Description

Hip osteoarthritis is nowadays one of the most prevalent diseases in developed countries. Prosthetic replacement of the degenerated joint is the definitive treatment for more advanced stages of osteoarthritis.

Despite continuous improvements in prosthesis material, design, and implantation procedures that have led to a percentage reduction in failures, there is still an albeit low risk of hip prosthetic implantation failure today.

Preoperative planning is therefore a prerequisite in order to ensure the success of the implant and its longterm survival. This is generally based on radiographic investigations, with implant selection being based on "templating" the radiographs to replicate the patient's joint anatomy.

However, with preoperative radiographs (or possibly second-level investigations such as CT scans), only the geometry of the bone subjected to the implant through is evaluated, without obtaining information regarding the bone density or the load to which the implant will be subjected. However, the long-term stability of the implant depends on the load transfer to the adjacent bone. Non-physiological load transfer can cause stress-shielding, bone resorption, or fibrous tissue growth due to high micromovements at the implant-bone interface.

The study of images by finite element analysis (FEA) has been used in orthopedic biomechanics for fifty years, and the techniques have progressively evolved in terms of sophistication and ability to assess the postoperative mechanical environment The Bone Strain Index (BSI) software, obtained from computerized bone mineral imaging (DXA) surveys using FEA, automatically calculates the deformations and stresses to which a given bone segment is subjected from patient-specific loading conditions. Previous studies have evaluated changes in periprosthetic bone mineral density (BMD) around hip replacement, noting densitometric changes that could vary between subjects and as a function of treatment, suggesting periprosthetic DXA as a useful technique in early assessment of possible bone loss from periprosthetic resorption. However, there are no DXA-based studies in the literature that correlate BMD changes to periprosthetic mechanical stress.

In this study, the investigators aim to study periprosthetic hip bone by DXA technique, applying the FEA method to obtain two-dimensional models of bone resistance to loading, using BSI software.

This evaluation will be included in the context of the normal pre- and postoperative evaluation process, with a view to better understanding the therapeutic outcome and possibly providing a means of predicting early mobilization and thus possible surgical failure.

Patients will be recruited as part of the normal surgical procedure for patients referred for hip replacement surgery to be performed at the Galeazzi - Sant'Ambrogio Hospital. Subjects, after being informed about the study and giving their written informed consent, will provide the examining physician with the information needed to fill out appropriate biographical and medical history forms. Recruitment will be entrusted to the physicians who will perform routine clinical examinations.

Once enrolled, patients will have a lumbar and femoral DXA scan as a preoperative preliminary investigation; anthropometric evaluations, postoperative DXA scans (immediate postoperative and at 3,6,12 months), blood draws, and PROMs will be administered for each patient. The study will be conducted according to the guidelines of Good Clinical Practices