Abstract
Acetabular dysplasia is a significant problem in the spectrum of developmental dysplasia of hip. In a younger child, positioning the femoral head into the acetabulum helps in reciprocal remodeling of the acetabulum and correction of dysplasia. In an older child, the remodeling potential is limited and often the acetabular dysplasia needs surgical intervention in the form of a pelvic osteotomy.
Thus, pelvic osteotomy forms an integral part of surgical management of hip dysplasia. The ultimate goal of these osteotomies is to preclude or postpone the development of osteoarthritis and add more years of life to the native hip.
Pelvic osteotomies play a pivotal role in normalizing hip morphology. The choice of pelvic osteotomy depends on the age of a child, the type of dysplasia and the status of the tri-radiate cartilage.
Several types of re-directional and reshaping pelvic osteotomies have been described in the literature to improve the stability and restore the anatomy and biomechanics of the dysplastic hip.
This article attempts to review the current indications for various pelvic osteotomies with a brief description of their techniques along with the outcomes and complications published thus far. Besides, the guidelines to choose the right pelvic osteotomy are also provided.
Introduction
Surgical correction of idiopathic developmental dysplasia of the hip (DDH) is one of the most challenging problems in pediatric orthopedic surgery. The treatment goal is to achieve a stable, congruent and concentric hip joint as early as possible, which in turn will preclude or postpone the development of degenerative osteoarthritis (OA) of the hip (1, 2). Despite extensive long-term studies, controversy still exists in all realms of surgical treatment of DDH (3, 4). As far as the acetabular side procedures are concerned, ambiguity still exists regarding the remodeling capacity of acetabulum, ideal age for pelvic osteotomy (PO), type of PO, safety and long-term radiological and clinical outcomes of each type of osteotomy.
The choice of treatment for DDH is age-dependent (5). Even after successful reduction of the hip joint, the remodeling capacity of the acetabulum decreases with age, leading to residual dysplasia, late subluxation or dislocation. It is believed that in DDH, if the treatment is not started before weight-bearing, the prognosis is poor for the satisfactory development of hip joint by any of the conservative methods (6). Pemberton stated that ‘in the treatment of DDH in a child 1 year and older, surgical correction by direct attack on the acetabulum is a more conservative and dependable method of treatment than so-called conservative methods’ (7).
The upper age limit of acetabular remodeling is 4 years, and beyond this, the correction of acetabular dysplasia will need surgical intervention in the form of PO. Spence et al. compared 38 patients who underwent open reduction (OR) and femoral osteotomy (FO) with 33 patients who underwent OR and PO in children aged 15 months to 4 years. Patients with PO had quicker and better improvement in the radiographic acetabular index and thus concluded that PO was more effective in improving acetabular dysplasia than FO (8).
Although PO is a powerful tool for improving radiographic parameters in DDH, it may not be necessary for all patients (5). In the age group between 18 months and 4 years, the need for a PO is decided based on the degree of acetabular dysplasia in serial radiographs over 6 months to 1 year. Persistent acetabular dysplasia with the subluxation is an absolute indication for a PO. This article presents a review of various reconstructive POs, indications for each, a brief technical description and their outcomes and complications. We also present simple guidelines to choose the right type of PO for a given patient.
Why is a pelvic osteotomy needed in DDH?
Until infancy, concentric reduction of the femoral head into the acetabulum through closed or open method is generally sufficient to get reciprocal remodeling to achieve a stable and congruent hip. Past infancy, most surgeons agree that treatment with a PO, with or without a FO, is indicated to ensure adequate femoral head coverage (9). Although the minimum age at which a PO should be performed is still controversial, it is generally accepted that DDH in a child above walking age will most likely need a PO (10).
