Abstract
Femoroacetabular impingement (FAI) causes pain and chondrolabral damage via mechanical overload during movement of the hip. It is caused by many different types of pathoanatomy, including the cam ‘bump’, decreased head–neck offset, acetabular retroversion, global acetabular overcoverage, prominent anterior–inferior iliac spine, slipped capital femoral epiphysis, and the sequelae of childhood Perthes’ disease.
Both evolutionary and developmental factors may cause FAI. Prevalence studies show that anatomic variations that cause FAI are common in the asymptomatic population. Young athletes may be predisposed to FAI because of the stress on the physis during development. Other factors, including the soft tissues, may also influence symptoms and chondrolabral damage.
FAI and the resultant chondrolabral pathology are often treated arthroscopically. Although the results are favourable, morphologies can be complex, patient expectations are high and the surgery is challenging. The long-term outcomes of hip arthroscopy are still forthcoming and it is unknown if treatment of FAI will prevent arthrosis.
Femoroacetabular impingement (FAI) and the general area of hip preservation surgery are currently two of the hottest topics in orthopaedics. The idea that bone-on-bone contact during movement of the hip, or ‘impingement’, causes pain, restricted range of movement, and degeneration of the joint was anecdotally mentioned before Reinhold Ganz’s work describing FAI in 2003.1 In 1936 Smith-Petersen2 described acetabular rim trimming and femoral neck osteoplasty for impingement of the acetabular rim on the femoral head or neck for cases of protrusio, healed slipped capital femoral epiphysis (SCFE) and osteoarthritis. Other authors recognised that impingement could occur secondary to healed SCFE and advocated osteoplasty of the femoral neck to alleviate pain and improve range of movement.3 However, it was Ganz et al4 in 1991 who began to resurrect these ideas, describing FAI occurring secondary to other hip pathology. In the decade that followed, the Bern group described impingement from callus formation or malunion after femoral neck fractures,4,5 impingement following periacetabular osteotomy6-10 and FAI as a cause of chondrolysis after healed SCFE.11,12 The description of a safe technique for surgical dislocation of the hip13 and MRI studies describing the alpha angle and decreased head-neck offset as potential causes of idiopathic impingement14,15 were also published prior to 2003, laying the foundation for this concept and its treatment.
The article published by Ganz et al1 in 2003 is widely cited by other authors as the introduction of the concept of FAI, and is now nearly ten years old. This article was the first conceptual description of FAI, and the first to propose FAI as a primary cause of idiopathic hip arthrosis. These ideas were substantiated by clinical and intra-operative observations made in a series of over 200 patients who underwent surgical hip dislocation for impingement.1 Although the ideal reason to treat FAI is to prevent further chondrolabral damage and future osteoarthrosis, the more immediate goals of treatment are to relieve pain, improve range of movement and allow a return to previous activity.
When considering the mechanical causes of hip pain, it is important to recognise that chondrolabral damage and arthrosis can be caused by static overload, dynamic motion, or both. Static overload of the cartilage and labrum most commonly occurs in the setting of dysplasia,16-18 but more recently has also been proposed as a cause of pain for patients with valgus neck-shaft angles.19 Intra-articular damage occurring as a result of hip motion – dynamic mechanical arthrosis – can be due to impingement or from motion-induced instability, similar to that occuring when impingement on the acetabular rim induces levering of the femoral head.1,20-24
There are two distinct mechanical types of impingement.1 Cam impingement can also be described as an inclusion-type of injury,1,11,12 where a bony deformity at the femoral head–neck junction enters the joint when the hip flexes (Fig. 1).12,25-27 Pincer impingement can also be thought of as an impaction-type of injury1,11,12 and occurs as a result of global or focal acetabular overcoverage, causing the acetabular rim to contact (or impact) the femoral head, metaphysis, or neck when the hip flexes (Fig. 2).25,28 Impaction injury can also occur in the setting of a relatively normal acetabulum with a very large femoral head offset deformity, or a broad or short femoral neck.11,12 Although this particular point is somewhat controversial, symptomatic patients most commonly have features of both cam/inclusion and pincer/impaction injury.29-33 Thinking about FAI in terms of mechanical forms of injury allows for the recognition that variations in anatomy can cause impingement, including the cam ‘bump’,1,14,15,31 lack of head-neck offset,14 increased acetabular depth or protrusio deformity,1,2,22 acetabular retroversion,1,34-38 and, at the extremes of this spectrum, slipped capital femoral epiphysis (SCFE)11,12 and the sequelae of childhood Perthes’ disease.39 This also explains why FAI can occur after a periacetabular osteotomy. Even if the acetabular correction is appropriate, the anterior femoral head in the dysplastic hip is characteristically flat,8,40 with a lack of head-neck offset that results in impingement when the acetabulum is rotated into a more normal position.8 Finally, there is also the most recently recognised cause of pincer/impaction-type impingement: that which occurs when a prominent anterior-inferior iliac spine (AIIS) or sub-spine region impinges on the femoral neck in hip flexion.28
