Challenges in Total Hip Arthroplasty with Prior Spinal Arthrodesis: A Comprehensive Review of Biomechanics, Complications, and Surgical Strategies.

Total hip arthroplasty (THA) has revolutionized patients' lives with hip osteoarthritis. However, the increasing prevalence of THA in individuals with prior lumbar arthrodesis (LA) poses unique challenges. This review delves into the biomechanical alterations, complications, and surgical strategies specific to this patient subset, highlighting the need for tailored preoperative assessments and planning. Due to altered pelvic and spinal biomechanics, patients with LA undergoing THA face a higher risk of dislocation and revision. The complex interplay between spinal and hip biomechanics underscores the need for meticulous preoperative planning. Comprehensive clinical examination and radiographic evaluation are vital for understanding patient-specific challenges. Various radiographic techniques, including computed tomography (CT)/X-ray matching and standing/seated studies, provide insights into postural changes affecting pelvic and spinal alignment. Complications following THA in patients with LA highlight the necessity for personalized surgical strategies. Careful consideration of implant selection, the surgical approach, and component positioning are essential to prevent complications. In summary, THA in patients with prior LA demands individualized preoperative assessments and planning. This approach is crucial to optimize outcomes and mitigate the heightened risks of complications, underlining the importance of tailored surgical strategies.

Arthroscopic Reduction and Fixation of a Pipkin Type-I Femoral Head Fracture.

Background: This video article describes the technique for arthroscopic reduction and fixation of Pipkin type-I fractures. Description: Surgery is performed with the patient in a supine position, with free lower limbs, on a radiolucent table. Arthroscopic superior and anterolateral portals are made similarly to the portals created to evaluate the peripheral compartment during an outside-in (ballooning) technique.1 An additional medial portal is subsequently created in order to aid in reduction and screw placement. The medial portal is created in abduction and external rotation of the hip (i.e., the figure-4 position). The adductor tendon is identified, and the portal is then safely positioned posteriorly to its margin, approximately 4 to 5 cm distal to the inguinal fold, avoiding the saphenous vein (usually identified with an ultrasound scan). The fragment is mobilized, debrided, and then reduced with use of a microfracture awl or a large Kirschner wire (used as a joystick). Following reduction, temporary fixation is performed with use of long Kirschner wires under direct visualization and fluoroscopic guidance. If reduction is satisfactory, definitive fixation can be performed with use of 4.5-mm headless screws through the medial portal. All steps of fragment reduction and fixation are performed through the medial portal, with the patient in the figure-4 position. Once the screws are placed, a final dynamic arthroscopic and fluoroscopic check is performed. Alternatives: In Pipkin type-I fractures, surgery is recommended when the femoral head fragment is large (exceeding 15% to 20% of the femoral head volume) and displaced (by >3 mm). In such cases, if untreated, spontaneous evolution to osteoarthritis may occur. For fragments smaller than 10% to 15% of the femoral head volume, arthroscopic removal is often the best choice2. Several approaches (e.g., Smith-Petersen, modified Hueter, Kocher-Langenbeck, and surgical safe dislocation) have been proposed for reduction and fixation, with surgical safe dislocation being the most versatile because of the uniquely complete visualization of the femoral head3. Rationale: The arthroscopic reduction and fixation technique for a non-comminuted Pipkin type-I fracture holds the intrinsic advantages of being less invasive than open surgery in terms of surgical exposure, and having less blood loss, infection risks, and wound complications. Arthroscopy allows direct visualization of the fragment and its reduction surface, along with removal of articular loose bodies and debridement. The surgical time is influenced by the surgeon's experience, but often is no longer than with an open procedure. In the few studies assessing the use of this technique, the rates of osteonecrosis and heterotopic ossification are lower than with open techniques. It is worth noting that the studies assessing the use of this procedure are limited both in number and quality; however, the results of these studies have been excellent. It must also be noted that patients undergoing arthroscopic fixation are mostly selected for this treatment because they have less severe injuries2-12. Expected Outcomes: Open reduction and fixation through one of a variety of approaches is the gold standard treatment for Pipkin fractures; however, it is a relatively invasive procedure, prone to increased risks of osteonecrosis of the femoral head and heterotopic ossification (from 4% to 78% of cases). In some cases, arthroscopic reduction and fixation can be as effective as open reduction, and carries with it the intrinsic advantages of a keyhole procedure. The reported 4.6% global complication rate following arthroscopic fixation demonstrates the potential advantages of this technique, with limits due to the low numbers of treated cases4. Important Tips: The operating room should be carefully set up, especially regarding the positions of the C-arm and the arthroscopy tower, which should be double-checked before starting the procedure.The medial portal should be created after identification of the saphenous vein on an ultrasound scan. The anesthesiologist or a radiologist may mark the vein on the skin preoperatively, or the surgeon may extend the arthroscopic portal and perform a superficial dissection to avoid the vessel.Visualization after creation of the portals is usually suboptimal until the hematoma is completely removed. Patience must be maintained in this phase of the procedure.A microfracture awl or a large Kirschner wire can be utilized as a joystick to aid in reduction of the fragment, from either the usual portals or the medial portal. This aid can facilitate rotation of the fragment, which is a key step in the reduction phase.Definitive fixation can be achieved with use of 4.5-mm cannulated headless screws. Large cannulated headless screws have longer and larger Kirschner wires that can also aid in reduction when used as joysticks, reducing the risk of bending or breaking during screw insertion. Additionally, a 4.5-mm screwdriver is longer, allowing easier insertion, especially in patients with a larger thigh. The large diameter should not be a concern because the head is sunk in a non-weight-bearing area of the head.To avoid the risk of misplacement or loss of the screw during its insertion, make use of a cannulated guide handle for 4.5-mm screws, such as the guide utilized in a Latarjet arthroscopic procedure.To prevent screw loss into the joint, utilize a loop-knotted wire around the proximal part of the screw; this wire is cut at the end of the procedure. Acronyms and Abbreviations: AAFF = arthroscopic-assisted fracture fixationHO = heterotopic ossificationUS = ultrasound/ultrasonographyAP = anteroposteriorCT = computed tomographyASIS = anterosuperior iliac spineGT = greater trochanterSP = Smith-PetersenIF = internal fixationK-wire = Kirschner wire.

