The aim of treatment of AVN of the hip is to prevent collapse of the FH and may vary depending on the underlying etiology and stage of progression. Treatment options include pharmacologic agents, biophysical treatments, as well as joint-preserving and joint-replacing surgeries. Medical management of AVN has been increasingly used in early stages in attempt to delay the progression of the disease.

Pharmacological management of AVN includes lipid lowering agents, anticoagulants, vasoactive substances, and bisphosphonates. Increases in both the number and size of circulating fat cells have been associated with the development of ON of the hip, therefore lipid lowering agents, such as statins, which reduce the rate of adipogenesis, are beneficial. Statins have been shown to provide protective effects for patients receiving steroids. It is still unclear whether statins have the ability to reverse steroid-induced ON once it has already occurred[31,32]. Anticoagulants such as enoxaparin act through the inhibition of platelets aggregation thereby increasing blood flow to ischemic areas of the bone. These agents are primarily beneficial in patients with underlying coagulopathy disorders, such as thrombophilia or hypofrinolysis[9,33]. Prostacyclin is a vasoactive agent that improves blood flow through its vasodilator effects in the terminal vessels. Although prostacyclin has shown significant improvement in both clinical and radiologic outcomes in early stages of AVN, long term benefits have yet to be established[34].

Bisphosphonates significantly reduce the incidence of collapse of the FH in osteonecrotic hips by reducing osteoclast activity. Alendronate has been shown to prevent early collapse of the FH in Steinberg stages II and III non-traumatic ON at 24-28 mo follow up and has been reported to diminish the amount of pain at one year follow up when it is compared with placebo treatment[35,36]. Alendronate has been used as an adjunctive therapy with surgical procedures and has been found to reduce pain and the risk of collapse in early stages of ONFH[37]. Evidence for prevention of THR and reduction of AVN progression still remains controversial[38].

Biophysical treatments include extracorporeal shockwave therapy (ESWT), pulse electromagnetic therapy, and hyperbaric oxygen (HBO) therapy. ESWT has been shown to restore tissue oxygenation, reduce edema, and induce angiogenesis and may offer an alternative to the invasive modalities for FH necrosis in the earlier stages[39,40]. ESWT has also been associated with improvement in both pain and function, and has been found to result in a reduction of lesion size and bone marrow edema at 1-year follow up. Long term (8-9 years) improvement in pain and Harris Hip scores has also been demonstrated in the ESWT group treatment when compared with the core decompression group treatment[41]. Although not as commonly used, pulse electromagnetic therapy is believed to function by stimulating osteogenesis and angiogenesis however its role as early stage ON treatment has not yet been established[42]. HBO increases extracellular oxygen concentration and reduces cellular ischemia and edema by inducing vasoconstriction[43]. Studies have reported radiographic improvement in Steinberg stage I-AVN, as well as pain and ROM improvement in Ficat stage-II ON[39,44].

Conservative treatment of AVN may be effective in the earlier stages of the disease. Although medical management may improve pain and functional outcomes, randomized clinical trials are necessary with long term follow up to determine effectiveness of therapy.

Currently there is no consensus regarding the treatment of the different stages of ONFH in the adult population[7,10,45,46]. A recent survey of 753 members of the American Association of Hip and Knee Surgeons reported that total hip replacement was the most common intervention for treatment of post-collapse stages of ONFH, whereas core decompression was the most common procedure for symptomatic pre-collapse stages of ONFH. Other less frequently performed treatments include conservative management, vascularized and non-vascularized bone grafts, hemi-arthroplasty, osteotomy, and arthrodesis[47]. ONFH tends to affect younger patients, therefore a variety of joint preserving surgical procedures have been developed to delay the progression of the disease and afford pain relief[5,21,48,49].

The surgical treatment of ONFH can be divided into two major branches: FH sparing procedures (FHSP) and FH replacement procedures (FHRP). In general, FHSP are indicated at pre-collapse stages with minimal symptoms whereas FHRP are preferred at post-collapse symptomatic stages.

FHSP: FHSP aim to preserve the FH and include core decompression (CD), CD combined with different grafting procedures and/or biologic agents and rotational osteotomies. Since all these procedures cannot restore the sphericity of the FH their role in the management of post-collapse stages is very limited[50,51].