Fig. 1
Cam impingement creates an inclusion-type of injury (a).25 A bony deformity at the femoral head-neck junction enters the acetabulum in hip flexion (curved arrow). This causes delamination of the cartilage and separation at the chondrolabral junction. Many different types of deformities can cause cam impingement, including a lack of femoral head-neck offset (b),26 a cam ‘bump’ (c),27 childhood Perthes’ disease (d) and both mild and remodelled slipped capital femoral epiphysis (SCFE) (e)12 (Reprinted with permission: a) Leunig et al. Femoroacetabular impingement: diagnosis and management, including open surgical technique. Oper Tech Sports Med 2007;15:178–188. b) Toogood et al. Proximal femoral anatomy in the normal human population. Clin Orthop Relat Res 2009;467:876–885. c) Siebenrock et al. Abnormal extension of the femoral head as a cause of cam impingement. Clin Orthop Relat Res 2004;418:54–60. e) Leunig et al. Slipped capital femoral epiphysis: early mechanical damage to the acetabular cartilage by a prominent femoral metaphysis. Acta Orthop Scand 2000;71:370–375).
Fig. 2
Pincer impingement causes an impaction injury (a).25 Global or focal acetabular overcoverage causes the rim to contact the femoral head, metaphysis or neck when the hip is flexed (curved arrow). Anatomical deformities that can produce impaction-type injury include acetabular retroversion (b), global acetabular overcoverage (c), a large or prominent subspine (d)28 or severe slipped capital femoral epiphysis (SCFE) (e). (Reprinted with permission: a) Leunig et al. Femoroacetabular impingement: diagnosis and management, including open surgical technique. Oper Tech Sports Med 2007;15:178–188. d) Larson et al. Making a case for anterior inferior iliac spine/subspine hip impingement: three representative case reports and proposed concept. Arthroscopy 2011;27:1732–1737. e) Leunig et al. Slipped capital femoral epiphysis: early mechanical damage to the acetabular cartilage by a prominent femoral metaphysis. Acta Orthop Scand 2000;71:370–375).
Pathoanatomy
Evolutionary factors
Anthropological studies of the proximal femur give some clues as to the aetiology of the anatomy that causes impingement. In mammals, there are two distinct types of development and resulting shape of the proximal femur. When the femoral capital epiphysis is completely separate from the trochanteric apophysis, the femoral head is rounder and the neck is longer (Fig. 3).41 This is thought to be the result of an evolutionary need for more range of movement at the hip, and is the typical developmental pattern in the human hip.41,42 More commonly, however, the two physes are coalesced, resulting in a hip with a shorter, stouter neck and a smaller range of movement (Fig. 3).41 This type of hip has been called coxa recta, and is seen most commonly in ‘runners’; quadripeds that require a stable hip without a large range of movement (such as horses).43 The counterpart to the coxa recta is the coxa rotunda, which is a hip with a round femoral head, relatively long femoral neck and higher head-neck offset circumferentially. This is seen in animals that are ‘climbers’ or ‘swimmers’; species that need a greater range of movement but bear less weight through the hip (such as chimpanzees or gorillas). After studying the spectrum of mammalian pelvis anatomy, Hogervorst et al43 proposed that evolutionary forces – specifically the increase in the size of the human brain and the biomechanics necessary for upright ambulation – are responsible for the pathoanatomy that results in symptomatic FAI.43 In order to accommodate the increased size of the human brain, ‘obstetric selection’ occurred, resulting in enlargement of the birth canal and anteroposterior deepening of the human female pelvis (Fig. 4).43 The acetabular socket became deeper and closer to the centre of rotation in order to keep the lever arm of body weight at a favourable distance. This requires a rounder head due to the reciprocal development of the femoral head and acetabulum, but also decreases the required abductor force. Hogervorst et al43 also hypothesised that the shape of the human proximal femur evolved to fit the needs of a ‘running ape’: a sturdy hip with more limited range of movement, and some features of the coxa recta hip.43Corresponding to this, a study examining proximal femur morphology associated with cam impingement noted that femurs with the cam ‘bump’ also had shorter and thicker femoral necks than femurs with a normal alpha angle.44
Fig. 3
Examples of separate and coalesced epiphyses during development of the proximal femur. At the end of growth, humans (A) have separation of the femoral capital epiphysis and the trochanteric apophysis, resulting in a rounder femoral head and longer femoral neck. Most quadripedal mammals (B) have coalescence at the proximal femur, resulting in a shorter, stouter femoral neck, which is more stable but with a smaller range of movement. (Reprinted with permission: Serrat et al. Variation in mammalian proximal femoral development: comparative analysis of two distinct ossification patterns. J Anat 2007;210:249–258).
