Revision Total Knee Arthroplasty With Extensile Exposure: Tibial Tubercle Osteotomy

DEFINITION

• Obtaining adequate anterior exposure of the knee can be difficult using standard approaches during revision total knee arthroplasty (TKA).

• The options available for dealing with difficult exposure include extensor mechanism snip (done 5 to 8 cm proximal to the superior pole of the patella), V-Y quadriceps turndown, and tibial tubercle osteotomy.

• Tibial tubercle osteotomy is performed to obtain an extensile exposure of the knee during difficult revision TKA.

• An osteoperiosteal segment—which includes the tibial tubercle and upper tibial crest—is elevated to relax the extensor mechanism and allow safe eversion of the patella.

• The technique was first described by Dolin4 in 1983, but subsequently was modified and popularized for exposure in revision TKA by Whiteside.8

  ANATOMY

• The extensor mechanism consists of the quadriceps muscles (ie, rectus femoris, vastus lateralis, vastus medialis, and vastus lateralis), quadriceps tendon, patella, and patellar tendon.

• The quadriceps muscle inserts into the patella via the quadriceps tendon and then into the tibial tuberosity via the patellar tendon.

• Tendinous fibers of the vastus medialis and vastus lateralis form the medial and lateral patellar retinaculae, respectively, which together reinforce the capsule of the knee joint anteriorly (FIG 1A).

• The tibial tuberosity forms the truncated apex of a triangular area at the proximal end of the tibia. It has a distal “rough” area, which is subcutaneous and palpable, and a proximal “smooth” area attached to the patellar ligament (FIG 1B).

  PATHOGENESIS

• Adequate anterior exposure of the distal femur and tibial plateau during revision TKA is crucial for gentle soft tissue handling, safe implant removal, recognition of bone defects, and correct placement of revision components.

• During revision TKA, adhesions and fibrosis within the extensor mechanism restrict eversion of the patella and limit exposure.

• A medial parapatellar arthrotomy, combined with intra-articular excision of the fibrous pseudocapsule, allows eversion of the patella in most cases.

• Inadequate exposure with continued forceful retraction of the extensor mechanism risks avulsion of the patellar ligament from the tibial tubercle.

  NATURAL HISTORY

• Avulsion of the patellar ligament is a serious complication during revision TKA, because it results in prolonged immobi-lization, extensor lag, and a poor functional outcome.

• To avoid this complication, an extensile exposure is required to relax the extensor mechanism and allow safe eversion of the patella.

   

  Vastus medialis

  Medial patellar retinaculum

  Vastus lateralis

   

   

   

  Quadriceps tendon

  Patella

  Lateral patellar retinaculum

   

  Patellar tendon Tibial tuberosity

  Distal femur

   

   

   

  Patella

   

  Left lateral femoral condyle

   

  Proximal smooth area of tibial tuberosity

  Distal rough area

  A B of tibial tuberosity

   

  FIG 1 • A. The extensor mechanism of the knee. Note that the medial and lateral patellar retinaculae originate proximally from the tendinous fibers of the vastus medialis and lateralis muscles, respectively. B. The tibial tuberosity. The distal “rough” area is subcutaneous and palpable. The patellar ligament is attached to the proximal “smooth” area.

   

   

  • Three options for obtaining such an extensile exposure during revision TKA are quadriceps snip, V-Y quadriceps turndown, and tibial tubercle osteotomy.

  • Tibial tubercle osteotomy is preferred because it has a lower incidence of extensor lag and quadriceps weakness compared to a V-Y quadriceps turndown.1,5

    PATIENT HISTORY AND PHYSICAL FINDINGS

  • A history of joint stiffness and complications after primary TKA (eg, arthrofibrosis, infection, hematoma) should alert the surgeon regarding potential difficulties with exposure during revision TKA.