Surgical Technique: Arthroscopic Reduction and Fixation of Partial Posterior Wall Acetabular Fractures.

Partial posterior wall fractures are usually fixed with open reduction-internal fixation through an open posterolateral approach, but when the fragment may be fixed without a plate (with screws only), reduction and fixation may also be achieved via hip arthroscopy with the patient in the prone position. This article presents all the surgical steps to perform this procedure.

Endoscopic Assisted Percutaneous Fixation of Anterior Inferior Iliac Spine Avulsion Fracture, Surgical Technique.

Avulsion fractures of the anterior inferior iliac spine rarely occur in adolescent athletes during rectus femoris contractions or eccentric muscle lengthening while the growth plate is still open. Currently, there are no official guidelines in the literature on the treatment indications of this type of fracture or the type of surgical technique to be used. Nowadays, young and athletic patients desire a quick return to their previous activities, which makes surgical treatment a reasonable choice. Open reduction and internal fixation with an anterior approach are usually recommended when the avulsion fragment has more than 1.5-2 cm displacement on plain radiographs. However, ORIF is associated with a higher risk of heterotopic ossifications and increases the risk of damage to the LFCN. An endoscopic technique was designed to reduce these complications. This technical note describes a procedure of percutaneous fixation to AIIS through 3 endoscopic portals that could potentially minimize complications associated with an open surgical dissection, allowing anatomic reduction under direct visualization.

Reevaluation of the surgical indications for anterior inferior iliac spine avulsion fractures in an acute setting - A narrative review of the current literature.

Purpose: The anterior inferior iliac spine (AIIS) is a frequent site of avulsion fracture in the pelvis, and these lesions could be observed mainly in teenage athletes. The present study aimed to re-evaluate the appropriate acute surgical treatment of AIIS avulsion fractures considering the three-dimensional anatomy of the supracetabular region. Methods: This study evaluated current evidence of AIIS avulsion fracture treatments and outcomes. A literature search was done in the following databases: PubMed, SCOPUS, Embase, and Cochrane Library. All relevant information was used in this review. Results: Several studies have shown how conservative treatment of these injuries lead to excellent outcomes, even when there is radiological evidence of displacement. However, only some surgeons describe clinical and radiological follow-up beyond six months. On the other side, recent studies have demonstrated the efficacy of arthroscopic or open procedures to solve a frequent cause of extra-articular femur-acetabular impingement (FAI) syndrome associated with previous AIIS avulsion fractures, the so-called sub-spine impingement. The acute surgical indication in AIIS avulsion fractures should be considered according to the three-dimensional anatomy of the supracetabular region, especially in young patients with high functional demands. Conclusions: Three-dimensional assessment allows accurate evaluation of the position and dislocation of the fragment, predicting the risk of complications related to conservative treatment and guiding toward surgical indication only when appropriate.