![Fig. 4
Photographs and reconstructions showing
the evolution of the female pelvis, from the chimpanzee to man,
in anteroposterior (AP) (top row) and axial views (bottom row) From
left to right: chimpanzee, Ardipithecus ramidus (4.4
million years ago), Australopithecus afarensis (3.2
million years ago), Australopithecus africanus (2.7
million years ago), Homo erectus (1.5 million years
ago) and Homo sapiens. Scale is approximate. The
birth canal first widened transversely, but from Au. afarensis to H.
sapiens, the AP dimension deepened. (Reprinted with permission: Hogervorst
et al. Human hip impingement morphology: an evolutionary
explanation. J Bone Joint Surg [Br] 2011;93-B:769–776).](/api/asset/2046-3758.110.2000105/2000105-galleyfig4.jpeg)
Fig. 4
Photographs and reconstructions showing the evolution of the female pelvis, from the chimpanzee to man, in anteroposterior (AP) (top row) and axial views (bottom row) From left to right: chimpanzee, Ardipithecus ramidus (4.4 million years ago), Australopithecus afarensis (3.2 million years ago), Australopithecus africanus (2.7 million years ago), Homo erectus (1.5 million years ago) and Homo sapiens. Scale is approximate. The birth canal first widened transversely, but from Au. afarensis to H. sapiens, the AP dimension deepened. (Reprinted with permission: Hogervorst et al. Human hip impingement morphology: an evolutionary explanation. J Bone Joint Surg [Br] 2011;93-B:769–776).
Developmental influences
The most common deformity causing cam impingement, the cam ‘bump’, may result from an abnormal extension of the epiphysis onto the anterior or anterosuperior neck.27 Initially, the decreased head–neck offset and the cam deformity were thought to occur following a subclinical SCFE. However, the morphology of the proximal femur and the orientation of the physeal scar after a SCFE is substantially different from that occurring in idiopathic cam-type FAI.27,45 There is also evidence that, as the physis is closing, it extends further distally onto the femoral neck,45 supporting the hypothesis that the deformity is due to extension of the epiphysis. One study looked at the incidence of cam deformity in young male basketball players compared with non-athlete volunteers.46 The study included hips both before and after physeal closure, and specifically excluded control volunteers who participated in more than two hours of any vigorous activity per week. The basketball players with closed physes had larger mean alpha angles and a much higher incidence of cam deformity (89%) than the control population (9%).46 Thus, what remains hypothesised but as yet unproven, is that sports cause increased rotational or other mechanical stresses on the physis that are responsible for a change in the physeal growth or closure pattern, causing the stereotypical cam deformity. Specific patterns of physeal adaptation in response to repetitive sports during growth are well-recognised for the upper extremities. These adaptations can be beneficial; for example, asymmetric humeral and glenoid retroversion allowing baseball pitchers to have increased external rotation in the throwing arm.47,48 Alternatively, the load on the physis can cause significant problems, such as wrist pain and early physeal closure seen in many gymnasts.49 There is also good evidence that the relative position and growth of femoral capital epiphysis and trochanteric apophysis affects the shape and orientation of the proximal femur.50,51 The classic proximal femur shape that occurs as the sequelae of childhood Perthes’ disease is one example of this.50 In another example, bony bar formation between the two physes was observed to produce coxa valga with a horizontal physeal scar.51
Prevalence of FAI
The bony anatomy that causes FAI is quite common, and the prevalence depends on the population being studied (Table I).52-65 In asymptomatic young males recruited for the Swiss military, the overall prevalence of the cam deformity was 24%.58 When recruits with limited internal rotation were selected out of the larger cohort, 50% had a cam deformity visible on MRI.58 A different study of this same cohort found that cam deformities were associated with a two- to threefold relative risk of damage to the labrum and cartilage, depending on the lesion.59 Others have also observed that the cam deformity is quite common, with a prevalence of between 14% and 35% in asymptomatic populations, and occurring more frequently in male compared with female hips.53,54,56 When regarding anatomical variations that contribute to FAI (such as acetabular retroversion or overcoverage), 33% of females and 52% of males were found to have at least one factor predisposing them to FAI.55 There may be some genetic influence to this as well, with an increased incidence of cam and pincer morphology in siblings of patients with FAI, with respective relative risk rates of 2.8 and 2.0, respectively, compared with controls.57 In comparison, there is a much stronger genetic component to hip dysplasia, with the relative risk in first-degree relatives of patients with dysplasia ranging from 3 to 12.66
