Plain radiographs are the most important imaging studies for the diagnosis
of impingement. The recommended radiographs are an anteroposterior view of the
pelvis and a cross-table lateral view of the hip in 15° of internal
rotation17. Tilting
of the pelvis on the anteroposterior view may obscure overcoverage or
undercoverage of the femoral head as well as affect the measurement of
acetabular anteversion. An optimal anteroposterior pelvic radiograph is one on
which the coccyx points toward the symphysis pubis with a distance of no more
than 2 cm between them and with symmetrical teardrops, obturator foramina, and
iliac wings (Figs. 2-A,
2-B, and
2-C)7,20.
Siebenrock et al.20
suggested that the optimal distance between the symphysis pubis and the middle
of the sacrococcygeal joint is 25 to 40 mm in females and 40 to 55 mm in
males. A reconstructed computed tomography scan to correct for tilt can be
used in place of a tilted anteroposterior pelvic
radiograph13,28,39.
The morphologic features on the radiograph that favor a diagnosis of
anterior impingement are a congruent but nonspherical femoral head, a short
femoral neck, and/or a small head-to-neck ratio with a reduced head-neck
offset. The most prevalent finding on the anteroposterior radiograph is a
flattened head-neck junction or a pistol-grip
deformity24
(Fig. 2-B). A pistol-grip
deformity is characterized by flattening of the usually concave surface of the
femoral head, a bump on the anterolateral surface of the femoral neck, a
so-called medial hook at the medial head-neck junction, and failure of the
femoral head to be centered over the femoral
neck4,24,26,40.
With milder forms of anterior impingement, the findings may be seen on only
lateral radiographs, which show displacement of the head over the neck and the
medial
hook4,24,26,40.
Specific acetabular changes include an os acetabuli or ossification of the
acetabular rim.
Pincer impingement is commonly associated with acetabular protrusion, coxa
profunda, or a retroverted
acetabulum1. An
additional observation on plain radiographs may be juxta-articular fibrocystic
changes (herniation pits) at the anterosuperior aspect of the femoral
neck13,35,41.
Fluoroscopy of the hip can be used in equivocal cases to observe whether
impingement occurs with dynamic motion of the
hip36.
Radiographic Measurements
A distance between the anterior and posterior margins of the acetabulum of
either greater or less than the normal distance of 1.5 cm can define the
presence of abnormal
version28.
Acetabular retroversion is also indicated by the crossover and posterior wall
signs18,20,21,28,34
(Figs. 3-A,
3-B, and 3-C). The head-neck
off-set can be measured quantitatively on a cross-table radiograph by drawing
a line bisecting the longitudinal axis of the femoral neck (which may not pass
through the center of the head), a parallel line tangential to the anterior
aspect of the femoral neck, and a third line parallel to the others and
tangential to the anterior aspect of the femoral
head4. The
perpendicular distance between the lines tangential to the neck and the
anterior aspect of the head is defined as the head-neck offset, with normal
being an absolute value of =9 mm or a ratio of the head diameter of
=0.174,36,42.
Computed Tomography and Magnetic Resonance Imaging
The common use for computed tomography scans in the evaluation of
impingement is to allow three-dimensional reconstruction of the hip joint for
detailed definition of femoral head-neck asphericities and reduced offset,
which cause osseous impingement, as well as determination of the version of
the femoral neck and the
acetabulum43. A
computed tomography scan also provides the opportunity to produce software
that can simulate impingement.
A gadolinium-enhanced magnetic resonance arthrogram is needed to assess
labral injury and the articular cartilage as well as to demonstrate the
contour of the femoral head-neck
junction7,9,15,16,35,44-46.
In one study, the sensitivity of magnetic resonance arthrography in detecting
labral hypertrophy, degeneration, and/or tears was between 63% and 90%, while
specificity was >70% when only labral tears were
present16. (The
specificity is poor for detecting chondral separations that remain
undetached7,44.)
Measurements made on computed tomography or magnetic resonance imaging scans
can suggest
impingement9,15-17,35,43-46.
Kassarjian et
al.45, using
magnetic resonance arthrography, defined a triad of anomalies in 88% of
patients with cam impingement: an abnormal head-neck morphology,
anterosuperior cartilage abnormality, and anterosuperior labral abnormality.
