Outlines the acetabular labrum, articular cartilage, and joint capsule. When contraindications (e.g., claustrophobia, pacemaker, cochlear implant, and intracranial aneurysm clip) or resource limitations prevent the use of MRI, CT reformations and 3D reconstructions facilitate the evaluation of osseous morphologic abnormalities such as hip dysplasia, acetabular retroversion, and abnormal offset of the femoral head–neck junction. MRI has been the primary imaging modality in the assessment of patients with suspected internal hip derangement and FAI. By adopting advanced MAR techniques, CT has become more valuable in evaluating implant alignment and bone stock as well as the complications of arthroplasty including liner wear, loosening, particle disease, and periprosthetic fractures. The data from these simultaneous acquisitions are then postprocessed to achieve tissue discrimination, minimization of metal artifact, and enhancement of diagnostic information ( Fig. CT scanners with dual energy capabilities simultaneously perform scans at two different kVps (e.g., 140 kVp and 100 kVp) ( 14). Dual energy CT (DECT) may also be used to decrease metal artifact. Unfortunately, these techniques still require redundant and copious computing power and have the potential to introduce new artifacts that degrade anatomical detail and diagnostic potential. The beam-hardening artifact associated with these metals can be decreased, though not completely resolved, by utilizing iterative techniques with sharp kernels ( 13). Metal artifact is more pronounced with stainless steel and chromium-cobalt alloys when compared to titanium due to higher x-ray attenuation coefficients. These protocols employ postprocessing algorithms that further diminish soft tissue contrast, but decrease the artifact associated with hardware.
Hardware protocols and MAR techniques typically involve the use of higher kilovolt potentials (kVp) and milliampere (mAs) settings compared to CT scans performed for soft tissue evaluation. Otherwise, if a straight AP approach is necessary, care should be taken to palpate, mark, and avoid the femoral neurovascular bundle.Īs metal artifact reduction (MAR) techniques continue to evolve and improve, CT is requested more frequently to evaluate metallic implants and complications following arthroplasty. If a non C-arm fluoroscopy unit is used, the patient can be angled on the table by positioning a sponge or pillow wedge under the ipsilateral hip. Following hip arthroplasty, the prosthetic femoral neck can be targeted. Intra-articular placement can be confirmed by fluid aspiration, loss of pressure resistance to injection or iodinated contrast instillation. For most injections, a 22-gauge 3.5- or 5-in spinal needle is adequate. Slight flexion of the hip can help to relax the anterior joint capsule and facilitate intra-articular access. Several fluoroscopic targets are feasible, including the lateral aspect of the subcapital femoral neck ( Fig. Using this technique, the needle trajectory is often so far lateral to the groin that it is unnecessary to palpate and mark the location of the femoral artery. This anterolateral approach moves the needle entry site lateral to the groin and femoral neurovascular bundle. With the patient positioned supine and the hip externally rotated, the C-arm is angled laterally from the straight AP axis until the beam profiles the femoral neck and greater trochanter (approximately 25 degrees). C-arm units allow the radiation source and detector to be angled along any desired trajectory, thereby optimizing the success and safety of the procedure. Several fluoroscopic techniques can be employed to gain intra-articular access.
If there are no restrictions in patient positioning, the “frog-leg” lateral projection is obtained by flexing, abducting, and externally rotating the hip and directing the beam either vertically or slightly cranially (∼20 degrees) ( Figs. Because the anterior and posterior head–neck junctions are not superimposed in this position, a ridge of femoral head osteophytes can give the false-positive appearance of a sclerotic fracture line ( Fig. In external rotation, the greater and lesser trochanters partially or completely overlap the femoral neck and intertrochanteric region ( Fig. The most common positioning error is external rotation. In this position, the contours of both greater and lesser trochanters should be visible, increasing sensitivity in the detection of subtle destructive lesions and nondisplaced fractures. Internal rotation helps to compensate for femoral anteversion and brings the femoral neck and head–neck junction into appropriate planes relative to the beam of the x-ray. In the absence of known trauma or suspected proximal femoral fracture, the ipsilateral hip is internally rotated approximately 15 degrees to obtain the AP view ( Fig.