Pemberton stated that the ‘structural defect in the anterior acetabulum is a constant finding in DDH, and surgical correction of dysplasia should include correction of this defect’ (6). An ideal PO should address the anatomical deficiency of the acetabulum to improve the femoral head coverage. However, the dictum of constant anterolateral acetabular deficiency in DDH is now debatable. Analysis of acetabular morphology using 3D CT demonstrates that the acetabular deficiency in DDH can occasionally be directly lateral or posterior superior (11, 12). This reveals that acetabular dysplasia is more complex than it is generally believed to be. More than localized defect or hypoplasia, acetabular dysplasia is a combination of mal-direction, marginal erosion, hypoplasia (localized or global), abnormal shape and decreased acetabular surface area (13). This emphasizes the fact that one single type of PO would not suffice to address the entire spectrum of acetabular deficiency. It cannot be overemphasized that the primary goal of any PO is only to improve the femoral head coverage and stability and not to obtain a reduction of the joint. Essentially, the hip must be well reduced before any reconstructive PO is undertaken.
When should a pelvic osteotomy be done in DDH?
There is a well-established correlation between age at reduction and residual dysplasia. Lindstrom et al. have shown that the acetabular index (AI) at follow-up is directly related to the age at an initial reduction (14). Salter and Dubos have stated that acetabular remodeling cannot be ensured after the age of 18 months (15). Others have suggested that remodeling may occur up to 8 years. Remodeling of the acetabulum is considered to be most predictable in children younger than 4 years. The risk of producing a dysplastic acetabulum will be doubled if the hip is not reduced by this age (16).
In general, for children up to 12–18 months, though OR is needed to get a concentric reduction, PO is rarely required considering remodeling potential. Between 18 months and 4 years, the need for a PO at the time of OR is controversial (17, 18, 19). One school of thought is to delay the acetabular procedure, assess the adequacy of the remodeling and decide based on serial follow-up radiographs. However, Salter and Pemberton strongly believed in adding the acetabular procedure at the time of primary treatment to maximize the likelihood of normal acetabular development. DelBello et al. compared the results of OR alone, OR followed by delayed PO and OR plus immediate PO in a group of older children with DDH. Only the immediate osteotomy group achieved acetabular indices comparable to those in normal control subjects. Based on these findings, the authors recommended routine PO at the time of OR for all patients over the age of 18 months (20). In children 4 years or older, the PO is performed routinely because of the unpredictable remodeling potential. In children older than 8 years, the need for intervention is based on the symptoms, severity of the dysplasia and laterality. An acetabular side procedure will always be needed if the patient is planned for surgical intervention.
Overview of pelvic osteotomies
The pelvic osteotomies can be broadly grouped into three types: (1) re-directional osteotomies (Salter’s triple, periacetabular osteotomy and spherical osteotomy), (2) reshaping osteotomies (Pemberton, Dega and San Diego) and (3) salvage procedures (Chiari and shelf – not detailed in this review). If the hip joint can be concentrically reduced by either closed or open reduction, reconstructive POs are indicated. If a concentric reduction is not possible by any described methods, salvage procedures are opted.
Radiological assessment
Complete radiographic evaluation of the hip is essential before any hip osteotomy. It includes a standardized pelvis anteroposterior (AP) view, frog-leg lateral view, false-profile view and functional radiographs (abduction internal rotation, flexion abduction and adduction views) to determine the severity of acetabular dysplasia and deformity of the proximal femur. AP view should be assessed for a break in Shenton’s line, the appearance of acetabular sourcil, teardrop morphology, AI, center-edge angle of Wiberg (CEA), extrusion index and congruency of the hip joint. A widened teardrop with loss of the concavity of its lateral aspect characterizes hip subluxation or dislocation. Standard radiographic acetabular indices in different age groups are shown in Fig. 1 (21, 22). The standard pelvic radiographs do not differentiate anterior, superior or posterior deficiency. As acetabular dysplasia is more than a simple malrotation or anterolateral deficiency, a 3D CT greatly helps determine an individual hip's exact morphology and plan for an osteotomy specifically to correct the defect (21). Though not routinely done, in young children, analysis with 3D MRI gives a true morphology of a cartilaginous acetabulum.
Standard anterior surgical approach
All POs described for DDH can be performed through a single standard anterior approach. We prefer an anterior bikini incision, which is more cosmetic and versatile. Proximally, the iliac apophysis is elevated to expose the inner and outer iliac table and distally, the Smith–Peterson interval is utilized. To protect the lateral femoral cutaneous nerve, the fascia over tensor fascia lata (TFL) is incised rather than the traditional approach between Sartorius and TFL. The rectus femoris can either be released (if an OR is needed) or retracted laterally (rectus sparing approach prevents hip flexion weakness). The inner iliac table is elevated subperiosteally up to the sciatic notch. In the outer table, the abductors are tunneled (rather than complete elevation) in line with the desired osteotomy up to the sciatic notch (abductor-sparing approach).