  • Physical findings indicating possible difficulty with exposure during revision TKA include multiple scars, reduced active and passive knee range of movement, a tight posterior cruciate ligament, and patella baja.

    IMAGING AND OTHER DIAGNOSTIC STUDIES

  • Standing anteroposterior and lateral radiographs of the knee usually are adequate in planning for extensile exposures during revision TKA.

  • The radiographs are specifically inspected for tibial osteope-nia and osteolysis, both of which are relative contraindications for tibial tubercle osteotomy.

    SURGICAL MANAGEMENT

  • A tibial tubercle osteotomy is indicated when there is any concern regarding patellar tendon avulsion despite adequate initial soft tissue release, as discussed later in this chapter.

    Preoperative Planning

  • Exposure is considered preoperatively: the history and physical findings should alert the surgeon regarding the potential need for extensile exposures during revision TKA.

  • Previous operative records and radiographs are studied to identify the initial approach during primary TKA, design of the implanted components to be removed, and potential problems during implant removal.

  • The quality of skin overlying the tibial tubercle should be assessed. In patients with multiple scars, the most recent,

appropriate, healed scar is used, but in many situations where tibial tubercle osteotomy is indicated, it may be necessary to consult with a plastic surgical team to plan soft tissue coverage (FIG 2).

Positioning

• The patient is positioned supine on the operating table.

• A tourniquet is sited around the upper thigh, and the leg is exsanguinated before inflation.

• A clamp is positioned laterally to stabilize the lower leg when the knee is flexed.

• A sandbag is positioned distal to the foot to prevent the lower leg from sliding during surgery.

  Approach

• A medial parapatellar approach is used whenever possible, because extensile exposures are most easily incorporated proximally (V-Y quadriceps turndown) and distally (tibial tubercle osteotomy).

A

B

FIG 2 • Skin incisions. A. Previous skin incisions marked.

B. Midline incision through most recent, healed scar.

TECHNIQUES

INITIAL SOFT TISSUE RELEASE BEFORE TIBIAL TUBERCLE OSTEOTOMY

• If the patella cannot be everted following medial parapatellar arthrotomy, the following soft tissue releases are performed sequentially before considering a tibial tubercle osteotomy.

  • Medial release: The dissection is carried medially around the proximal tibia with subperiosteal elevation of the medial retinaculum and deep medial collateral ligament around to the semimembranosus insertion (TECH FIG 1A,B). This allows external rotation of the tibia and relaxes the extensor mechanism (TECH FIG 1C,D).

  • Lateral gutter release and pseudocapsule excision.

    • Superior to the patella, the suprapatellar pouch is freed by dividing the underlying adhesions tether-

ing the extensor mechanism to the anterior femur (TECH FIG 1E).

• Lateral to the patella, adhesions in the lateral gutter tethering the extensor mechanism are divided (TECH FIG 1F).

• Inferior to the patella, the interval between the patellar tendon anteriorly and fat pad posteriorly is identified and the intervening pseudocapsule excised distally to the insertion of the patellar tendon (TECH FIG 1G,H).

• If the patella still cannot be everted, a tibial tubercle osteotomy is performed to reduce the risk of patellar tendon avulsion from forceful retraction of the extensor mechanism.

   

  Medial patellar retinaculum

  Medial parapatellar incision

  A

   

   

  Medial collateral ligament

  Pes anserinus

   

   

  TECHNIQUES

   

     

   

   

   

  Pseudocapsule between fat

  pad and patellar tendon

   

   

   

  TECH FIG 1 • Initial soft tissue release to relax extensor mechanism and allow eversion of the patella. A. Subperiosteal elevation of medial retinaculum.

  B. Subperiosteal medial release to semimembranosus insertion. C,D. The pseudocapsule is completely excised medially to free the medial gutter. E,F. First the suprapatellar pouch, with the lateral gutter, is freed from under-

  G lying adhesions. G,H. Next, the pseudocapsule inferior to the patella is excised.