Table I
Prevalence of femoroacetabular impingement (FAI) in asymptomatic and symptomatic hips and those of athletes (AP, anteroposterior)
| Author/s | Population description | Cohort assessed | Imaging used | Major finding | |||
|---|---|---|---|---|---|---|---|
| Asymptomatic general population | |||||||
| Dudda et al52 | Elderly patients with non-arthritic hips (China and US) | 200 (400 hips) (all F) | Supine AP pelvis x-ray | Cam deformity found in 24% of US women and 7% of Chinese women. Pincer deformity (centre-edge angle > 35°) found in 46% of US women and 22% of Chinese women | |||
| Gosvig et al53 | Population-based (Denmark) | 3620 patients (1332M, 2288F) | Standing AP pelvis x-ray | Pistol grip found in 19.4% of male and 5.2% of female hips, deep socket found in 15.2% of male and 19.4% of female hips. Deformity was not predictive for groin pain but deep socket and pistol grip were risk factors for development of OA (relative risks 2.4 and 2.2, respectively) | |||
| Hack et al54 | Recruited volunteers (Canada) | 200 (400 hips) (89M, 111F) | MRI radial slice | 53% had an alpha angle > 50° at the 1:30 (anterosuperior) position. The mean alpha angle was greater in male hips | |||
| Kang et al55 | Patients having abdominal CT for trauma (New Zealand) | 50 (100 hips) | CT | At least one predisposing factor for FAI was found in 33% of female hips and 52% of male hips | |||
| Laborie et al56 | Population-based (Norway) | 2060 (874M, 1207F) | Standing AP pelvis, frog lateral x-ray | In males: 25% bilateral cam and 22% bilateral pincer. In females: 6% bilateral cam and 10% bilateral pincer | |||
| Pollard et al57 | Siblings of FAI patients vs control patients (UK) | 96 cases (54M, 42F) and 77 controls (39M, 38F) | Supine AP pelvis, cross-table lateral x-ray | Siblings of FAI patients have a risk ratio (RR) of 2.8 of having cam deformity, RR 2.0 of pincer deformity and RR 2.6 of bilateral deformity compared with controls | |||
| Reichenbach et al58 | Military recruits (Switzerland) | 244 (all M) | MRI | Cam deformity in 24%, increasing to 48% in hips with limited internal rotation | |||
| Reichenbach et al59 | Military recruits (Switzerland) | 244 (all M) | MRI | Cam deformity associated with labral lesion (adjusted odds ratio (OR) 2.8), impingement pits (adj. OR 2.9) and cartilage thinning | |||
| Sahin et al60 | Contralateral hip of THR patients compared with age and gender controls (Turkey) | 44 cases (23M, 21F) and 40 controls (21M, 19F) | Supine AP pelvis and cross-table lateral x-ray | All 84 participants: pincer FAI in 26% and cam FAI in 68%. Cam deformity found in 84% of study hips vs 32% of control hips; no significant difference in prevalence of pincer FAI | |||
| Athletes | |||||||
| Gerhardt et al61 | Professional soccer players (US) | 95 (75M, 20F) | AP pelvis, frog lateral x-ray | Cam deformity in 68% of male and 50% of female hips; pincer anatomy in 26.7% of male and 10% of female hips | |||
| Kapron et al62 | Collegiate football players (US) | 67 (134 hips) (all M) | Supine AP pelvis, frog lateral x-ray | 95% with at least one finding of FAI: 72% with an abnormal alpha angle, 61% with crossover sign | |||
| Silvis et al63 | Professional and collegiate hockey players (US) | 39 (all M) | MRI | 36% incidence of common adductor dysfunction, 56% with acetabular labral tears, 39% prevalence of cam deformity | |||
| Symptomatic patients | |||||||
| Ochoa et al64 | Active military with hip symptoms (US) | 157 patients (79M, 78F) | Combination of AP pelvis or AP hip and lateral hip | Total of 135 patients (87%) with at least one finding of FAI. Not all patients had complete radiographs, but of those with complete films, 65% had combined impingement, 17% had pure cam and 18% had pure pincer | |||
| Dolan et al65 | Patients (< 55 yrs) with symptomatic labral tears (US) | 135 patients with symptomatic labral tears (78M, 57F) | CT | 90% of symptomatic hips with at least one bony abnormality; 76% prevalence of cam FAI, 43% acetabular retroversion, 55% combination of deformity | |||
Table II
Prognosis of femoroacetabular impingement (FAI)
| Author/s | Population | Number of cases | Imaging used | Level of evidence | Major finding | ||||
|---|---|---|---|---|---|---|---|---|---|
| Allen et al67 | Patients < 55 yrs with symptomatic cam FAI (Canada) | 113 (82M, 31F) | AP pelvis and lateral x-ray | Prognostic, III | 88 patients with bilateral cam, but only 23 of these with bilateral symptoms | ||||