In addition, dynamic magnetic resonance imaging with an open or large-bore
unit can provide real-time imaging of the
impingement35.
Nonoperative Treatment
The goal of treatment is relief of the impingement. An initial trial of
nonoperative treatment has been recommended by some
authors7,11,38,44,47.
This may include modification of activity; restriction of athletic pursuits;
and reduction of excessive motion of, and demand on, the hip. Nonsteroidal
anti-inflammatory medication may relieve pain, but it may also mask symptoms.
Physical therapy should emphasize muscle-strengthening and avoidance of
extremes of range of motion. The young age of these patients means that they
have a high activity level and athletic ambitions, which usually jeopardize
compliance with nonoperative treatment.
Hip impingement is a mechanical problem, and nonoperative measures will not
eliminate the pathomechanics of structural
deformities1,47.
Jäger et al.38
recommended an operation in patients with symptoms that persist beyond six
months, provided that the articular damage is not severe. In their study, all
nine patients who underwent nonoperative treatment had continued pain and hip
dysfunction whereas six patients treated with an open osteoplasty all rated
the hip as excellent or good and had resolution of the clinical symptoms.
There seems to be little place for nonoperative treatment except when the
cause is overuse without structural deformity.
Operative Treatment
Chronicity of signs and symptoms along with radiographic evidence of
impingement and chondral and/or labral lesions are clear indications for
operative
intervention7,38,44.
When there is damage to the articular cartilage it is permanent and may
compromise the result of operative treatment. Operative treatment focuses on
improving the clearance of hip motion and alleviating femoral abutment against
the acetabular rim, which will relieve the pathologic changes in the labrum
and the articular cartilage. The three choices of treatment are arthroscopy,
arthroscopy combined with a limited open operation, and an open operation with
surgical dislocation of the hip. The operative treatment is chosen according
to the specific disease pattern being corrected and the technical preferences
and treatment philosophy of the surgeon. Open operative treatment is the
original and best documented method for treatment of femoroacetabular
impingement6, and it
is the standard against which other joint-preserving treatment methods must be
measured.
Arthroscopy
Usually, arthroscopy is indicated during the earlier stage of the
disease47-49.
Clohisy and McClure stated that they preferred to perform arthroscopy
initially to inspect the hip and determine the severity of the disease and to
address the labral and chondral
lesions36; when
they found localized disease, they performed a limited open resection
osteoplasty without dislocating the joint. However, if the disease is
extensive or global or there are posterior hip impingement lesions, surgical
dislocation of the hip is necessary because it provides circumferential
exposure and access to the entire acetabulum and proximal part of the
femur6,7.
The most common use for this minimally invasive treatment option is
assessment and reconstruction of a nonspherical femoral head with a decreased
head-neck
offset44,47-49.
Associated labral and chondral lesions are treated in the hope of restoring
nearly normal mechanics of the hip joint during the extremes of
motion47. The
technique separates the hip into two compartments, central and peripheral. The
central compartment includes the weight-bearing part of the head, the
articular cartilage of the head, the acetabular fossa, and the ligamentum
teres. The peripheral compartment contains the non-weight-bearing portions of
the femoral head, the femoral neck, the hip capsule, synovial folds, and the
orbicular ligaments. Access to the anterolateral aspect of the neck is through
the peripheral compartment, and visualization of the labrum is through the
central
compartment47.
Labral lesions and any areas of chondral damage can be addressed, and labral
tears can be repaired. Labral resection should be conservative, and attempts
should be made to leave a stable labral remnant. In areas of exposed
subchondral bone, a microfracture technique, chondroplasty, or drilling may be
performed to stimulate a fibrocartilaginous
response47-49,
although we are not aware of any reports of the clinical outcomes of these
techniques in hips with impingement. Osteophytes on the femoral head or neck
may be resected with a power burr or a radiothermal device to restore the
concavity of the femoral head-neck junction. To avoid injury to the branches
of the medial circumflex vessels, the distal and posterior extent of the
procedure should be limited on the femoral neck to the area of impingement,
typically about 10 mm from the articular
margin47. A
concomitant excision of the anterior part of the acetabular rim is indicated
when that part of the rim contributes to the impingement.
