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eISSN: 2374-6939

Orthopedics & Rheumatology

Research Article Volume 1 Issue 3

Outcome analysis of displaced acetabular fractures

Kalia RB, Gupta P, Badoni N, Anant Singh

Department of orthopedics, India

Correspondence: Anant Singh, Senior resident, Department of Orthopaedic Surgery, All India Institute of Medical Sciences, Raipur, India, Tel 08120085833

Received: August 25, 2014 | Published: November 8, 2014

Citation: Kalia RB, Gupta P, Badoni N, et al. Outcome analysis of displaced acetabular fractures. MOJ Orthop Rheumatol. 2014;1(3):53-56. DOI: 10.15406/mojor.2014.01.00015

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Abstract

Over a period of three and half years, twenty-eight patients with complex displaced fractures of the acetabulum were operated at our institution. Between December 2004 and June 2008 twenty-eight patients with closed displaced acetabular fractures were treated with open reduction and internal fixation. The surgical procedure consisted of open reduction and internal fixation by anterior, posterior or combined approaches during the same period of anesthesia. The cases were reviewed to determine the adequacy of the various approaches, ease of reduction and to determine the choice of approach for various fracture patterns. The patients were followed for a mean period of 20 months after surgery (Range 12 months to 36 months). Anatomical reduction and rigid internal fixation could be achieved in 71% of the cases. The clinical result was excellent for 11 hips (39 per cent), good for 10 hips (36 percent), fair for 3 hips (11 per cent), and poor for four hips (14 per cent). Osteonecrosis of the femoral head was noted in one hip (3 per cent), and progressive wear of the femoral head was seen in two hips (6 per cent). Our findings indicate that anatomical reduction can be achieved in these complex injuries in a large percentage of cases with satisfactory midterm results.

Keywords: Acetabulum fracture, Fixation, Approach

Introduction

High-energy fractures resulting in an unstable hip or incongruous weight-bearing area are best managed operatively. No displaced fractures or those not involving the weight-bearing acetabulum, especially in older patients can be managed no operatively. Anatomic reduction of the acetabulum is important for good long-term function. Residual displacement of more than one or two millimeters may lead to progressive posttraumatic osteoarthritis and a poor functional result.1 However anatomic reduction does not always ensure a good result. Impacted fragments tend to worsen the prognosis. Cartilage impaction injury, comminution, and fragment avascularity may also lead to posttraumatic arthritis.

Materials and methods

This is a retrospective study with level of evidence 3 in 28 patients which we have operated between December 2004 to June 2008. Displaced fractures were defined as fractures with minimum five millimeters of displacement in any of the three standard radiological views. All 28 patients were operated within twenty-one days after the injury. The study included twenty-six male patients and two female patients. The ages of the patients ranged from 21 to 65 years (mean, thirty-two years). Twenty patients (71 percent) were from twenty to forty years old. The most common mechanisms of injury were a motor-vehicle accident (23 patients; 82 per cent), fall from height (five patients; 17 per cent). Six patients had associated injuries. Five fractures were associated with a head injury and one fracture had an injury involving lower extremity.

All patients were initially evaluated with use of three standard plain radiographs (one anteroposterior radiograph and two 45-degree oblique radiographs of the pelvis).2 Computerized tomographic scans and three-dimensional reconstructions of the scans were made for all patients. The displacement of the fracture was measured separately. The maximum displacement seen on each of the three radiographs was recorded. The fractures were classified according to the criteria of Letournel and Judet3 of the 28 fractures, six fractures (21 per cent) were simple fracture types and twenty two (79 per cent) were associated fracture types. The simple fracture types included five posterior wall fractures (18 per cent) and one anterior column fractures (4 per cent). The associated fracture types included seven posterior column-posterior wall fractures (25 per cent), four transverse-posterior wall fractures (14 per cent), one T-shaped fractures (4 per cent), and ten both-column fractures (36 per cent). Seven hips had a posterior dislocation and one had an anterior dislocation. All eight hips were reduced before the operation. Preoperative below knee skin traction was used in all patients (Figure 1).

Figure 1 Preoperative radiograph showing anterior column fracture acetabulum.