For all acetabuloplasty procedures, care should be taken to protect the sciatic nerve and the superior gluteal neurovascular bundle in the greater sciatic notch by placing the blunt retractors subperiosteally in the notch (23). Pemberton, Dega, San Diego and Salter osteotomies need a bone graft (iliac autograft, graft from femur osteotomy or allograft) to hold the correction. Salter’s osteotomy, triple PO and periacetabular osteotomies are unstable and need internal fixation.
Re-directional osteotomies
These are complete innominate osteotomies, which can reorient the acetabulum to improve anterolateral coverage without change in size or shape of the acetabulum.
Salter innominate osteotomy (SIO)
In 1961, Salter first described a complete innominate osteotomy for stabilizing the reduced hip by redirection of the entire acetabulum. The pubic symphysis serves as a rotating hinge, and the acetabulum is redirected to cover the anterolateral deficiency (24).
The primary indication for an SIO is an anterolateral acetabular deficiency in an otherwise concentrically reduced hip. A shallow acetabulum is a relative contraindication. SIO is indicated between 18 months and 8 years of age, beyond which the correction could be suboptimal due to rigidness of symphysis. However, the best results are shown in <4 years of age. The most common error that leads to a poor outcome is failure to achieve a concentric reduction of the hip joint before innominate osteotomy.
The SIO is a transverse iliac osteotomy from just above the anterior inferior iliac spine (AIIS), extending to the sciatic notch (Fig. 2A). The distal acetabular fragment is manipulated by a pointed clamp to hinge on the pubic symphysis and provided anterior and/or lateral translation. A triangular wedge of bone is cut from the iliac crest and placed into the osteotomy site and fixed with two- or three-threaded K-wires (Fig. 2B).
Salter et al. reported 93.6% excellent to good results in patients operated from 18 months to 4 years of age with no failures in a review of 15-year follow-up on 140 patients. In the 4–10-year age group, only 56.7% achieved excellent to good results, and the failure rate was 6.6% (15). The reported complications include avascular necrosis (AVN) (5.7%), loss of correction (2.8%), re-dislocation (5.6%), sciatic nerve palsy and acetabular retroversion. Overcorrection can lead to retroversion of the acetabulum and posterior insufficiency. Posterior subluxation of the femoral head, especially when combined with femur osteotomy, was reported in a series by Dora et al. (25). The SIO is not recommended in older children, albeit few reports of its successful application in the older age group as well (26, 27).
Thomas et al. reported the survivorship of SIO at 45 years as 54% and said that bilateral dysplasias were associated with poor outcomes (28). Bohm et al. reported overall survivorship of 90% following SIO at an average of 30 years of follow-up (29). Kobayashi et al. reviewed long-term radiographic results of SIO and found that the osteotomy does not consistently result in acetabular retroversion into adulthood (30).
Triple pelvic osteotomy (TPO)
TPO is a complete reorientation osteotomy described to overcome the drawbacks of the SIO. A prerequisite of the operation is a congruous joint or a joint that would become congruous by the osteotomy. The primary indications are in older children and adolescents with open TRC, where other POs are inadequate or counterproductive and also where the acetabulum requires a change in the version. Sufficient hip abduction (20–30) should be present to allow lateral rotation of the acetabulum. The drawbacks of TPO are it violating the posterior column and creating pelvic discontinuity. It is an unstable osteotomy requiring rigid fixation and immobilization. It leads to pelvic asymmetry and affects the birth canal negating the possibility of a normal vaginal delivery.
The TPO technique continues to evolve since its original description by Le Coeur in 1965 (31). The main limitation of this original technique is that the sacrospinous ligament remains attached to the mobile fragment and can lead to retroversion of the acetabular fragment. Steel modified Le Coeur’s TPO to divide the ischium through an incision in the gluteal region (32). Many modifications of the TPO are described with changes at the level of the ischial cut and the type of the iliac cut (33, 34, 35, 36) (Fig. 2C and D).