| Audenaert et al68 | Patients < 65 yrs undergoing THR (Belgium) | 121 | AP pelvis and cross-table lateral x-ray | Prognostic, IV | Low correlation of radiological and activity variables with age at THR. Patients with primarily cam impingement were younger at THR than patients with primarily pincer impingement | ||||
| Bardakos and Villar69 | Patients < 55 yrs with idiopathic OA with 10 years of radiological follow-up (UK) | 43 hips (43 patients) (35M, 8F) | Supine AP pelvis x-ray | Prognostic, III | 28 of 43 showed radiological progression of OA | ||||
| Clohisy et al70 | Patients < 50 yrs undergoing THR (US) | 604 (710 hips), (314M, 290F), 118 with FAI | AP pelvis and cross-table lateral x-ray | Prognostic, IV | High prevalence of FAI in patients previously diagnosed with “unknown causes of OA” (118 of 121), 70 FAI patients with radiographs at more than one timpoint all with bilateral findings, 73% progression of disease over time | ||||
| Hartofilakidis71 | Contralateral hip of patients < 65 yrs treated for unilateral hip disease (Greece) | 96 with FAI (31M, 65F) | AP pelvis x-ray | Prognostic, IV | 17.7% progression of OA over 10 years, presence of “idiopathic OA” on contralateral side was the only predictor of progression |
Lending further support to the hypothesis that stress on the developing physis causes FAI pathomorphology, the prevalence of FAI pathoanatomy appears to be more common in athletes. Pelvic radiographs of a cohort of American football players revealed that 61% had a crossover sign (evidence of acetabular retroversion or focal overcoverage) and 91% had at least some lack of femoral head-neck offset.62 In asymptomatic professional soccer players, 72% of males and 50% of females had at least one radiological abnormality predisposing them to FAI.61 MRIs of asymptomatic professional and collegiate hockey players revealed a 39% incidence of increased alpha angle and a 77% prevalence of hip or groin abnormalities, including labral tears, osteochondral lesions, or irregularities at the common adductor-rectus femoris tendon insertions.63
Although FAI-type morphology is common, the prognosis and identification of those patients who ultimately develop arthrosis is unclear (Table II).67-71 There is indirect evidence of the connection between FAI and hip arthrosis. Several studies have found an increased prevalence of hip arthrosis and total hip replacement in athletic patients compared with non-athletic controls.72-77 In 1971 Murray and Duncan78 found that athletes had higher rates of head-tilt deformity, which they interpreted as subclinical epiphysiolysis78; in the era of FAI the same morphology would likely be interpreted as a cam deformity. They also proposed that the subclinical SCFE was the causative factor of the increased rates of hip arthrosis seen in athletic patients.78 In other studies, elite athletes, dancers and those with high activity levels have at least twice the risk of hip arthrosis compared with controls.72-77 In general, the rates of radiological progression of arthrosis for patients with FAI morphology range from 18% to 73%.70,71 The evidence is limited, however, as these studies are Level III or IV evidence, and based on plain radiographs. In patients who do have hip pain or symptomatic labral tears, FAI morphology is very common, with a prevalence of around 90%.64,65
Intra-articular patterns of damage
The intra-articular pattern of chondrolabral damage is specific for each particular type of impingement. The most frequent site of a cam deformity is between 1 and 3 o’clock on the femoral neck, but can extend from 12 o’clock (directly superior) to the ligament of Weitbrecht at 6 o’clock.21,31,54,79 Cam or inclusion-type impingement causes shear and delamination injury to the cartilage.1,20,24 The labrum tears at the chondrolabral junction, but usually remains attached to the acetabular rim (Fig. 5).1,20 Pincer or impaction-type impingement causes a crush or bruising injury to the labrum, with less cartilage damage. Cartilage damage that does occur typically has a linear wear pattern (Fig. 6).20,24 The impact to the acetabular rim causes microfractures, with resultant bone apposition at the rim and labral ossification.23,24 Frequently the impaction causes levering of the femoral head, with a contre-coup injury to the posterior cartilage, opposite to the site of impingement.1,20,21 Patients with acetabular protrusio will also have medial cartilage thinning.22 Patients with subspine (AIIS) impingement have focal synovitis and labral ecchymosis inferior to the AIIS and localised bony build-up at the anterior acetabular rim or calcific deposits within the rectus insertion.28
Fig. 5
Arthroscopic image showing chondrolabral damage occurring as a result of cam impingement. The deformity at the head–neck junction causes a shearing, delamination injury to the cartilage (white arrow) with tearing at the chondrolabral junction (black arrowheads) (L, labrum; FH, femoral head).
