Effect of recombinant PDGF-BB on bone formation in the presence of ß-tricalcium phosphate and bovine bone mineral matrix: a pilot study in rat calvarial defects.

BACKGROUND: Supplementation of bone substitutes with recombinant platelet-derived growth factor-BB (PDGF-BB) can enhance bone regeneration. The aim of the study was to evaluate the effect of PDGF-BB on bone formation in the presence of ß-tricalcium phosphate and bovine bone mineral matrix in a rat calvaria defect model. METHODS: The authors examined 5 mm rat calvarial defects treated with ß-tricalcium phosphate (TCP) or demineralized bovine bone mineral (DBBM) with and without 0.3 mg/ml recombinant PDGF-BB. Calvaria defects were randomly divided into the following treatment groups (n = 5); TCP; TCP plus PDGF-BB; DBBM; DBBM plus PDGF-BB; and untreated empty control. After 45 days, bone formation was evaluated by histomorphometry and fluorescence microscopy. RESULTS: The authors report that the area of newly formed bone was similar between the empty controls and the two bone substitutes, TCP and DBBM. Supplementation of TCP and DBBM with PDGF-BB had no significant impact on bone formation. Fluorochrome staining revealed no visible changes in the pattern of bone formation in defects filled with TCP and DBBM, irrespective of PDGF-BB. Furthermore, supplementation with PDGF-BB did not influence biomaterial degradation. CONCLUSIONS: The authors concluded that PDGF-BB had no impact on bone formation and degradation of bone substitutes in the respective rodent models. Thus, possible beneficial effects of PDGF-BB may require other model situations.

Impact of dietary vitamin D on osseointegration in the ovariectomized rat.

AIM: Vitamin D deficiency is highly prevalent in the population and associated with impaired peri-implant bone regeneration. Yet, there is a gap in understanding the impact of vitamin D supplementation on the process of osseointegration. In this study, the effect of vitamin D supplementation on peri-implant bone regeneration was investigated. METHODS: Fifty ovariectomized Sprague-Dawley rats were divided into three groups. The depletion group was fed a vitamin D-free diet for 8 weeks. The repletion group received vitamin D-free diet for 6 weeks, before animals were switched to standard diet containing 2400 IU/kg vitamin D. The control group was fed the standard diet. Two titanium mini-implants were placed in the tibia. All groups remained on their previous diet until sacrifice. Blood sample testing and histomorphometric analysis were performed. RESULTS: Vitamin D depletion caused a significant reduction in 25-hydroxvitamin D in rat serum that returned to control levels in the repletion group. This vitamin deficiency was associated with a decrease in bone-to-implant contact in the cortical area, which was leveled to controls in the repletion group. No significant changes by vitamin D depletion were noticed in the medullar compartment. Moreover, also the peri-implant bone area and the mineral apposition rate remained unchanged upon vitamin D depletion. CONCLUSION: These results indicate that vitamin D deficiency has a negative impact on cortical peri-implant bone formation in ovariectomized rats, which can be compensated by vitamin D supplementation. This study provides first insight into the potential beneficial effect of vitamin D supplementation in implant dentistry.

The effect of BMP-2 on the osteoconductive properties of ß-tricalcium phosphate in rat calvaria defects.

Bone formation in critical-sized calvaria defects is strongly dependent on the osteoconductive properties of grafts. It remains a matter of controversy whether biomaterials can replace autografts and whether the supplementation of biomaterials with Bone Morphogenetic Proteins (BMPs) is necessary to enhance bone formation. We examined rat calvaria critical-sized defects (5-mm-diameter) treated with ß-tricalcium phosphate (TCP; Cerasorb® M), polylactic and polyglycolic acid gel (PLA/PGA; Fisiograft®) and calcium phosphate cement (CPC; Norian® CRS®), either alone or in the presence of 5 µg of BMP-2 after 45 days. Autografts and untreated defects served as controls. Bone formation was evaluated based on µCT analysis, histomorphometric analysis and fluorescence analysis. We report that TCP supported bone formation more efficiently than did autografts. Bone formation in the presence of TCP alone reached a maximal level, as BMP-2 supplementation failed to enhance bone formation. By contrast, no significant difference in bone formation was observed when PLA/PGA and CPC were compared to autografts. Moreover, the presence of BMP-2 did not substantially change the osteoconductive properties of PLA/PGA or CPC. We conclude that the osteoconductive properties of TCP are superior to those of autografts and that TCP does not require BMP-2 supplementation. Our findings also show that the decreased osteoconductive properties of PLA/PGA and CPC cannot be overcome by BMP-2 supplementation in rat calvaria defects.

Paste-like inorganic bone matrix: preclinical testing of a prototype preparation in the porcine calvaria.