In Tonnis TPO, ischial cut is made in a prone position just below the acetabulum exiting proximal to the ischial spine. The proposed advantages are less compromise in pelvic stability, greater mobility of the acetabular fragment for lateral rotation and medial displacement, avoiding the possibility of retroversion (33). The Bernese TPO is done through a single anterior incision, and the cuts are similar to Tonnis TPO. It is important to stay extra-periosteal to avoid injury to the tri-radiate cartilage. A modification of Bernese TPO is described in which the ischial cut is done through a medial incision (36, 37). Lipton’s modified TPO and interlocking type TPO are modifications of the iliac cut to increase the stability and contact of the osteotomy (34, 35, 38) (Fig. 2D).
Bernese periacetabular osteotomy
Ganz et al. in 1988 described a complete reorientation osteotomy with bone cuts made close to the acetabulum that can allow for the maximum correction of version, lateral and anterior coverage (39). The primary indication is to improve the congruency and coverage of hip with acetabular dysplasia in patients with closed TRC.
The Bernese peri-acetabular osteotomy (PAO) technique has been described in detail and has not changed significantly over time (39). Most surgeons use a single anterior approach that spares the abductor muscles, performing the osteotomies from the inner aspect of the pelvis. These include an incomplete osteotomy of the ischium, a complete osteotomy of the pubis and a biplanar osteotomy of the ilium. The continuity of the posterior column of the acetabulum is maintained (Fig. 2E and F). The intact posterior column makes this osteotomy very stable, and postoperative immobilization is not required. Additional advantages include preserving the blood supply to the acetabular fragment and preserving the shape of the pelvis, which permit normal vaginal delivery. The major disadvantage is the technical difficulty and steep learning curve.
Siebenrock et al. reported the long-term results in 71 of the 75 hips initially reported by Ganz. At a mean follow-up of 11.3 years, the hip joint was preserved in 82% of the patients, with good to excellent results in 73%. The remaining patients required salvage procedures at an average of 6.1 years. The factors associated with an unfavorable outcome were older age at the time of surgery, moderate to severe pre-operative arthritis, an associated labral lesion, less anterior coverage correction and suboptimal postoperative radiological indices (40).
Reshaping osteotomies
Reshaping osteotomies are incomplete innominate osteotomies in which the acetabular roof is bent down to increase the coverage at the desired place of deficiency. These are rightly called ‘acetabuloplasties’ and are inherently stable, which doesn’t require fixation (Fig. 3).
Pemberton pericapsular osteotomy (PPO) (anterolateral acetabuloplasty)
Paul A Pemberton described a pericapsular osteotomy for DDH in 1965, one of the most popular acetabuloplasties (6). It is recommended in a child >1 year of age or who has started walking. As this technique depends on the plasticity of TRC, it can be done up to 12–14 years, after which the triradiate will become too rigid (6). The hinging occurs at TRC till 4 years of age and in older children, along with hinging at TRC, rotation also occurs at the symphysis and sacroiliac joint.
In this, a bicortical iliac osteotomy is done, which starts just above the AIIS and goes into the posterior column of acetabulum halfway between the sciatic notch and posterior acetabular rim and stops short of the ilio-ischial ramus of the TRC. The osteotomy is curvilinear, parallel to and approximately 1 cm above the joint capsule (Fig. 4).
Pemberton reported good results in 94.3% cases, and the AVN rate was 10.4%, most of which were Kalamchi type-II with typical findings of coxa valga (6). Wu et al. studied the effect of an isolated PPO on rates of AVN in patients who underwent only an OR with no FO. In 49 patients who were followed for >10 years, 51% had some AVN and 37% had clinically relevant AVN. They have reported that more distal positioning of the femoral head after the PO is an independent risk factor for AVN (41). Careful surgical release of soft-tissue contractures, avoiding negative AI, femoral shortening and avoidance of cast immobilization with the hip in an extreme position are believed to reduce the incidence of AVN effectively.