Weight-bearing is restricted following reconstruction to decrease the risk
of postoperative femoral neck
fracture47,49.
Patients are allowed to stop using crutches in two to four weeks, and for four
to six weeks activities are limited to range-of-motion exercises with use of a
stationary bicycle or swimming. The femoral neck should be protected from
fracture after osteochondroplasty of the head-neck junction for three to six
months.
The results of arthroscopic surgery reported to date have been short-term,
and we have no knowledge of the ability of this operative technique to alter
the course toward total hip arthroplasty. Of 156 patients (age range, fourteen
to seventy-three years) who had been treated with arthroscopy, 50% stated that
the pain had resolved by three months; 75%, by five months; and 95%, by one
year49. During that
time, three patients required a total hip arthroplasty, and these failures
correlated with the amount of articular cartilage damage noted at arthroscopy.
Similarly, Guanche and
Bare47 found that
their results correlated with the presence of degenerative cartilage changes.
The advocates for arthroscopic surgery have suggested that the results will be
comparable with those reported following open operations, but the patients
recover much earlier after arthroscopic
surgery44,49;
however, most arthroscopically treated patients have early-stage disease.
Hybrid Arthroscopy and Open Procedures
Arthroscopy with a limited open osteochondroplasty is advocated for the
treatment of focal cam impingement. The potential advantage is that it is less
invasive than surgical dislocation, and it may reduce complications while
enabling quicker
recovery36. This
approach was developed because of concerns that arthroscopy would provide
inadequate exposure of the head-neck junction, create the potential for
osseous debris to become entrapped in the joint, and provide an inadequate
osseous reconstruction. Arthroscopy can allow treatment of labral disease at
the acetabular margin and any associated chondral damage. The limited open
procedure, with use of the Smith-Petersen interval and without dislocation of
the hip, is difficult except in thin patients, and we are not aware of any
published reports of clinical outcomes. Exposure of the anterolateral
head-neck junction and the anterolateral aspect of the acetabular rim allows
osteoplasty at these sites. This procedure is not advocated for hips with
posterior impingement or circumferential lesions of the femoral head. The
postoperative treatment is similar to that described following
arthroscopy36.
Open Procedures
Operative reconstruction as joint-preserving surgery has been recommended
for osteoarthritis that is no worse than grade
12,50.
Advanced degenerative changes and extensive chondral lesions have not
responded well to open débridement, with high rates of progression and
conversion to a total hip
arthroplasty2,25.
Patients who have a structural problem that cannot be corrected with this
technique are not candidates, and it may be relatively contraindicated in
elderly patients, depending on the severity of symptoms and presence of
secondary arthritic
changes51. In their
original report, Ganz et
al.6 stated that
they made an intraoperative decision to perform a total hip arthroplasty in
patients with advanced chondral lesions. Patients with migration of the
femoral head into the acetabular cartilage defect at the time of evaluation
may benefit from surgery in the short term, but ongoing degeneration of the
hip has to be
expected11.
Open procedures have been performed with a posterior incision made from the
posterior-superior edge of the greater trochanter distally to the posterior
border of the vastus lateralis
ridge6,52.
After placement of drill holes for later reattachment, a trochanteric flip
osteotomy (or a trigastric osteotomy with the gluteus medius, vastus
lateralis, and gluteus minimus remaining attached to the trochanteric
fragment) is
performed6. The
osteotomy consists of a horizontal cut with the leg internally rotated. It has
a maximum thickness of 1.5 to 2.0 cm at its proximal
limit6,52.
The osteotomy (Figs. 4-A and
4-B) must be anterior to the most posterior insertion of the
gluteus medius tendon and should exit superficial to the piriformis fossa
superiorly. At the vastus ridge distally, the integrity of the external
rotator muscles is respected, with preservation and protection of the
profundus branch of the medial circumflex femoral artery, which becomes
intracapsular at the level of the superior gemellus
muscle53. It is
also necessary to protect the epiphyseal branches of the medial circumflex
femoral artery, which lie subperiosteally on the posterior-superior surface of
the femoral neck. It must be remembered that the blood supply to the femoral
head arises mainly from the medial circumflex femoral artery, and during
dislocation of the hip this vessel is protected by the intact obturator
externus
muscle6,7,53.
