prosthesis.

DISTAL FEMORAL ALLOGRAFT

images Indicated for massive osteolytic defects involving both distal condyles and distal femoral metaphysis. It allows for restoration of bone stock while preserving the collateral ligament insertions.

images In cases in which a distal femoral allograft may be required, preoperative sizing of the host femur and the allograft is crucial.

images Comparing radiographs of the allograft to the host femur (may size against an unoperated side if available) improves fit and decreases the chances of mismatch.

images The native femur is prepared to accept the allograft by carefully preserving the collateral ligament attachments (TECH FIG 3A).

images The allograft is then shaped to allow for intussusception (bone within bone) into the native femur. It is important to obtain a secure fit of the allograft during this step (TECH FIG 3B).

images Using traditional distal femoral cutting guides, the femur is prepared to accept a stemmed prosthesis (TECH FIG 3C–E).

images Demineralized bone matrix is used to line the host–allograft interface. This allows the filling of gaps and also provides a barrier against cement intrusion (TECH FIG 3F).

images A stemmed femoral implant is cemented into place (TECH FIG 3G,H).

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TECH FIG 3  A. Severe bone loss encountered during surgery. Because the collateral ligaments were still intact, use of structural allograft to reconstitute bone was deemed appropriate. B. The allograft is cut to the approximate size needed to fit the defect. C–E. The rest of the cuts are performed using standard instruments to obtain a well-shaped structural graft. The prepared graft is produced to fit the defect exactly. F. Demineralized bone matrix can be used in the interface between allograft and host. G,H. The long stem implant is then cemented over the allograft.

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FIG 3  Using a marking pen, the trial prosthesis is traced following a satisfactory trial of all the components. This tracing will provide a guide to the depth of seating for the definitive prosthesis.

POSTOPERATIVE CARE

images Early motion is instituted for most patients using a continuous passive motion (CPM) machine set from 0 to 60 degrees immediately following surgery.

images For patients who have had extensive procedures, a wellpadded Robert Jones dressing is applied following the operation. Immobilization is maintained for 24 to 48 hours.

images Following revision TKA, patients usually are allowed to bear weight as tolerated on the prosthesis.

images Alterations of weight-bearing status and limitations on knee flexion generally result from other procedures performed at the time of arthroplasty, such as tibial tubercle osteotomy, quadriceps snip, or V-Y turndown.

OUTCOMES

images Overall, the survivorship of revision femoral components using metal wedges with or without structural augments is 79.4% at 8 years.5

images For knees with small, contained cavitary defects requiring only cement or morselized graft, the 10-year survivorship approaches that of primary knee arthroplasty.6

images Modular femoral augments used for reconstruction of type II defects have an 11-year survival rate of 92%. It is not uncommon to see nonprogressive radiolucent lines surrounding metallic augments.9

images Femoral revisions augmented with structural allografts have a 10-year survival rate of 75%.3

COMPLICATIONS

images Traditional complications following revision TKA include infection, wound complications, and loosening.

images Patellar maltracking and extensor mechanism dysfunction also can occur, especially if there is component malrotation.

images Knee instability can result from an imbalance in the flexion and extension gaps.

images Resorption of large structural allografts leading to subsequent implant loosening has been described.

REFERENCES

1.     Banks SA, Harman MK, Bellemans J, et al. Making sense of knee arthroplasty kinematics: news you can use. J Bone Joint Surg Am 2003;85A(Suppl 4):64–72.

2.     Bellemans J, Banks S, Victor J, et al. Fluoroscopic analysis of the kinematics of deep flexion in total knee arthroplasty. J Bone Joint Surg Br 2002;84:50–53.

3.     Clatworthy MG, Balance J, Brick GW, et al. The use of structural allograft for unconstrained defects in revision total knee replacement: A minimum 5 year review. J Bone Joint Surg Am 2001;83A:404–411.

4.     Gonzalez MH, Mekhail AO. The failed total knee arthroplasty: Evaluation and etiology. J Am Acad Orthop Surg 2004;12:436–446.

5.     Hockman DE, Ammeen D, Engh GA. Augments and allografts in revision total knee arthroplasty: usage and outcome using one modular revision prosthesis. J Arthroplasty 2005;20:25–41.

6.     McAuley JP, Engh GA, Ammeen DJ. Revision of failed unicompartmental knee arthroplasty. Clin Orthop Relat Res 2001;392:279–282.

7.     Patel J, Masonis JL, Guerin J, et al. The fate of augments to treat type-2 bone defects in revision knee arthroplasty. J Bone Joint Surg Br 2004;86B:195–199.

8.     Saleh KJ, Rand JA, McQueen DA. Current status of revision total knee replacements: how do we assess results. J Bone Joint Surg Am 2003;85A:18–20.

9.     Vessely MB, Frick MA, Oakes D, et al. Magnetic resonance imaging with metal suppression for evaluation of periprosthetic osteolysis after total knee arthroplasty. J Arthroplasty 2006;21:26–31.

10. Werle JR, Goodman SB, Imrie SN. Revision total knee arthroplasty using large distal femoral augments for severe metaphyseal bone deficiency: a preliminary study. Orthopedics 2002;25:325–327.



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