Operative technique

On the basis of the classification and the specific configuration of the fracture judged on radiographs and 3D CT scans a single operative approach was selected if the entire reduction could be performed with use of one approach (Figure 2A & 2B). The Kocher-Langenbeck approach was used in 12 hips (43 per cent); the ilioinguinal approach was used in 12 hips (43 per cent); and the extended iliofemoral approach was used in one (4 per cent). In three hips (11 per cent), an initial Kocher-Langenbeck or ilioinguinal approach was inadequate to complete the reduction and fixation and a combined ilioinguinal and Kocher-Langenbeck approach was used, during the same session of anesthesia. The extended iliofemoral approach was used for associated anterior wall and anterior column fractures. The Kocher-Langenbeck approach was used for posterior wall, posterior column, and posterior column-posterior wall fractures. The ilioinguinal approach4 was used for anterior column, and both column fractures with greater displacement of anterior column. The reduction was performed by direct manipulation of the bone with special reduction instruments with the goal to achieve an anatomical reduction of the acetabulum. The posterior stable fragment attached to the sacroiliac joint was used as the starting point and all fractures were reduced from posterior to anterior. The fixation was performed with plates and screws in 27 hips (96 per cent) and with screws alone in 1 hip (4 per cent) with a posterior wall fracture.2 Fixation with interfragmentary screws, with the reduction held with reduction forceps or clamps, was usually performed before fixation with a plate. Kirschner wire fixation was used for very small fragments to augment fixation achieved by a screw. Duration of Surgery ranged from 2 1/2 hours to 5 hours. The duration of the operation varied according to the operative approach. Combined approaches were the most time consuming. The duration of the operation decreased with increasing familiarity with the surgical approaches.

Figure 2 A, B: Dimensional CT scan of the same patient as in Figure 1 showing displaced fracture anterior column acetabulum with posterior hemi transverse fracture.

Various kinds of articular cartilage injuries were noted like free intra-articular fragments, chondral fissures on the cartilage of the femoral head and impacted fractures on the acetabular surface were observed in seven fractures operated by the Kocher-Langenbeck approach. Removal of intraarticular fragments required redislocation of the hips in five patients. Patients operated by ilioinguinal approach had limited visualization of the intra-articular injury and cartilage injuries could not be observed (Figure 3). Postoperatively, immobilization or traction was not used. Non weight bearing exercises were commenced within one week of the operation. Partial weight bearing was allowed after eight weeks and full weight-bearing was allowed twelve weeks after the operation. Low molecular weight heparin was used as prophylaxis against deep venous thrombosis in all patients. No routine prophylaxis against heterotopic ossification was used.

Figure 3 Postoperative radiograph of the same patient as in Figure 1 operated by the Ilioinguinal approach showing anatomical reduction.

Results

Clinical and radiographic examinations were performed and data were recorded at three months, six months, one year, and two years. At the last follow-up examination, radiographic and clinical grades were assigned (Figure 4). The clinical grade was based on a modification of the system of Merle d’Aubigne and Postel (Table 1).

Figure 4 Follow up radiograph at 3 months showing congruent hip joint and maintenance of anatomical reduction graded as excellent radiologically.

Clinical Grading System

Points

Pain

 

None

6

Slight or intermittent

5

After walking but resolves

4

Moderately severe but patient is able to walk

3

Severe, prevents walking

2

Walking

 

Normal

6

No cane but slight limp

5

Long distance with cane or crutch

4

Limited even with support

3

Very limited

2

Unable to walk

1

Range of motion*

95–100%

6

80–94%

5

70–79%

4

60–69%

3

50–59%

2

<50%

1

Clinical grade†

Excellent

18

Good

15, 16, or 17

Fair

13 to 14

Poor

<13

Table 1 Data of Clinical and Radiographic results

Operative reduction

The mean postoperative displacement measured on x-rays was two millimeter (range, one to twelve millimeters). The postoperative reduction was graded as anatomical for 20 hips as the displacement was zero to two millimeters (71 per cent), imperfect for 3 hips as the residual displacement was two to four millimeters (11 per cent), poor for 5 hips as the residual displacement was more than four millimeters (18 per cent). At the time of recent follow up all had united (Table 2). Most of the simpler fracture types could be reduced anatomically. In one case fixation of posterior lip failed because of non compliance of the patient who started unrestricted weight bearing in the immediate post operative period. Of the associated fracture types seven fractures could not be reduced anatomically (32 per cent).The over-all clinical result was excellent for 11 hips (39 per cent), good for 10 hips (36 percent), fair for 3 hips (11 per cent), and poor for four hips (14 per cent).

Radiological Grading System

Excellent

Normal appearance of the hip

Good

Mild changes, small osteophyte,  moderate (one-millimeter) narrowing of the joint, and minimum sclerosis

Fair

Intermediate changes, moderate osteophyte, moderate (less than 50 per cent), narrowing of the joint, and  moderate sclerosis

Poor

Advanced changes, large osteophyte, severe (more than 50 per cent) narrowing of the joint, collapse or wear of the femoral head, and acetabular wear.

Table 2 Radiological Grading System

Complications

Osteonecrosis of the femoral head was noted in one hip (3 per cent), and progressive wear of the femoral head was seen in two hips (6 per cent). Loss of reduction occurred in one posterior lip fracture because of noncompliance which resulted in incongruence of the hip which was treated by total hip replacement. Heterotopic ossification was noted in two cases (Brooker class I). We had one preoperative complication of initial tear of the external iliac artery which was repaired immediately with no unto worth complication afterwards. Screw pullout of the trochanteric osteotomy happened in one case which needed revision surgery. We had no post-operative infection in our patients.

