Abstract
Diagnosis and treatment of intra‐articular hip problems in young patients present a challenge to hip surgeons. Previous studies have shown that non‐invasive investigations such as radiography, computed tomography and magnetic resonance imaging provide limited help. Non‐operative treatment is likely to result in persistent symptoms, and surgical options for intra‐articular hip problems involve open arthrotomy of the hip joint, which carries potential risks associated with joint dislocation. Arthroscopy of the hip joint, therefore, seems to be an attractive option. It was once thought that introduction of a straight arthroscope into the ball‐and‐socket hip joint was almost impossible. Hip arthroscopy has seen several advances since then, and the speed at which it developed in recent years directly corresponded to the rate at which the conditions affecting the hip joint were identified. Athletes and other young individuals with hip injuries are increasingly being diagnosed with an ever evolving series of conditions. Many of these conditions were previously unrecognised and thus left untreated, resulting in premature ends to the patients' competitive careers. Hip arthroscopy, as with any procedure, is not without risks. The procedure is not widely available as it requires specialist equipment and takes a long time to learn. Complications are few, occurring in <5% of patients.
Diagnosis and treatment of intra‐articular hip problems in young patients present a challenge. Historically, there have been limited diagnostic and treatment options available for diseases that affect the cartilage, bone or synovium in the young hip joint. Provocative manoeuvres to diagnose a hip problem are unreliable owing to extreme apprehension, and non‐invasive investigations provide limited help with the diagnosis of these conditions. Radiographs have traditionally been poor at detecting early lesions in the hip. Other imaging studies have not been very reliable either, as a negative imaging study does not exclude important intra‐articular pathologies.1 Although gadolinium‐enhanced magnetic resonance imaging (MRI) is much more sensitive than conventional MRI for detecting intra‐articular lesions,2 limitations do exist with these investigations, as previous studies have shown.3,4 Diagnostic hip blocks are useful to distinguish between intra‐articular and extra‐articular lesions,5 but they provide information on the generality of intra‐articular problems rather than specific lesions within the ball‐and‐socket joint.
Although open surgeries of the hip joint are performed more routinely and successfully, they are not without potential risks associated with joint dislocation, infection, deep vein thrombosis, avascular necrosis, major nerve or vessel injury, heterotopic bone and muscle weakness.6,7,8 Non‐operative treatment is likely to result in persistent symptoms. Keyhole surgery of the hip joint, therefore, seems to be an attractive option.
It was once thought that the introduction of an arthroscope into a hip joint was almost impossible. In 1931, Burman9 stated that “It is manifestly impossible to insert a needle between the head of the femur and the acetabulum”. Hip arthroscopy has seen several advances since then. The speed at which it developed in recent years directly corresponded to the rate at which the conditions affecting the hip joint were identified. The advent of hip arthroscopy has facilitated comprehensive access to an evolving series of conditions that affect the hip joint, many of which were previously unrecognised and thus left untreated.10 Today, arthroscopy of the hip joint has led to a greater understanding of the nature of adolescent and adult hip pathologies of acetabular labrum, acetabular chondral surfaces, fovea, ligamentum teres, femoral head and adjacent synovium,5 and their management, particularly in hip injuries in athletes.
Having been used minimally in the 1980s, hip arthroscopy has a recent history. Our understanding of arthroscopic anatomy, indications, potential complications and techniques has evolved in recent years, and hip arthroscopy has become a successful treatment method for a variety of hip pathologies in selected patients. It is hoped that this article will shed light on the most recent concepts and developments in this ever evolving technique.
Technique
Preoperative planning is important for hip arthroscopy. The range of movement of the hip must be assessed to determine the presence of fixed deformities. Radiographs should be completed to identify spurs or dysplasia. Entry into the joint may become difficult if there are large spurs, and dysplastic hips have been shown to have poorer outcomes.
In our institution, hip arthroscopy is performed in the lateral position with the patient under general anaesthesia, under image intensifier control and traction (fig1). In some centres, the procedure is performed with the patient in the supine position.11 We believe that the lateral position provides enhanced instrument manoeuvrability, easier entry into the hip joint and particularly helps in obese patients, as fatty tissue tends to fall out of the way. The traction apparatus includes a foot piece and a stretcher to hold the leg, a well‐padded perineal post for counter traction, and a tensiometer to gauge the amount of traction applied (fig 1).