CD: CD of the FH is the most common procedure currently performed to treat early stages of ONFH with the goal of decompressing the FH pressure in order to restore normal vascular flow and ultimately relieve pain[5,52,53]. The technique of CD has varied in terms of surgical approaches, number of drillings, and trephine diameter. Small diameter drilling has been proposed as an alternative because it has the advantage of reaching the anterior portion of the FH (most frequently involved region in ONFH) (Figure 5). In addition, small diameter drilling has been associated with minimal morbidity, less risk of weakening the FH and the articular cartilage, and less risk of stress risers that ultimately can lead to a subtrochanteric fracture[54]. Although CD has been shown to delay the progression of ON, its role in complete reconstruction of the necrotic area has not yet been established[55].

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Figure 5 Core decompression of the left femoral head. Preoperative magnetic resonance imaging, above (coronal and axial views) and fluoroscopic imaging during the procedure below.

Bone grafting procedures: Non-vascularized bone grafts from different sources (allograft, autograft or artificial) have been used to fill the necrotic area in the FH. The grafting can be performed through the core decompression tract, which is the most common technique, but also through a window in the FH or in the femoral neck[56]. This latter technique, also referred to as the trapdoor procedure, requires a surgical dislocation of the hip in order to graft the defect through a cartilage window in the FH.

Vascularized bone grafting combines the benefit of core decompression along with an osteoinductive and osteoconductive graft in the devitalized FH. This procedure was popularized in the 1970’s coincidently with the emergence of microsurgical techniques[51]. The variability among the surgical techniques to perform this procedure has however confounded the uniformity of the published data.

The free vascularized fibular grafting (FVFG) has been shown to support the subchondral architecture as well as restore local circulation to the necrotic FH in treatment of ONFH. A study on 470 patients with a mean follow-up of 5.0 years showed an average Harris hip score improvement from 65.0 to 86.9, no radiographic changes in 57.3% of patients, improvement in 33.7% of patients, and necrosis progression in 9.0% of patients respectively. These results show that the modified technique of the use of FVFG for treatment of ONFH yields similar postoperative results in comparison to the traditional method. Although vascularized fibular grafting has shown promising results, especially in young patients with ONFH, the extensive surgical time, donor-site morbidity, prolonged rehabilitation, and an increased risk of a proximal femoral fracture has limited its use in practice[57-59].

Tantalum implants: Porous tantalum implants in combination with core decompression offers the advantage of providing structural support without the risk of autograft harvest or the infectious complications of bone allograft[60-62]. Veillete et al[62] reported an overall survival rate of 91.8% at twenty-four months, and 68.1% at forty-eight months after evaluating fifty-four patients with ONFH treated with core decompression and the insertion of a porous tantalum rod. Although these results appear promising, there are concerns about the origination of metal debris in the joint if a THR becomes necessary as well as a more complicated surgical technique. In addition, previous histologic studies demonstrated little bone ingrowth and insufficient mechanical support of the subchondral bone at the time of conversion from a tantalum rod to THR[63]. Long-term follow up is necessary in order to assess the functional and clinical outcomes of this technique.

Biological agents: There is considerable enthusiasm in the development of biological therapies that can enhance core decompression with osteogenic (mesenchymal stem cells) and/or osteoinductive agents (bone morphogenic protein) that have the potential to produce better results for larger lesions.

It has been hypothesized that there is an insufficient supply of progenitor cells in patients with AVN, which are required to enhance remodeling in areas of ON[64]. For this reason, newer treatment modalities have been developed to introduce stem cells to the areas of necrosis in order to prevent fracture and collapse of the FH. Since 2002, when Hernigou et al[65] first described a technique for injecting mesenchymal stem cells into an area of necrosis, four studies have prospectively evaluated the use of stem cells and core decompression. These studies presented consistent findings showing that patients treated with core decompression and stem cells achieved a significantly higher Harris Hip Score at final follow up. Gangji et al[66] reported in 2004 the results of a controlled, double blind study comparing core decompression with and without bone marrow aspirate. After 24 mo follow up the survival analysis revealed a significant difference in the time to collapse between both groups and a decreased of 35% of the necrotic lesion in the bone marrow graft group.

The instillation of stem cells into the osteonecrotic region of the FH can be performed through various methods. These include the direct instillation through the core tract, a selective femoral arterial perfusion, or the catheterization of the medial, lateral, or obturator artery. The direct instillation through the core tract is the most commonly performed procedure, however the catheterization of these vessels makes it difficult thereby requiring higher technical skills. However, it is important to maintain the final concentrate of cells when doing a direct instillation in order to effectively regenerate the osteonecrotic region (optimum effective dosage minimum necessary concentration 5 × 107 and CD 34 + 5 × 107 cells)[45,67]. This is another factor that has been shown to influence healing of necrotic areas in the FH[64,65]. Additionally, the relationship between the injected volume and the lesion volume needs to be studied. Although these previous studies confirm that bone marrow aspirate concentrate has the potential to induce bone repair in ONFH, the data is preliminary and many questions still need to be addressed[45,64-67].

