Abstract
Instability is one of the most common complications after total hip arthroplasty and can present early or late after hip replacement. Late instability is considered if the event occurs five or more years after the primary arthroplasty, and in contrast to early dislocation, it appears to require operative intervention. The incidence of late instability may be greater than initially appreciated, and the cumulative rate rises with longer follow-up. The etiology of hip instability is often multifactorial with the presumed risk factors for late instability including long standing malposition of the components, trauma, deterioration in muscle mass, neurological status impairment and polyethylene wear. This article presents a synopsis of published studies on late instability and outlines our institutional experience with treatment of late dislocation following total hip arthroplasty occurring due to polyethylene wear.
Keywords: Dislocation, Hip, Arthroplasty, Joint instability, Postoperative complications, Prosthesis failure
Hip pain due to underlying arthritis represents a common reason for individuals to seek medical attention. The symptoms of arthritis may be addressed by non-operative management delivered by primary care physicians;1 however, for patients failing non-operative treatment, total hip arthroplasty (THA) is considered. THA is one of the most successful procedures in orthopaedic surgery that has effectively improved the quality of life of patients affected by osteoarthritis of the hip.2 Unfortunately the outcome of THA is compromised by complications such as instability.3 Instability comprises two inter-related yet distinct conditions, dislocation and subluxation. Dislocation is a term reserved for situations in which the femoral head is completely out of the acetabulum, whereas subluxation is partial dislocation in which the femoral head is partially out of the acetabulum.
Instability can present early or late after hip replacement.4,5 Late dislocation is considered if the event occurs five or more years after the primary arthroplasty, and in contrast to early dislocation, it appears to require operative intervention. Recent studies suggest that the incidence of late dislocation may be greater than initially appreciated4,6–8 and that the cumulative rate rises with longer follow up.9
In this article, we review the etiological factors for late instability. We also present our institutional experience on late instability due to polyethylene wear as the primary cause when no discrete reason for dislocation is identified.
Etiology
The etiology of hip instability is often multifactorial. Patient demographics, operative technique and implant design variables have been demonstrated to affect the risk of dislocation. There are multiple surgical and implant-related factors that predispose to dislocation, such as malorientation of the components, decreased head-to-neck ratio, proximal placement of the acetabular component, decreased femoral offset, posterior surgical approach, abductor insufficiency secondary to trochanteric migration, or abductor avulsion.3,5,10–12 Patient risk factors for early dislocation after primary THA are female gender, older patients, neurological dysfunction or cognitive impairment, and a preoperative diagnosis of osteonecrosis of the femoral head, femoral neck fracture and/or inflammatory arthritis.3,9,10,12 The presumed etiological factors for late instability include long standing malpositioning of the components, trauma, deterioration in muscle mass, neurological status impairment and polyethylene wear4,5,13 (table 1 ▶).
Table 1.
Risk factors for late instability following total hip arthroplasty.
| Female gender |
| Younger age |
| Pseudocapsule laxity |
| Abductors mechanism insufficiency |
| Previous subluxations |
| Hip trauma |
| Cognitive impairment |
| Neuromuscular dysfunction |
| Initial malposition of the acetabular component |
| Loosening with migration of the components |
| Polyethylene wear |
Presentation
Instability following THA is a frequent and very distressful complication. It may occur early or late, and can present as a single or recurrent event. If the prosthesis dislocates early after surgery, there is a higher rate of success for closed reduction, as opposed to late dislocation in which revision arthroplasty surgery is most likely required.4 Late instability can be a challenging problem as it is associated with a higher risk of recurrent dislocation and rate of reoperation.4,12,14
Prevalence
The prevalence of dislocation following THA is likely underestimated. A close surveillance and a more rigorous follow-up for a longer period is likely to identify more late dislocations.4,9,11 The cumulative risk of a first-time dislocation progressively increases with time: 1% at 1 month, 1.9% at 1 year, a constant rate of 1% every 5 years, and a 7% dislocation rate at 25 years.9 Late dislocation is more common than previously thought, as one third of all the dislocated hips occur five or more years after the primary replacement.4 Berry et al9 reported a 4.8% prevalence rate of dislocation after 6,623 consecutive primary Charnley THAs over 15 years.
