The Outcome of 69 Recemented Hip Femoral Prostheses Performed by One Surgeon 22-40 Years Ago.

BACKGROUND: There is a lack of long-term data on cement-in-cement technique in revision of failed hip femoral stem. METHODS: We present the outcome of 69 consecutive recemented femoral prostheses, performed by one surgeon (GH) 22-40 years ago. Four patients (4 hips) were lost to follow-up. Sixty-three patients (65 hips) were followed for their lifetime or until the time of the preparation of the study. The study population consisted of 18 failed hemiarthroplasties and 47 failed total hip arthroplasties. RESULTS: The 23-year probability of survival for the recemented femoral components, with re-revision for any reason and resection arthroplasty as the end point, was 73.6% (61.8%-85.4%) and, with re-revision for aseptic loosening as the end point, was 82.2% (71.4%-93%). CONCLUSION: Our follow-up study at 22-40 years, after recemented hip femoral prostheses, shows that recementing works well in selected cases.

Freeze-Drying Process for the Fabrication of Collagen-Based Sponges as Medical Devices in Biomedical Engineering.

This paper presents a systematic review of a key sector of the much promising and rapidly evolving field of biomedical engineering, specifically on the fabrication of three-dimensional open, porous collagen-based medical devices, using the prominent freeze-drying process. Collagen and its derivatives are the most popular biopolymers in this field, as they constitute the main components of the extracellular matrix, and therefore exhibit desirable properties, such as biocompatibility and biodegradability, for in vivo applications. For this reason, freeze-dried collagen-based sponges with a wide variety of attributes can be produced and have already led to a wide range of successful commercial medical devices, chiefly for dental, orthopedic, hemostatic, and neuronal applications. However, collagen sponges display some vulnerabilities in other key properties, such as low mechanical strength and poor control of their internal architecture, and therefore many studies focus on the settlement of these defects, either by tampering with the steps of the freeze-drying process or by combining collagen with other additives. Furthermore, freeze drying is still considered a high-cost and time-consuming process that is often used in a non-optimized manner. By applying an interdisciplinary approach and combining advances in other technological fields, such as in statistical analysis, implementing the Design of Experiments, and Artificial Intelligence, the opportunity arises to further evolve this process in a sustainable and strategic manner, and optimize the resulting products as well as create new opportunities in this field.