   

   

  TIBIAL TUBERCLE OSTEOTOMY

  • The skin incision is extended 8 to 10 cm below the tibial tubercle.

  • The periosteum is vertically incised 1 cm medial to the tibial tubercle.

  • An osteotomy site measuring 6 cm long, 2 cm wide, and 1 cm thick,3,5 which includes the tibial tubercle and anterior tibial crest, is marked with electrocautery (TECH FIG 2A,B).

    • The 6-cm medial, vertical limb of the osteotomy is tapered distally to prevent a stress riser.

    • The 2-cm horizontal limb proximal to the insertion of the patellar tendon resists proximal migration of the osteotomized segment.

       

• The proposed medial, lateral, and proximal osteotomy cuts are perforated using a drill (TECH FIG 2C).

  TECHNIQUES

   

• Sequential osteotomes are used to transect the medial tibial crest and separate the osteotomized segment from the tibia.

• The lateral cortex is transected through the osteotomy, but the lateral periosteum and soft tissues are left attached to the elevated segment to act as a “hinge,” allowing eversion of the extensor mechanism.

   

   

  6-cm-long medial

  1. vertical limb

      

     1-cm-deep proximal step

      

     2-cm horizontal limb of osteotomy

      

      

      

     6-cm medial vertical limb of osteotomy

      

  2. C

  Laterally hinged fragment

   

   

   

  Sequential osteotomes used to transect drill holes

   

  Medial tibial crest elevated

   

  Tapered Fragment distally

   

   

  TECH FIG 2 • Tibial tubercle osteotomy. A. The distal cut is tapered to prevent a stress riser. Proximally, the step-cut reduces the risk of proximal migration. B. The medial, vertical limb should be at least 6 cm long. C. The medial cortex is perforated with a drill, and the drill is passed through the lateral cortex to create corresponding perforations in the lateral cortex that will allow the osteoperiosteal segment to be “hinged” around the lateral soft tissue attachments. The proximal osteotomy cut is perforated, and sequential osteotomes are used to elevate the osteotomy.

   

  REATTACHMENT OF OSTEOTOMY WITH WIRES

   

   

  • In our preferred technique, three 18-gauge stainless steel wires are inserted and left untied before the final components are implanted.

    • The most proximal wire is passed through the osteotomized segment and through a drilled hole in the medial tibial cortex.

    • The two distal wires are passed around the osteotomized segment and through drilled holes in the medial and lateral tibial cortices (TECH FIG 3).

  • The wires are twisted until tight, cut, and angled 45 degrees posteromedially to prevent soft tissue irritation.8

   

  TECH FIG 3 • Reattachment of osteotomy with wires. The most proximal wire is passed through the osteotomized segment to prevent proximal migration; the two distal wires are passed around the osteotomy segment. Wires are cut and angled posteromedially to prevent soft tissue irritation.

   

  Proximal wire passed through fragment

   

  Distal wires passed around fragment

   

  Wires tied posteromedially

   

   

  PEARLS AND PITFALLS

  Indications Initial exposure

   

  Tibial tubercle osteotomy

   

  Reattachment of osteotomy

  • Anticipate need for extensile exposure preoperatively.

  • Anticipate need for soft tissue coverage with plastic surgery.

  • Medial parapatellar approach.

  • Medial release, meticulous lateral gutter release, and excision of pseudocapsule before tibial tubercle osteotomy.

  • Use a long (6–8 cm) osteoperiosteal segment.

  • Use a proximal step-cut to prevent proximal migration.

  • Taper distally to avoid stress risers.

  • Use sequential osteotomes, not an oscillating saw.

  • Anatomic fixation of the osteotomized segment is critical to ensure union of the osteotomy.

  • At least one wire is passed through the osteotomy fragment to prevent proximal migration.

   

   

  REATTACHMENT OF OSTEOTOMY WITH SCREWS

  ■

   

  ■

  At least three cortical screws are inserted after implantation of the tibial component (TECH FIG 4).