Institutional Experience
We have previously reported on the association polyethylene wear and late dislocation of the hip.13,15 Twenty-two patients with late dislocation and polyethylene wear (measuring >2 mm) were retrospectively evaluated (figure 1 ▶). Patients with onset of instability at less than 5 years postoperatively, those with radiographic and/or intraoperative evidence of component malpositioning, and patients with any previous history of prosthetic hip instability were excluded. Analysis of the medical records and radiographs were performed.
Figure 1.
Anterior-posterior radiograph of the left hip in a 68-year-old patient. (A) Polyethylene wear is present and can be identified by eccentric seating of the femoral head in the acetabulum. (B) Polyethylene wear was implicated as the main cause of late instability in this patient.
The cohort consisted of 7 women and 15 men with a mean age of 57.8 years (range 35–85) at initial primary arthroplasty. The revision surgery was performed between the years 1982 and 2000. The average time from initial arthroplasty to dislocation was 9.0 years. Revision surgery to address polyethylene wear and instability was performed at a mean of 11.1 years (range 5.8 to 23 years). Direct lateral approach was used in all cases.
Acetabular liner was exchanged in 11 of the 22 patients. The liner was cemented into the well-fixed and well-positioned cup in two hips, and inserted into a functioning locking mechanism in nine hips. The remaining 11 patients with all polyethylene, cemented acetabular component required revision of the acetabular component. The initial acetabular component was confirmed to be well-positioned intraoperatively. An uncemented acetabular component was inserted press-fit for all these patients. The femoral head was changed in all cases. Five of the 22 patients, who were noticed to have osteolysis around their cemented prosthesis, underwent revision of their femoral component using an extensively coated component. Revision surgery restored stability to 18 patients (82%), with a redislocation rate of 18% (4/22). Although the patients who underwent acetabular liner exchange did not present any episodes of instability during follow-up, it is important to highlight that all the cases had also received femoral head exchange. Furthermore, the femoral head was upsized from 22 to 28 mm in three patients and the neck length increased in an additional three patients.
Discussion
The success of THA in restoring function and alleviating pain cannot be disputed. The number of primary hip replacements per year in the United States is rising dramatically, and this trend is expected to continue at an exponential rate.16 Therefore, primary care physicians, as well as orthopedic surgeons, are likely to encounter more patients in need of THA.
Although very successful, THA may fall victim to complications such as instability. Instability after THA can occur after 2% to 5% of primary hip surgeries.3 Late instability represents one-third of all dislocations.4 Coventry7 described that patients with late dislocation had a larger range of motion and attributed pseudocapsule laxity as a possible etiological factor for late dislocation.
A recent study from the same institution delineated the causes of late dislocation after 19,680 primary THAs over a period of 25 years. They identified a total of 165 hips which had the first dislocation event five or more years after the primary arthroplasty.4 Factors associated with a higher risk of late dislocation included female gender and a younger age at the time of operation. One-fourth of their cohort presented with previous subluxations, substantial trauma or marked neurological impairment.4 Surgical or implant-related factors such as initial malposition of the acetabular component, loosening with migration or change in position of the components, or a femoral head penetration of more than 2 mm into the acetabular polyethylene were radiographically identified in 34% of these patients.4 Late dislocation recurred in 55% of the patients, and 61% of these recurrent dislocations required surgical intervention for treatment.
Polyethylene wear is an important cause of late instability (figure 1 ▶). Primary care physicians need to be familiar with radiographic evaluation and detection of liner wear in order to seek an early intervention. This condition can be identified by eccentric seating of the femoral head in the acetabular component (figure 1 ▶). Once identified, these patients can receive surgical intervention that may prevent complications such as late instability and osteolysis.
The exact mechanism by which polyethylene wear results in late instability remains unknown. It has been suggested that polyethylene wear debris eliciting an inflammatory response may result in capsular distension and subsequent instability.7 On the other hand, eccentric seating of the femoral head with asymmetric excursion arc of motion may impart a mechanical disadvantage predisposing the hip to impingement, levering out and subsequent dislocation. Another factor is that polyethylene-wear presenting many years after the initial surgery occurs in the context of an aging patient with gradual deterioration in the status of the periarticular muscle mass and the dynamic stabilizers. The critical importance of soft tissues, particularly the abductors, in stabilizing the hip cannot be overemphasized.
The treatment of late dislocation as a result of polyethylene wear by liner exchange or revision of the all-polyethylene acetabular component is a viable option that can be expected to provide significant improvement in function and stabilize the hip in most patients.
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