Biosilicate® and low-level laser therapy improve bone repair in osteoporotic rats.

The aim of this study was to investigate the effects of a novel bioactive material (Biosilicate®) and low-level laser therapy (LLLT) on bone fracture consolidation in osteoporotic rats. Forty female Wistar rats were submitted to ovariectomy (OVX) to induce osteopenia. Eight weeks after surgery, the animals were randomly divided into four groups of 10 animals each: a bone defect control group (CG); a bone defect filled with Biosilicate group (BG); a bone defect filled with Biosilicate and irradiated with LLLT at 60 J/cm(2) group (BG60); and a bone defect filled with Biosilicate and irradiated with LLLT at 120 J/cm(2) group (BG120). Bone defects were surgically performed on both tibias. The size of particle used for Biosilicate was 180-212 µm. Histopathological analysis showed that bone defects were predominantly filled with the biomaterial in specimens treated with Biosilicate. LLLT with either 60 or 120 J/cm(2) was able to increase collagen, Cbfa-1, VGEF and COX-2 expression in the circumjacent cells of the biomaterial. A morphometric analysis revealed that the Biosilicate + laser groups showed a higher amount of newly formed bone. Our results indicate that laser therapy improves bone repair process in contact with Biosilicate as a result of increasing bone formation, as well as COX-2 and Cbfa-1 immunoexpression, angiogenesis and collagen deposition in osteoporotic rats.

Effect of aluminum oxide-blasted implant surface on the bone healing around implants in rats submitted to continuous administration of selective cyclooxygenase-2 inhibitors.

PURPOSE: The continual use of selective cyclooxygenase-2 (COX-2) inhibitors may have a negative impact on bone repair around titanium implants. Because modified implant surfaces could be considered an important strategy to increase success rates in some conditions that interfere in bone healing, the aim of this study was to investigate whether an aluminum oxide (Al2O3)-blasted implant surface could reduce the negative action promoted by the continuous administration of selective COX-2 inhibitors on bone healing around implants. MATERIALS AND METHODS: Thirty Wistar rats received one titanium implant (machined or Al2O3-blasted surface) in each tibia and were randomly assigned to one of the following groups: saline (n = 14) or meloxicam (n = 16); each was administered daily for 60 days. Bone-to-implant contact (BIC), bone area (BA) within the limits of threads, and bone density (BD) in a zone lateral to the implant were examined in undecalcified sections. RESULTS: The Al2O3-blasted surface resulted in significantly increased BIC in both groups, and meloxicam significantly reduced bone healing around implants (P < .05). For the machined surface, significant differences were observed for BIC (39.48 +/- 10.18; 25.23 +/- 9.29), BA (60.62 +/- 4.09; 42.94 +/- 8.12), and BD (56.31 +/- 3.64; 49.30 +/- 3.15) in the saline and meloxicam groups, respectively. For the Al2O3-blasted surface, data analysis also demonstrated significant differences for BIC (45.92 +/- 11.34; 33.30 +/- 7.56), BA (61.04 +/- 4.39; 44.89 +/- 7.11), and BD (58.77 +/- 2.93; 50.04 +/- 3.94) for the saline and meloxicam groups, respectively. CONCLUSIONS: The Al2O3-blasted surface may increase BIC; however, it does not reverse the negative effects promoted by a selective COX-2 inhibitor on bone healing around implants.

Histochemical demonstration of gamma-glutamyl transpeptidase activity in normal rat cartilage and bone.

The feasibility of histochemical detection of GGT activity in decalcified bone tissue is proved and the activity distribution pattern of GGT in normal rat cartilage and bone is described. The results suggest the association, in this model, between GGT activity and differentiation mechanisms rather than proliferative processes. The fact that GGT activity in adult tissues which are normally GGT negative has been linked to premalignant transformation confers significance to the study of GGT activity in normal tissues. The results contribute to the knowledge of the biological mechanisms in which GGT activity is involved and to the understanding of the behaviour of tissues which can be used as controls in carcinogenesis models.