Some surgeons prefer to assess the sciatic nerve to determine if it bifurcates
over the belly of the piriformis, and, if it does, the piriformis is released
to prevent traction injury to the more superficial branch during hip
dislocation.
Capsular incision: The capsule is incised anterolaterally along
the axis of the femoral neck. The capsulotomy must remain anterior to the
lesser trochanter to avoid damage to the main branch of the medial circumflex
femoral artery, which lies just superior and posterior to the lesser
trochanter. Elevation of the anteroinferior capsular flap allows visualization
of the acetabular labrum. The first capsular incision is then extended toward
the acetabular rim, where it is sharply turned posteriorly, parallel to the
labrum, reaching the retracted tendon of the piriformis (completing the
z-shaped capsulotomy for the right
hip6
[Fig. 5] and an inverse
z-shaped capsulectomy for the left hip). Alternatively, a T-shaped capsulotomy
may be done52.
Dislocation: Anterior dislocation of the femoral head provides up
to an 11-cm gap between the femoral head and the acetabular surface and
provides a 360° view of the joint, including the acetabular rim, labrum,
articular cartilage, and femoral head-neck
junction6. The
ligamentum teres can be torn by further external rotation of the femoral head,
or incised without loss of the important blood supply to the
head6,54.
Placement of a 2.0-mm-diameter drill hole into the dislocated femoral head can
document the preservation of its blood supply, although this should not be
used as an absolute
test6,54.
Bleeding of the surfaces of the cancellous bone after trimming of osteophytes
on the periphery of the head is an additional sign of satisfactory
vascularity. Laser Doppler flowmetry has shown that blood flow is consistently
restored after relocation of the
hip54. After
operative treatment, the capsule of the hip may be repaired, but it should not
be tightened since this may create tension on the retinacular vessels, causing
a decrease in perfusion of the femoral head. The greater trochanter is
reattached with use of two or three 3.5 or 4.5-mm cortical screws. Cerclage
wires may endanger the blood supply to the head, and their use is not
encouraged. Ganz et
al.6 stated that
they did not routinely use prophylaxis against heterotopic ossification but
did use subcutaneous low-dose heparin for eight weeks postoperatively for
prophylaxis against venous thrombosis.
Some authors have used other approaches for localized or less extensive
lesions25,38.
The direct lateral exposure can be chosen for hips in which less exposure of
the posterior-inferior aspect of the acetabulum is required, and the
iliofemoral exposure may be chosen for hips with pure anterior impingement.
However, global visualization and comprehensive deformity correction on both
sides of the joint are best obtained with the trochanteric flip
operation6. All
approaches that retain an intact greater trochanter are associated with
greater difficulty in separating and mobilizing the gluteus minimus from its
attachment to the capsule, since the tip of the greater trochanter overlies
the most critical part of its
insertion6.
Treatment Options for the Lesions Seen with Impingement
Osteoplasty of the Femoral Neck
To avoid lateral retinacular vessels on the posterolateral aspect of the
femoral neck, the osteotome used for the osteoplasty should be oriented
perpendicular to the cartilage plane and small pieces of bone should be
fractured gently by prying distally on the
fragment11. The
pieces of bone are sharply dissected free of retinacular attachment with a
scalpel. Studies of cadavera have shown that the total amount of bone resected
should not exceed 30% of the anterolateral quadrant of the head-neck junction
to minimize the risk of femoral neck
fracture51.
Resection of approximately 20% of the head-neck diameter has been found to be
satisfactory for optimizing hip flexion without
impingement52.
Before capsular closure, the cartilage edge on the femoral head, created by
the osteotome, is smoothed with a scalpel, and bone wax is applied to the
bleeding
surface11.
This review has not focused on extra-articular impingement, but it should
be noted that reorientation of the proximal part of the femur with a
flexion-valgus intertrochanteric osteotomy can be done to reduce
extra-articular impingement caused by decreased femoral anteversion or a varus
position of the
neck6,11.
Relative neck lengthening through trochanteric advancement is another option
for increasing clearance and alleviating the extra-articular impingement to
optimize hip
abduction7.