Osteotomies: Two general types of osteotomies, angular intertrochanteric and rotational transtrochanteric, can be performed to remove the segment of necrotic bone away from the weight-bearing region in the hip[68-72].

The transtrochanteric rotational osteotomy (TRO) for treatment of ONFH was introduced by Sugioka[71] in 1972. The aim of this procedure is to rotate the necrotic region of the FH out of the weight bearing area of the acetabulum. Sugiota[71] reported promising clinical results with a success rate of 78% after 3-16 years. However, their results with this technically demanding procedure have not been reproduced[68-70]. Rotational osteotomies can provide a painless, mobile, and stable hip if there is an unloading of the necrotic area of the FH when it is rotated from the acetabular major bearing surface and if the depth of the necrosis is not bigger than one third of the head diameter[71]. Hisatome et al[72] reviewed 25 hips in 21 patients six years after Sugioka’s transtrochanteric anterior rotational osteotomy for ONFH. They concluded that although the collapse of a new weight-bearing region can be prevented, the progressive collapse of the transposed necrotic area induces anterior joint instability and subsequent arthritic changes.

Despite the promising results, patients who ultimately require conversion to THA after a proximal femoral osteotomy have a 17% intraoperative complication rate and an 82% survival rate of the implant after 10 years. Osteotomies are a reasonable option when they are performed by experienced surgeons in patients younger than 45 years with a Kerboull angle below 200° and no longer taking steroids.

Although FHSP may provide good clinical results in patients with small pre-collapse lesions, these interventions are less predictable in patients with larger lesions or in FH collapse. These patients are therefore better candidates for FHRP.

Hemi-resurfacing arthroplasty and hemipolar/bipolar hip replacement: Hemi-resurfacing arthroplasty is a significant treatment option when the joint surface is still preserved and the articular cartilage is minimally damaged. Possible indications include a Ficat III, early stage Ficat IV, or early failure of a free vascularized fibula graft. With good patient selection and surgical technique this procedure can restore patient function although pain relief may not be as predictable as after THR[73]. Hemi-resurfacing arthroplasty causes little distortion of the anatomy, preserves bone, and produces minimal particle debris. Accurate evaluation of the acetabular articular cartilage and its longevity with this component poses a difficult challenge.

Hemi-arthroplasty replacements are an alternative treatment strategy as they preserve the acetabular bone stock. The major concerns with this procedure are the incidence of protrusion and polyethylene wear that can lead to particle-induced osteolysis and femoral stem loosening[74,75]. Nevertheless, either hemi-resurfacing arthroplasty or proximal femoral osteotomies are preferred to hemi-arthroplasty.

THA: Arthroplasty is typically reserved for patients with late-stage ONFH, as well as older patients and those with more advanced arthritis (Figures 6 and 7)[47]. Arthroplasty is the only treatment that has been proven to reduce pain and restore mobility. In the United States, it is estimated that approximately 10% of all THRs are done in symptomatic hip ON[6,49].

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Figure 6 Right femoral head osteonecrosis. Flattening of femoral head progression in 24 mo ending up in a right total hip replacement.

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Figure 7 Bilateral total hip replacement in a patient with bilateral hip osteonecrosis of the femoral head.

There have been several studies which have shown poor results of THR for ONFH with failure rates between 37% and 53%, but more recent long term follow up studies have reported improved results compared with earlier reports[76-78]. The advances in the past two decades with the advent of surface bearings with low wear rates present promising results when used in patients with an advance stage of necrosis at mid-term follow up[79-81].

Kim et al[82] recently reported a 98% stem survivorship and an 85% cementless cup survivorship at 17.3 years of mean follow up. The most common reason for revision was due to cup wear or loosening. Although longer-term follow up studies are needed, promising stem and cup survivorship seems to be feasible.

Overall patients with ONFH present similar failure rates after THA than the general population. However a few ON risk factors, as renal failure and/or transplant and sickle cell disease, have been associated with worse outcomes[81]. Fortunately these risk factors are present in a small population of patients with ONFH and even in this high-risk group population the outcomes of THR have improved over time[83-85]. Many studies have also shown that the outcomes of primary THR are not affected by previous hip joint preserving procedures[86-91]. However, THAs performed after rotational or angular osteotomies have shown higher complication rates when compared to those who did not have a previous osteotomy because of the disturbed anatomy of the proximal femur after the TRO[86,92-94].