Ali Aydin, in 2012, reported results of OR and PPO in 91 hips with a mean age of 34 months. In their series, type-1 AVN was seen in 9.9%, type-2 in 7.7% and type-3 in 1.1% and one had type-4 AVN. They observed that complication rate increased in patients with Tonnis type-4 hip dislocation, in patients over 3 years and in cases where a second surgery was necessary (42). Wada et al. reported excellent and good results with PPO in 82.3% of 17 hips, all over 7 years of age (43). Wang et al. compared radiographic results of SIO and PPO at >10-year follow-up and found that patients with PPO had improved anterior acetabular coverage. The functional outcomes were good and equivalent with both osteotomies (44).
Dega osteotomy (lateral acetabuloplasty)
Wiktor Dega briefly described a transiliac osteotomy in 1964 in German literature, followed by a detailed description of his technique in 1974 in Polish (45, 46). In his initial report, Dega described the supra-acetabular semicircular osteotomy as a true lateral bending acetabuloplasty in which the inner table of the ilium was completely intact. However, in the later publication in 1974, he modified the technique in which the inner table of the ilium was cut in the anterior two-thirds. The first detailed description of the technique in English literature was published in 2001 by Grudzaik et al. (47).
The osteotomy begins anteriorly on the interspinous ridge between the ASIS and AIIS. The orientation of the osteotomy is curvilinear when viewed from the lateral cortex, starting just above the AIIS, curving gently cephalad and posteriorly (curves at the midpoint of the acetabulum) to end approximately 1–1.5 cm in front of the sciatic notch. The osteotomy is bicortical anteriorly, and a variable amount of posteromedial cortex of the inner table of the pelvis in front of the sciatic notch is left intact. A lamina spreader is used to open the osteotomy in a desirable direction. Bone graft is shaped according to the gap at the osteotomy site, and a larger graft is placed anteriorly than posteriorly to get more anterior coverage (Figs 3 and 5 ). Theoretically, it is possible to change the graft size and placement, the extent of inner iliac cortical cut and the size of acetabular fragment based on whether the patient has an anterior or lateral deficiency, thus making it a versatile osteotomy that can both reorient and reshape the acetabulum.
Czubak et al. in 2018 reported the outcomes of OR, femur osteotomy and Dega osteotomy in 52 hips with a mean age of 3.9 years (1.2–12.8). The AI was corrected to normal in all hips. AVN was seen in 5.8% of hips and coxa magna in one hip (48). Karlen et al. in 2009 reported results of Dega osteotomy in 26 hips, with an overall complication rate of 19% and AVN in 7.6% hips. The incidence of reoperation rate in their series was 3.8% (49). Ming-Hua et al. in 2016 reported the outcomes of modified high-level Dega osteotomy in 162 patients, between 1.5 and 6 years of age. They reported a favorable and good outcome in >90% of hips where the mean AI changed from 38.0° to 20.8° and the mean CE angle increased from −10.7° to 29.4° after the intervention (50).
Modified San Diego acetabuloplasty
Mubarak et al. modified Dega’s osteotomy to improve the lateral and posterior coverage of the acetabulum (51). This modified Dega osteotomy, known as San Diego acetabuloplasty, was designed initially for hip dysplasia secondary to neuromuscular disease, where the deficiency is predominantly posterosuperior or direct lateral compared to the anterolateral deficiency seen in DDH (11). Later, it was expanded to treat idiopathic DDH with anterior and anterolateral deficiency (52).
The main difference between the Dega acetabuloplasty and the San Diego acetabuloplasty is that in the latter the inner cortex of the ilium is completely intact except anteriorly and posteriorly, where it is bicortical at the AIIS and sciatic notch respectively. The acetabulum is hinged on the anterior and posterior limbs of the TRC, and bone grafts are utilized to wedge the osteotomy open (Figs 3 and 6 ). The unicortical osteotomy allows the surgeon to alter the shape of the acetabulum specifically to address the deficiency simply by changing the size and placement of the bone grafts. Three unequal-sized triangular bone wedges are used, and when the largest graft is placed anteriorly, it increases the anterolateral coverage (52). Placing the largest graft posteriorly increases the posterior coverage.
Badrinath et al. in 2019 compared the results of PPO with modified San Diego in DDH and showed comparable clinical and radiographic outcomes. The proposed advantage is that the acetabular reshaping can be customized to address a specific acetabular deficiency (52).
Which pelvic osteotomy to choose for a patient?