  The screws are passed posteromedially and posterolater-ally around the tibial component using the triangular cross section of the proximal tibia.2,7

  TECH FIG 4 • Lateral radiograph of the knee after revision TKA with reattachment of the tibial tubercle osteotomy using screws.

   

   

  TECHNIQUES

   

  POSTOPERATIVE CARE

• If fixation of the tibial tubercle osteotomy is adequate, weight bearing is permitted as tolerated with unrestricted range of movement in a hinged knee brace.

• If fixation is not adequate, the patient can bear weight as tolerated with the knee locked in full extension in a brace until there is radiologic evidence of union.

   

  OUTCOMES

• Whiteside8 reported good results using a tibial tubercle osteotomy to gain extensile exposure during 136 TKAs, of which 110 were revision procedures. At 2-year follow-up, the mean postoperative range of movement was 94 degrees, with a 1.5% incidence of extensor lag. Three tibial shaft fractures and two avulsions of the tibial tubercle were reported in this series, but no non-unions.

• Mendes6 reported 87% good-to-excellent results (based on the Knee Society Score) in 64 patients in whom a tibial tubercle osteotomy was used for extensile exposure during revision TKA. At an average follow-up of 30 months, the mean postoperative range of movement was 107 degrees, with a 4.5% incidence of extensor lag. One fracture of the tibia, no tibial

  avulsions, and two non-unions of the osteotomy were reported in this series.

• Barrack1 reported a significantly lower incidence of extensor lag following tibial tubercle osteotomy when compared to V-Y quadriceps turndown, although outcome scores were similar for both groups at the 4-year follow-up.

• Biomechanical studies show that although reattachment of an osteotomy with screws has greater fixation strength than cerclage wires, placement of screws around revision tibial component stems is difficult.2 Cerclage wires are easier to place and still provide solid fixation, especially when combined with a proximal step-cut osteotomy.

• High rates of fixation failure with tibial tubercle osteotomy most likely are due to the use of small (<3 cm) osteoperiosteal fragments and failure to maintain lateral soft tissue attachments in continuity with the osteotomized segment.9

  COMPLICATIONS

• Extensor lag1,6,8

• Tibial fracture6,8

• Tibial tuberosity avulsion7,8

• Non-union of osteotomy6

• Metalwork removal7,8

REFERENCES

1. Barrack RL, Smith P, Munn B, et al. The Ranawat Award. Comparison of surgical approaches in total knee arthroplasty. Clin Orthop Relat Res 1998;356:16–21.

2. Caldwell PE, Bohlen BA, Owen JR, et al. Dynamic confirmation of fixation techniques of the tibial tubercle osteotomy. Clin Orthop Relat Res 2004;424:173–179.

3. Clarke HD. Tibial tubercle osteotomy. J Knee Surg 2003;16:58–61.

4. Dolin MG. Osteotomy of the tibial tubercle in total knee replacement: A technical note. J Bone Joint Surg Am 1983;65A: 704–706.

5. Kelly MA, Clarke HD. Stiffness and ankylosis in primary total knee arthroplasty. Clin Orthop Relat Res 2003;416:68–73.

6. Mendes MW, Caldwell P, Jiranek WA. The results of tibial tubercle osteotomy for revision total knee arthroplasty. J Arthroplasty 2004;19:167–174.

7. Ries MD, Richman JA. Extended tibial tubercle osteotomy in total knee arthroplasty. J Arthroplasty 1996;11:964–967.

8. Whiteside LA. Exposure in difficult total knee arthroplasty using tibial tubercle osteotomy. Clin Orthop Relat Res 1995;321:32–35.

9. Wolff AM, Hungerford DS, Krackow KA, et al. Osteotomy of the tibial tubercle during total knee replacement. J Bone Joint Surg Am 1989;71A:848–852.