Figure 1 Lateral position for right hip arthroscopy.
The lower limb is placed in slight flexion (approximately 10–20°), with the foot maintained in neutral to slight external rotation. The perineal post is pushed upwards against the medial portion of the thigh on the involved leg, keeping the post away from the branch of the pudendal nerve that crosses over the pubic ramus. Distraction is achieved carefully until the “vacuum phenomenon” is seen on the image intensifier, as described by Byrd.11 Usually, three portals are used: anterolateral, proximal trochanteric and posterolateral, although sometimes more portals may be required. One needs to be extremely careful of the lateral cutaneous nerve when establishing the anterolateral portal and of the posterior neurovascular bundle when establishing the posterolateral portal. Specially designed extra‐long arthroscopic instruments, which include a long spinal needle (Howard Jones spinal needle with Pitkin point, Luer lock fitting, 15 g and 155 mm in length, Smith and Nephew, Massachusetts, USA) and a specially designed flexible guide wire to reach the depth of the hip joint, are used. Special attention must be taken to avoid penetration of the acetabular labrum. As the needle penetrates through the capsule, there is a palpable decrease in resistance. If the needle is directed into the labrum, the resistance is greater. The joint is then distended with approximately 40 cm3 of saline, and the intracapsular position of the needle confirmed by backflow of fluid. A guide wire is fed through the spinal needle into the joint space, and the spinal needle is removed. After the guide wire is positioned in the joint, a sharp cannulated trocar is used to penetrate only the joint capsule, followed by a blunt cannulated trocar, to avoid damage to the articular cartilage.
Understanding the arthroscopic anatomy of the hip joint is essential before embarking on hip arthroscopy. During the procedure, the hip joint is systematically inspected so as to view every possible part and detect any abnormalities. An arthroscopic pump is used throughout to maintain constant distension of the joint with saline solution. A 70° arthroscope is used most commonly for hip arthroscopy, although a 30° arthroscope is also useful. Most hip arthroscopy procedures require the use of multiple portals for the proper positioning of hand instruments, power shavers and electrocautery devices. At the end of the procedure, traction is removed carefully under the direct supervision of the operating surgeon. The average imaging time in our institution is 10 s and the procedure takes roughly 40 min.
Findings at hip arthroscopy
Acetabular labral injuries
Previous reports have suggested that injuries of the acetabular labrum (fig 2) are mostly due to degenerative change in the hip (50%) or trauma (20%).12,13,14,15 When the damaged labral cartilage is subjected to repetitive loading conditions, joint fluid is pumped beneath the acetabular chondral cartilage, causing delamination (fig 3) of the articular cartilage.15 As a result, the fluid eventually burrows beneath the subchondral bone to form a subchondral cyst.15 Traumatic acetabular labral injuries commonly occur in the presence of abnormal proximal femoral or acetabular anatomy,16 or during abnormal loading, as may be seen in the hips of professional sportsmen.17,18 Studies have shown that most labral injuries occur at the anterior marginal attachment of the acetabulum,18,19 although injury to the posterosuperior aspect of the labrum has been reported in an adolescent Asian population by Ikeda et al.20 Often, injuries of the acetabular labrum are associated with congenital or structural abnormalities such as acetabular dysplasia, slipped upper femoral epiphysis or Perthes' disease.21 Studies have also shown that labral tears are linked to the onset of hip impingement, now termed “femoroacetabular impingement” (FAI).15,22,23,24
Figure 2 A peripheral tear of the acetabular labrum. AL, acetabular labrum; AS, acetabular surface; FH, femoral head.
Figure 3 Clear delamination of the acetabular articular cartilage from the subchondral bone. AL, acetabular labrum; AS, acetabular surface (delaminated); FH, femoral head.