Fig. 6
Arthroscopic image showing chondrolabral damage occurring as a result of pincer impingement. The labrum (L) is bruised and hypertrophied, with adjacent synovitis (S). Cartilage damage occurs on the femoral side in a linear wear pattern (FH, femoral head; Ac, acetabulum).
It is also important to recognise the intra-articular pathology associated with instability. Static instability, which typically occurs in the setting of dysplasia, is associated with labral hypertrophy and ganglia.80,81 In contrast to the ‘outside-in’ damage that occurs with inclusion-type impingement, there is an inside-out avulsion of the labrum due to the lateral shear force of the subluxing femoral head. Often this piece of labrum has an attached piece of cartilage.16 Dynamic instability, or instability associated with motion and levering, can also cause the labrum to hypertrophy and develop ganglia. As mentioned earlier, instability that results from levering causes the posterior contre-coup injury to the cartilage. The extreme example of this is an anterior labral tear associated with a posterior subluxation or dislocation event (Fig. 7).82
Figs. 7a - 7b
Fluoroscopic images showing dynamic instability due to impingement. The patient has a large anterior cam deformity, seen here on a lateral view with the leg in flexion (a). As the leg is flexed further, the deformity contacts the rim and causes levering of the head (b).
Exacerbating and mitigating factors
There are clear gender differences in FAI, some of which may actually be a consequence of gender differences in soft-tissue laxity. For example, it is well-recognised that women with symptomatic cam impingement have smaller deformities than men.14,61,83 A motion-analysis study of professional ballet dancers revealed that the repetitive motion of dance and relative soft-tissue laxity allowed the dancers to place their hips in impinging positions, despite not having any anatomic predisposition towards FAI.84 Similarly, because females typically have more soft-tissue laxity than males, they may become symptomatic or have impingement with more subtle deformities than males. The combination of soft-tissue laxity and a predisposition towards acetabular overcoverage also makes females more prone to dynamic instability and levering, with contre-coup cartilage injury.1,11,22,85 Looking at bony anatomy and the mechanical types of FAI, the prototypical patient with cam impingement is a young athletic male,1,21 whereas pincer impingement is more common in women.1,21,29 Further complicating the mechanical situation, symptomatic dysplasia is also more common in females86,87 and can co-exist with acetabular retroversion as well as with FAI.1,37,38,88 One study also found that women presented with worse pre-operative scores for pain and function than men.89 Post-operatively, however, there was no difference in outcomes between men and women, implying that the women had a more marked improvement than the men.89
There is increasing recognition that femoral version can exacerbate or mitigate the severity of FAI (Fig. 8).85,90 Specifically, femoral retroversion may exacerbate the effect of a cam deformity and is associated with decreased internal rotation and osteoarthrosis.83,88 Femoral retroversion was also recognised to be part of the pattern of malunion in post-traumatic FAI.5 An early radiological study of FAI found less femoral anteversion (i.e., retroversion) in a cohort of patients with cam-predominant FAI compared with a control group,14 but a more recent study did not observe a difference in femoral version between FAI patients and a control group.90 The proposed mechanism is that, in the retroverted femur, the femoral head is relatively rotated into the acetabulum, which decreases the clearance for flexion or flexion and internal rotation.14,85,90 Conversely, increased femoral anteversion may mitigate the effect of an anterior cam deformity, but is known to place increased stress on the psoas tendon.91 Patients with increased femoral anteversion who undergo psoas tenotomy are known to have worse results post-operatively, and it is thought that the psoas tendon is a dynamic anterior stabiliser in these patients.91 There has been one study that observed an association between increased femoral anteversion and pincer-type FAI morphology,90 but on the whole the relationship between femoral and acetabular version is unclear, as both positive and negative or inverse relationships between the two have been observed.88,92
Fig. 8
Diagrams showing the proposed mechanism of the effect of femoral version. In the retroverted femur (left), the femoral head is already relatively rotated into the acetabulum, which decreases the clearance of any head-neck abnormality in flexion and exacerbates cam impingement. In an opposite manner, femoral anteversion (right) may mitigate the effect of an anterior cam deformity but could result in more impact on the posterior rim in external rotation. (Reprinted with permission: Sutter et al. Femoral antetorsion: comparing asymptomatic volunteers and patients with femoroacetabular impingement. Radiology 2012;263:475–483).
