Abstract
The application of porous materials is increasingly being used in orthopaedic surgery due to its good results. Bone growth within the pores results in excellent mechanical fixation with the bone, as well as good bone regeneration. The pores, in addition to being colonised by bone, produce a decrease in the modulus of elasticity that favours the transfer of loads to the bone. This research shows the results of an experimental study where we have created critical osteoperiosteal defects of 10 mm on rabbit’s radius diaphysis. In one group of 10 rabbits (experimental group) we have implanted a bioactive porous titanium cylinder, and in another group we have allowed spontaneous regeneration (control group). Mechanical tests were performed to assess the material. Image diagnostic techniques (X-ray, scanner and 3D scan: there are no references on the literature with the use of CT-scan in bone defects) and histological and histomorphometric studies post-op and after 3, 6 and 12 months after the surgery were performed. All the control cases went through a pseudoarthrosis. In 9 of the 10 cases of the experimental group complete regeneration was observed, with a normal cortical-marrow structure established at 6 months, similar to normal bone. Titanium trabecular reached a bone percentage of bone inside the implant of 49.3% on its surface 3 months post-op, 75.6% at 6 months and 81.3% at 12 months. This porous titanium biomaterial has appropriate characteristics to allow bone ingrowth, and it can be proposed as a bone graft substitute to regenerate bone defects, as a scaffold, or as a coating to achieve implant osteointegration.
Highlights
The treatment of bone defects represents an unsolved problem in reconstructive orthopaedic surgery, and the most frequent procedures used on the treatment of those defects are the bone grafts
Porous titanium scaffold was produced by Powder Metallurgy (PM) technique mixing commercially pure titanium, with a mean grain size of about 80 μm, with NaCl particles of 300 to 600 μm of diameter as space holder, in a 65-to-35% volume ratio
The results showed that there were no differences in titanium before and after treatment; this fact ensures the good quality of the treatment
Summary
The treatment of bone defects represents an unsolved problem in reconstructive orthopaedic surgery, and the most frequent procedures used on the treatment of those defects are the bone grafts. Cellular metallic prosthesis presents a particular interest in orthopedics applications, due to the reduction of the stiffness between bone tissues and titanium implants avoiding the stress shielding. This stiffness can be controlled by adjusting the pore size and total porosity of the implant. These aspects favor the replacement of damaged or broken bones [1,2,3,4]. The cellular hip implants with different unit cell size and porosity were manufactured via selective laser melting (SLM) using the
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