Femoroacetabular impingement
A difficult entity to diagnose and treat, hip impingement usually appears in younger and more physically active adults and can be physically debilitating. Ganz et al22 described two distinctive types of FAI. “Pincer impingement” occurs as a result of anterior overcoverage of the acetabulum or acetabular retroversion, and “cam impingement” occurs when a non‐spherical femoral head abuts against the anterior acetabulum, usually with the hip in flexion. A non‐spherical femoral head is known to occur because of structural proximal femoral head–neck offset abnormalities, usually described as “pistol grip deformity”(fig 4) of the femoral neck,25 attributed to mild or subclinical slipped upper femoral epiphysis.26 Several other morphological deviations in the hip can also lead to FAI, as described by Ito et al.27 FAI results in repetitive microtrauma to the acetabular labrum at the extremes of motion of the hip, leading to labral and chondral lesions, known to have a role in the cascade of hip osteoarthritis.27 Arthroscopic assessment and removal of the impingement lesion, either by partial labrectomy or by debridement of non‐spherical femoral heads with decreased head–neck offset causing impingement, restores hip mechanics at the extremes of motion.28 This results in elimination of the microtrauma to the anterior acetabular margin and, thus, potentially slows down the progression of osteoarthritis in young individuals.29
Figure 4 Plain x ray of pelvis showing “pistol grip deformity” of both proximal femora. If the x ray is shown upside down, the proximal femora appear like pistol grips.
Chondral lesions
The earliest chondral lesion detectable at hip arthroscopy is chondral split, progressing onwards to a more formal delamination, chondral flap lesion and subchondral cyst.15 The diagnosis of these chondral lesions (fig 5) is extremely difficult with the available non‐invasive techniques. Chondral flaps and osteochondral defects may occur in association with a multitude of hip conditions. The anterior aspect of the acetabulum is a commonly involved site, as shown by McCarthy and Lee5 in 2001. They found that 259 of 477 (54%) chondral injuries had occurred in the anterior aspect of the acetabulum in their series.15 Early chondral splits are usually “glued” using a radiofrequency probe, whereas large, unstable flaps are excised and the underlyingsubchondral bone microfractured. The outcome of treatment for these lesions depends mainly on how soon the diagnosis is made and the extent of damage.
Figure 5 Chondral flap lesion in the femoral head. CF, chondral flap; FH, femoral head.
Less common findings in hip arthroscopy
Other less common pathological conditions diagnosed at hip arthroscopy include avascular necrosis, loose bodies, lesions of the synovium, abnormalities in the cotyloid fossa (fig 6) and torn ligamentum teres. The role of arthroscopy in avascular necrosis is largely diagnostic. Hip arthroscopy helps to stage the disease30 and detect osteochondral degeneration, which cannot be identified by plain radiographs and MRI, particularly in post‐collapse femoral heads.31 Occasionally, arthroscopy may help to relieve mechanical symptoms in avascular necrosis.5,32 Synovial chondromatosis (fig 7) produces loose bodies in the hip, and hip arthroscopy helps to remove these loose bodies less invasively,33 although a recurrence rate of 10% has been reported in patients with synovial chondromatosis treated with hip arthroscopy.5 Lesions of the ligamentum teres, as a source of hip pain, either alone or in conjunction with other articular lesions, have been described by Gray and Villar34 and recently, by Byrd and Jones.35 These lesions are thought to be associated with trauma, dysplasia or degenerative arthritis.
Figure 6 Lipoma (L) in the cotyloid fossa. It is difficult to pick up these abnormalities by conventional investigations. AS, acetabular surface; FH, femoral head.
Figure 7 Synovial chondromatosis of the hip with numerous loose bodies. AS, acetabular surface; FH, femoral head.
What is already known on this topic
It was once thought that hip arthroscopy was almost impossible to perform.
The late 1990s and early 2000s saw an increasing number of procedures being performed worldwide.
This has led to the recognition of a number of conditions that were previously undiagnosed and, therefore, left untreated.
The speed at which hip arthroscopy developed in the recent years directly corresponded to the rate at which the conditions affecting the hip joint were identified.