The effect of femoral neck-shaft angle is even less clear. A varus femur may be associated with symptomatic protrusio and pincer-type FAI,22 and varus malunion was also part of the pattern of post-traumatic FAI.5 A valgus femur can cause static acetabular overload19 and, in rare cases, can cause atypical patterns of impingement such as those occurring after valgus SCFE or valgus malunion of the femoral neck.4 On the whole, however, the mechanical effects of neck–shaft angle, femoral neck length, and femoral offset on FAI are unknown.
The athlete with asymptomatic FAI but limited hip motion may be at risk for additional soft-tissue injury or groin strain when trying to compensate for inadequate rotation.82 This may be especially common for sports requiring axial loading and rotation of the acetabulum over the femur. The ‘sports hip’ triad of labral tears, adductor strains, and rectus strain has been described in a cohort of American football players and provides some evidence for this.82 Other investigators have noted an association of athletic pubalgia and osteitis pubis with decreased hip range of movement.93 There is biomechanical evidence of increased movement at the pubic symphysis in the setting of a cam deformity,94 also providing some confirmation of the hypothesis that osteitis pubis is a compensatory injury secondary to decreased hip range of motion in FAI.
Arthroscopic management of FAI
A review article published on hip arthroscopy in 2003,95 the same year as Ganz et al’s description of FAI,1 lists the following indications for hip arthroscopy: labral tears, capsular laxity, chondral injury, ligamentum teres injuries, snapping hip, loose bodies and osteoarthritis. Although this review describes cheilectomy of the femoral neck for early osteophytes,95 the first arthroscopic technique specifically for management of FAI was published in 2005.96 As the understanding of FAI has improved, arthroscopic treatment of FAI and associated labral tears has also evolved. With minor (and sometimes major) variations in technique, arthroscopic management of FAI is similar to open management and involves resecting the impinging bone on the femoral neck, acetabular rim, or subspine region and addressing the associated chondrolabral pathology with either debridement or refixation.28,97-104
Presently, there are seven systematic review articles examining the outcomes of treatment for FAI, all of which were published between 2008 and 2011.105-111 Although each examines a slightly different question, many of the conclusions are similar. Nonetheless, this collective assessment of the available evidence is useful and makes several important points:
1. The level of the published evidence for arthroscopic management of FAI is relatively low. By far, the majority of studies constitute Level IV evidence, describing the outcomes in retrospective cohorts of patients.105-110
2. However, in comparison to other indications for hip arthroscopy, management of FAI had the best grade of recommendation (B), meaning that there was fair evidence to support the use of hip arthroscopy for treating FAI.108
3. Overall, most patients show improvement after surgery, with good to excellent outcomes in 68% to 96% of patients at two years post-operatively.105,106,110
4. There is an observed ceiling effect to the outcomes scores. Many studies are published with outcomes scores that are not validated for, or responsive to, the hip arthroscopy population.111 Furthermore, non-blinded observers assessed many of the outcome measures, which is a potential source of bias in the evaluation.111
Several systematic reviews have compared open and arthroscopic management of FAI. When early open series were included in the analysis, there was a higher rate of conversion to arthroplasty with open management.107,110 However, when the analysis included only the later series with more selective indications for surgery, conversion rates between arthroscopic and open management were similar. Correspondingly, the rates of good to excellent outcomes are comparable between open and arthroscopic techniques,105,107,110 although reported complications may be slightly less with arthroscopy.109,110 It is important to keep in mind that all of these reports were from high-volume surgeons and that complications will occur more frequently in the hands of less-experienced surgeons. The speed and rate of return to play was initially touted to be faster with arthroscopy,109,110 although this conclusion is debatable due to cultural differences in rehabilitation protocol and incentives for early return to sport. Finally, no direct comparison of return-to-play rates or time to return has been made in an otherwise homogeneous population.109,110 Since these systematic reviews were published, four other studies describing return-to-play in elite athletes have been published, which may have narrowed the gap in time to return, especially as the rehabilitation after arthroscopy may take longer than that initially published.102-104,112
Lessons learned in a decade of treating FAI
The past ten years of treating impingement though both arthroscopic and open techniques have produced important advances in the management of FAI. These advancements have served to refine the surgical indications, improved management of labral tears and helped to minimise complications. Treatment of FAI is, however, a ‘triple threat’: correct diagnosis of the impingement pathoanatomy can be difficult, the surgery itself is technically difficult, and the patients are typically young and active, with high expectations for their post-operative function. One study that assessed six-month post-operative outcomes found that, although patients demonstrated significant improvement in pain and function, “feeling better” (improvement) did not equate with “feeling good” (acceptability of the current status).89 Furthermore, for patients to consider their current state acceptable, the six-month outcome scores had to be 80% to 95% of the best achievable score for the given scale.89