The choice of PO depends on the morphological abnormality in the acetabulum and the magnitude of correction needed to normalize it. We can broadly categorize acetabular dysplasia’s into two different types as follows:
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Primary dysplasia– acetabular deficiency in an untreated DDH
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Residual dysplasia – the dysplasia in a treated DDH (both closed and open reduction)
In general, the amount of correction needed is less in residual dysplasia compared to primary dysplasia. The other factor which influences the magnitude of correction required is the age at which the patient presents. We can divide this into four different age groups: (1) <4 years, (2) 4–8 years, (3) >8 years (up to TRC closure) and (4) young adults (after skeletal maturity). As the age advances, reshaping acetabuloplasties hinging through the cartilage becomes challenging and getting a massive correction may not be possible. The authors’ preferred approach to choose a PO is shown in the algorithm (Fig. 7).
Acetabular dysplasia in <4 years
In children less than 4 years with primary dysplasia, the type of PO is decided based on the acetabular shape and location of deficiency. In this age group, the AI measured on the X-ray may not be accurate as part of the acetabular cartilage is unossified. The authors prefer to measure the cartilaginous AI with intra-operative arthrogram (Fig. 8). The shape of the normal acetabulum is hemispherical, and the anterior wall is about half of the posterior wall. In untreated dysplasia, weight-bearing and walking gradually lead to a change in the shape of the acetabulum from hemispherical to ellipsoidal. If the acetabulum is spherical and there is an anterior or anterolateral deficiency, an SIO is indicated. A Pemberton or Dega type of acetabuloplasty in this scenario can lead to inferior subluxation of the head. If the acetabulum is shallow and ellipsoidal, any kind of reshaping acetabuloplasty (Pemberton, Dega, San Diego) may be performed.
In those children with residual dysplasia in this group (typically seen during follow-up visits after closed/open reduction), the acetabulum is invariably shallow and ellipsoidal, and a reshaping acetabuloplasty is indicated.
Acetabular dysplasia in 4–8 years
Residual dysplasia in this age group is often mild as the hip is enlocated and can be tackled with reshaping acetabuloplasty procedures.
Primary dysplasia in this age group could be challenging as often the degree of dysplasia is severe. The classical San Diego type of acetabuloplasty may not be adequate as it is unicortical, limiting the amount of correction one could achieve. Similarly, the classical Dega type osteotomy is also limited by the intact posterior part of the ilium.
The PPO, which is bicortical and extends up to the TRC, could provide enough correction for severe dysplasia, especially when the deficiency is anterolateral. However, the amount of lateral coverage that one could achieve is limited with PPO. Thus, in cases with severe lateral uncoverage, a re-directional osteotomy like TPO is the preferred choice by the authors (Fig. 9). There are a few reports of the use of SIO in this age group as well.
Acetabular dysplasia >8 years
Mild residual dysplasias in this age group are amenable for correction with Pemberton or Dega type osteotomy. The severe residual dysplasias and all primary dysplasias will need a re-directional osteotomy, and TPO is the preferred choice. Theoretically, an SIO can be done in this age group and the authors do not have any personal experience with this.
Acetabular dysplasia in young adults (after skeletal maturity)
Irrespective of the type of dysplasia, in this age group, the preferred PO is the Bernese PAO which is a powerful tool to correct even severe dysplasias (Fig. 10). However, the PAO is technically challenging, requires specialized osteotomes and instruments, and hence a TPO is a worthy alternative in this age group which equally gives good correction.
Conclusion
PO is an essential part of the surgical management of hip dysplasia, and the literature is loaded with various types with modifications. A thorough understanding of the principles of pelvic osteotomies is essential to choose the right intervention for the right patient. The guidelines provided based on the type of dysplasia, the age of the patient and the status of the tri-radiate cartilage help in choosing the right type of PO. With the advent of the 3D technology in the field of orthopedics, in future, 3D planning and printing may be of immense use in planning and executing these complex osteotomies.
ICMJE Conflict of Interest Statement
The authors declare that there is no have conflict of interest that could be perceived as prejudicing the impartiality of this study.
Funding Statement
This work did not receive any specific grant from any funding agency in the public, commercial, or not-for-profit sector.
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