Indications for hip arthroscopy
The difficulty in diagnosing all the above lesions with conventional methods and in determining their effect on outcome provides a substantial rationale for hip arthroscopy.5 Current indications for hip arthroscopy include the presence of symptomatic acetabular labral tears, femoroacetabular impingement, chondral lesions, osteochondritis dissecans, ligamentum teres injuries, snapping hip syndrome, iliopsoas bursitis and loose bodies. Less common indications include management of osteonecrosis of the femoral head, synovial abnormalities, crystalline hip arthropathy (gout and pseudogout), infection and post‐traumatic intra‐articular debris. In rare cases, hip arthroscopy can be used to temporise the symptoms of mild‐to‐moderate hip osteoarthritis with associated mechanical symptoms.10 Patient selection is an important issue for a potentially successful outcome. General parameters include younger patients, mechanical joint symptoms, partial joint space preservation, adequate rotational motion, failure of conservative treatment, and reasonable expectations from the patient.36 Arthroscopic evaluation may also be considered when joint symptoms are unremitting, and no diagnosis has been made. If the symptoms have been present for >6 months, one can expect an arthroscopy‐facilitated diagnosis in approximately 40% of these patients.37
Conditions that limit the potential for hip distraction may preclude arthroscopy. These include joint ankylosis, dense heterotopic bone formation, considerable protrusion and morbid obesity, not only because of distraction limitations but also because of the requisite length of instruments necessary to access and manoeuvre within the deeply receded joint. In addition, sepsis with accompanying osteomyelitis or abscess formation requires open surgery.
Problems with hip arthroscopy
Hip arthroscopy is technically demanding owing to both anatomical and technical constraints, and involves a steep learning curve.5 The hip joint is deeply recessed in a soft‐tissue envelope and the femoral head is contained in a concavely shaped acetabulum.38 The joint capsule, especially the iliofemoral ligament, is thick and resists traction for joint distraction. Sufficient joint distraction is paramount, and Byrd et al39 described a vacuum phenomenon that occurs after the initial application of traction. The magnitude of the force required to provide sufficient distraction has been reported to be between 300 and 900 N in an anaesthetised patient.40 Guhl et al41 and Glick et al42 suggested that a longitudinal force of at least 20 kg may be required to obtain a good view of the joint. With increased traction, neurovascular structures are susceptible to injury leading to complications.43
What this study adds
Hip arthroscopy is not just about diagnosis.
Recent advances in the techniques of hip arthroscopy have allowed surgeons to treat conditions such as femoroacetabular impingement with minimal access to the joint.
Athletes and other young individuals with hip injuries are increasingly being diagnosed with an ever evolving series of conditions. Many of these conditions were previously unrecognised, resulting in premature ends to the patients' competitive careers.
With current technical advancement, it remains to be seen whether we can change the natural history of the disease process and potentially curb the progression of osteoarthritis.
Complications occur in 0.5–5% of patients and are most often related to transient neuropraxia due to distraction of the joint.44,45,46 Injuries to the sciatic nerve (posterior portal), lateral femoral cutaneous nerve (anterolateral portal) and pudendal nerves have been reported in the literature.42,47,48 However, the effects of traction on the integrity of the joint capsule, the ligamentum teres and the acetabular labrum remain unknown. Some authors argue that the labrum may be vulnerable to relatively minor trauma by traction,47,49 but a study by Elsaidi et al50 did not show any injury to the acetabular labrum from longitudinal distraction of the hip on the fracture table.
Conclusions
Historically, athletes and other young individuals with hip injuries were simply resigned to living within the constraints of their symptoms, being diagnosed with an ill‐defined chronic groin injury and often prematurely ending their competitive careers.51 Advances in hip arthroscopic techniques have helped us to understand various forms of intra‐articular hip pathologies and to define elusive causes of disabling hip pain in athletic population, including occult labral and chondral damage and rupture of ligamentum teres. Acetabular labral tears can contribute to persistent symptoms in the hip joint, and lesions of the articular cartilage of the femoral head and acetabulum can eventually contribute to the progression of hip osteoarthritis. We are now capable of recognising these at an early stage in the disease. However, with current technical advancement, it remains to be seen whether we can change the natural history of the disease process and potentially curb the progression of osteoarthritis.
Acknowledgement
We thank Mr Vikas Khanduja from Cambridge Hip and Knee Unit for helping with fig 1.
Abbreviations
FAI - femoroacetabular impingement
MRI - magnetic resonance imaging
Footnotes
Competing interests: None declared.
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