Discussion

Displaced fractures of the Acetabulum are a diverse group of serious injuries which are difficult to treat with various complications like post-traumatic osteoarthritis, osteonecrosis of the femoral head, acetabular non-union and bone defects which may require revision to total hip arthroplasty.5,6 Saterbak et al.7 in a study performed to evaluate the factors that predict clinical failure after posterior wall fractures of the acetabulum, reported a mean Musculoskeletal Function Assessment score of 47.3 for ten patients who had a failure of treatment and a mean score of 26.1 for thirty-one patients who did not have failure.8

The success of the operation after high-energy trauma is contingent on the articular cartilage of the hip remaining viable. If post-traumatic osteoarthritis develops in the presence of viable cartilage, it is primarily the result of altered pressure distribution of the femoral head articulating with an inaccurately reduced acetabulum. Specifically, the contact area between the head of the femur and the acetabulum is markedly reduced by a malreduction, and the force per unit area to the articular cartilage increases. This results in loss of the joint space and, sometimes in wear of the femoral head. The most clearly predictive initial factor was injury to the cartilage or bone, or both, of the femoral head; this factor was significantly predictive of a worse prognosis but not all potentially deleterious effects of the initial injury can be completely countered in all patients. In our study over-all clinical result was excellent for 11 hips (39 per cent), good for 10 hips (36 percent), fair for 3 hips (11 per cent), and poor for four hips (14 per cent),which clearly shows 75 percent patient have excellent to good midterm results.

The goal of treatment is anatomical reconstruction and rigid internal fixation resulting in a functional, mobile, painless hip joint that continues to function for the rest of the patient’s life.7 This goal can be achieved by properly planned approaches. However, despite the appearance of an anatomical reduction on radiographs, there may still be imperfections on areas of the articular surface that are invisible on standard plain radiographs or are hidden by plates and screws. It must therefore be hypothesized that satisfactory clinical and radiographic results are due in part to the capability of the acetabulum in an adult to tolerate limited changes in the distribution of pressure and perhaps to reshape itself over time. As the learning curve for the complex fracture patterns is long with potential disastrous complications because of the deep location of the acetabulum, the presence of the proximal femur with its tenous blood supply and close proximity of various neurovascular structures but as more experience is gaining over years hopefully the outcomes will also improve.

Conclusion

The relationship between the quality of the reduction and the clinical result closely parallels the findings of Letournel and Judet and some other studies in the recent year.9–12 It can therefore be concluded that the positive results reported by Letournel9 and Judet2 can be reproduced by the concentrated efforts of a team of surgeons who treats these fractures frequently and can give better outcomes to patients for extended periods of time.

Acknowledgments

None.

Conflicts of interest

The author declares that there is no conflict of interest.

References

  1. Matta JM, Anderson LM, Epstein HC, et al. Fractures of the acetabulum: A retrospective analysis. Clin Orthop Relat Res. 1986;(205):230–240.
  2. Judet R, Judet J, Letournel E. Fractures of the acetabulum: classification and surgical approaches for open reduction. J Bone and Joint Surg Am. 1964;46:1615–1646.
  3. Letournel E, Judet R. Fractures of the Acetabulum. In: Reginald AE (Ed.), Springer, New York, USA, 1993.
  4. Letournel E. The treatment of acetabular fractures through the ilioinguinal approach. Clin Orthop Relat Res. 1993;(292): 62–76.
  5. Knight R A, Smith H. Central fractures of the acetabulum. J Bone and Joint Surg Am. 1958;40–A(1):1–16.
  6. Johnson EE, Matta JM, Mast JW, et al. Delayed reconstruction of acetabular fractures 21–120 days following injury. Clin Orthop Relat Res. 1994;(305):20–30.
  7. Saterbak AM, Marsh JL, Nepola JV, et al. Clinical failure after posterior wall acetabular fractures: the influence of initial fracture patterns. J Orthop Trauma. 200;14(4): 230–237.
  8. Kebaish AS, Roy A, Rennie W. Displaced acetabular fractures: long–term follow–up. J Trauma. 1991;31(11):1539–1542.
  9. Triantaphillopoulos PG, Panagiotopoulos EC, Mousafiris C, et al. Long–term results in surgically treated acetabular fractures through the posterior approaches. J Trauma. 2007;62(2):378–382.
  10. Matta JM, Letournel E, Browner BD. Surgical management of acetabular fractures. 1986.
  11. In Instructional Course Lectures, The American Academy of Orthopaedic Surgeons. In: St. Louis & Mosby CV (Eds.) Vol. 35, pp. 382–397.
  12. Briffa N, Pearce R, Hill AM, et al. Outcomes of acetabular fracture fixation with ten years’ follow–up. J Bone Joint Surg Br. 2011;93(2):229–236.
  13. Giannoudis PV, Grotz MR, Papakostidis C, et al. Operative treatment of displaced fractures of the acetabulum: A meta–analysis. J Bone Joint Surg Br. 2005;87(1):2–9.
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