Acetabular Osteotomy
The prominent anterior aspect of the acetabular rim can be removed by
resection osteoplasty or by reorientation of the retroverted
acetabulum11. The
acetabular depth, in particular the posterior wall, and the status of the
acetabular articular cartilage determine which option should be chosen. If the
acetabulum is retroverted, it can be internally rotated and flexed through a
periacetabular osteotomy. Siebenrock et
al.20 reported good
or excellent results in twenty-six (90%) of twenty-nine hips treated with this
procedure55;
however, it can produce an excessively prominent posterior wall and cause
secondary posterior impingement. Conversely, a reverse periacetabular
osteotomy may be preferred if the acetabular articular cartilage is intact,
but there is a lack of posterior
coverage7,11.
The anatomy of the posterior wall is best assessed on an anteroposterior
pelvic radiograph on the basis of the posterior wall
sign20,34.
Simple rim osteoplasty and labral repair can be done after dislocation of
the hip. Identified labral and chondral lesions are tested, with use of a
nerve hook, for partial or complete avulsions from the acetabular
rim11. In cases of
anterior overcoverage, a resection osteoplasty of the anterosuperior aspect of
the rim is done after mobilization of the acetabular labrum. Resection of the
labrum (limited to the injured area) is done when it is ossified or when
excessive scarring, attrition, or degeneration of the labrum is seen. The
amount of rim resection can be estimated after reduction of the head and
evaluation of the impingement. The labrum is then reattached to the acetabular
rim with anchored sutures. The hip is reduced, and the stability of labral
fixation and the resolution of impingement are confirmed. In a retrospective
study of matched cohorts, Espinosa et
al.5 found that
thirty-two patients treated with labral refixation recovered earlier and had
superior clinical and radiographic results at one and two years when compared
with twenty patients who had undergone resection of the torn labrum.
Postoperative Rehabilitation and Pattern of Recovery
The hospital stay ranges from two to four days. To prevent adhesions
between the capsule and the site of the femoral osteoplasty, a
continuous-passive-motion device is used for the first postoperative
week11. Protected
weight-bearing and limitation of flexion to 70° are continued for eight
weeks, after which the patient begins self-administered abduction exercises as
well as swimming (except for the breast stroke) and bicycling. At three to six
months, the patient may be allowed to resume all activities of normal living.
Ganz et al.55 did
not recommend starting or continuing with high-impact or stop-and-go sports.
Joint-preserving surgery does not provide a perfectly normal joint, and
high-impact sports can cause the operation to fail.
Clinical Outcomes
Osteonecrosis has not been reported, to our knowledge, after open
reconstruction involving
dislocation2,6,25,26,38.
Ganz et al.6
performed 213 surgical dislocations, including twenty-four with an additional
intertrochanteric osteotomy. They did not include hips that had been converted
intraoperatively to a total hip replacement in their report. Three hips (1.4%)
required a reoperation because of trochanteric nonunion, and heterotopic
ossification developed in seventy-nine hips (37%). Most patients had an
improvement in the range of motion and a decrease in pain, although these
results were not specifically discussed. In a study by Murphy et
al.25, seven (30%)
of twenty-three hips treated with débridement because of
femoroacetabular impingement were converted to a total hip arthroplasty and
one had subsequent arthroscopic débridement of a recurrent labral tear.
Beck et al.2
reported that fourteen of nineteen patients had an excellent or good result at
a mean of 4.7 years after surgical treatment of femoroacetabular impingement,
whereas five required a total hip arthroplasty.
Although long-term analyses of the outcomes of surgical intervention are
not available, the preliminary results indicate that surgical dislocation of
the hip to allow improvement in the head-neck offset, as well as rim
osteoplasty, is successful in alleviating the symptoms of impingement in most
patients. It is important that the treatment, particularly realignment
osteotomies of the acetabulum and proximal part of the femur, do not result in
secondary impingement. Although early correction of impingement has improved
hip function, it is not yet known how often the correction prevents the
progression of osteoarthritis. ?
Note: The authors appreciate the suggestions and advice of
Reinholz Ganz, MD, in the preparation of this manuscript.