A better understanding of the biomechanics of impingement, instability, and dysplasia facilitated the realisation that most labral tears are actually secondary to an underlying bony abnormality.65,113 Thus, if the patient undergoes labral repair without addressing the underlying impingement or dysplasia, the repair is likely to fail.97,98,114,115 This concept was reinforced by the clinical experience treating patients with recurrent labral tears and hip pain following arthroscopic labral repair, but who had inadequate treatment of their impingement or dysplasia.97,98,114,115 Although the initial observations of the pathology associated with instability and impingement were made via open surgery, observations made during arthroscopy have helped to clarify these mechanisms and the subsequent damage. In particular, arthroscopists have validated the concept that the intra-articular location and pattern of damage correlates with the particular type of impingement or instability,1,20,23,24,28,81 Although the pre-operative clinical and radiological evaluation should guide the plan for addressing the pathoanatomy causing FAI, the intra-operative appearance of the joint and associated damage should be used as confirmatory evidence guiding treatment.
The early failures, complications, and poor outcomes that occurred despite performing a technically good surgery are also important to note. As the short and mid-term results of hip arthroscopy and the treatment of FAI were published, it became evident that chondral damage is the biggest predictor of outcome after surgery for FAI.107,116-118 As a result of this early experience, most authors now consider Tönnis grade 2 or greater arthrosis on pre-operative radiographs a contraindication to surgical management. Heterotopic ossification can be a frequent complication after both open or arthroscopic femoral neck osteoplasty.99,100,119,120 This can be decreased or prevented entirely by giving non-steroidal anti-inflammatories post-operatively.100,120,121 Even prior to the introduction of the arthroscopic technique for managing FAI, it was recognised that traction-related complications are frequent in hip arthroscopy.117,122-127 Thus, inherent to the arthroscopic management of FAI is the importance of being efficient when addressing central compartment pathology and under traction.
Summary and conclusions
The field of preservation of the hip is currently the focus of intense interest, both within the orthopaedic community and among the general public. Correspondingly, this concentrated attention has produced tremendous advancements and change over the past decade. Some types of impingement pathoanatomy can now be treated with predictably good outcomes, for example, those patients with large cam deformities and minimal chondral damage. However, some mechanical hip pain is not yet fully understood. In particular, the intertwined effect of hyperlaxity and gender on both impingement and instability is only now being recognised. Similarly, the importance of femoral version to the mechanics of impingement is currently being worked out. Although femoral retroversion may exacerbate existing cam impingement, further biomechanical confirmation of this effect is necessary. The normal correlation between the acetabular and femoral version is unknown, as is whether a ‘mismatch’ in version can cause pincer impingement or instability.88,92 Finally, the potential contribution of extra-articular impingement and/or secondary instability to hip pain and pathology is beginning to be discussed among leaders in the field, but also remains unexamined. Valuable information about the pathoanatomy and biomechanics of impingement has been produced over the past decade. As a result, the treatment of FAI can relieve symptoms and help return patients to sports and activity. The latter has however be carefully balanced with the intra-articular damage; for some hips, return to sports might be ill-advised, and should not be considered as a measure for treatment success. It remains to be seen, however, if mid and long-term outcomes can be maintained and, ultimately, if this treatment will prevent hip arthrosis.
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Funding statement:
This work received no specific grant from any funding agency in the public, commercial or not-for-profit sectors.
Author contributions:
L. M. Tibor: Contributed to paper concept, Wrote manuscript draft and revisions
M. Leunig: Developed paper concept, Assisted with manuscript revisions
ICMJE Conflict of Interest:
Dr. Leunig has the following potential conflicts of interest: consultant for Smith & Nephew; stock options in Pivot Medical. No payment or benefit of any kind was received related to this work.
©2012 British Editorial Society of Bone and Joint Surgery. This is an open-access article distributed under the terms of the Creative Commons Attributions licence, which permits unrestricted use, distribution, and reproduction in any medium, but not for commercial gain, provided the original author and source are credited.