OBJECTIVE: To evaluate the osteoconductive properties and the volume stability of an injectable paste-like inorganic bone matrix (PBM) in porcine calvaria defects. MATERIAL AND METHODS: We created six circumferential defects in the calvaria of 12 adult iberico pigs. The defects were filled with either PBM, Bio-Oss((R)) of different particle size, carrier alone, or left empty. PBM was composed of Bio-Oss((R)) with a particle size ranging from 250 to 500 mum and a hydrogel-carrier of carboxymethylcellulose and collagen. After 6 and 12 weeks of healing, the animals were sacrificed and undecalcified ground sections were prepared and subjected to histologic and histomorphometric analysis. To quantify the osteoconductive properties of PBM, bone volume per tissue volume (BV/TV) in the defect area was determined. To determine the volume stability, bone substitute volume per tissue volume (BSV/TV) was measured. RESULTS: After 6 weeks, PBM particles in the center of the defect were surrounded by fibrous connective tissue, which was later replaced by bone. BV/TV in the PBM group increased from 29.7+/-12.7% (minimum 12.2%, maximum 43.7%) after 6 weeks to 43.9+/-14.9% (minimum 27.8%, maximum 63.9%) after 12 weeks (Mann-Whitney test; P=0.6). According to the Friedman test, BV/TV in groups containing Bio-Oss((R)) of different particle sizes, the carrier and the empty defects was similar to the results obtained with PBM (6 weeks P=0.8; 12 weeks P=0.22). BSV/TV in the PBM group was stable over time, with 10.1+/-9% (minimum 3.3%, maximum 27.6%) and 16.5+/-12.9% (minimum 1%, maximum 32.7%), after 6 and 12 weeks, respectively (P=0.72). BSV/TV in the PBM group was comparable to the results obtained with the Bio-Oss((R)) particles of different sizes (Friedman test; 6 weeks P=0.0503; 12 weeks P=0.56). CONCLUSIONS: The results of this preclinical study showed that the PBM is osteoconductive and maintains the augmented volume, similar to commercial Bio-Oss((R)). These data suggest that the osteoconductive properties of Bio-Oss((R)) are maintained at the smaller particle size and in the presence of the carrier.

Influence of low-level laser treatment on bone regeneration and osseointegration of dental implants following sinus augmentation. An experimental study on sheep.

OBJECTIVES: The aim of this experimental study was to evaluate if low-level laser treatment (LLLT) enhances bone regeneration and osseointegration of dental implants in a sinus graft model. MATERIAL AND METHODS: Twelve sheep underwent a bilateral sinus floor elevation procedure with cancellous bone from the iliac crest. Implant insertion followed 4 weeks (six sheep) and 12 weeks (six sheep) later. Sixteen weeks after second-stage surgery, animals were sacrificed. Unilaterally, the grafted sinus and during the second-stage surgery the implant sites were irradiated intraoperatively and three times during the first postoperative week with a diode laser (75 mW, 680 nm). The overall energy density per irradiation was 3-4 J/cm(2). Biopsies of the augmented area were obtained during implant insertion and after scarification. RESULTS: Bone regeneration within the grafted sinus histomorphometric analysis hardly differed between control and test side both 4 and 12 weeks after sinus grafting. Osseointegration measurements resulted in a significantly higher bone/implant contact (BIC) on the test side (P=0.045). Further evaluation of peri-implant bone tends to amount in significant higher percentage on the laser side (P=0.053). CONCLUSION: The presented experimental study on sheep did not confirm a positive LLLT effect on bone regeneration within a cancellous sinus graft. Nevertheless, LLLT possibly has a positive effect on osseointegration of dental implants inserted after sinus augmentation.

Bone formation following sinus grafting with autogenous bone-derived cells and bovine bone mineral in minipigs: preliminary findings.

Bone formation in a sinus grafted with a cell-free scaffold requires the presence of local progenitor cells that differentiate into osteoblasts. The purpose of this study was to examine the effect of culture expanded autogenous bone-derived cells (ABC) with bovine bone mineral (BBM) on bone formation after single-stage sinus grafting in minipigs. Bone biopsies from the iliac crest were harvested 4 weeks prior to sinus grafting and ABC were culture expanded in vitro. The sinuses of five adult minipigs were grafted. In one sinus of each minipig the space between Schneider's membrane (SM) and the sinus wall was grafted with ABC (325,000 cells per sinus, on average) and BBM. In the other sinus, BBM alone was used. The animals were sacrificed after 12 weeks. One block of each grafted area was prepared by saw cutting and the amount of newly formed bone was analysed by micro-computed tomography (mu-CT). The addition of ABC to BBM significantly increased the amount of newly formed bone compared with BBM alone on mu-CT analysis (ABC+BBM: 29.86+/-6.45% vs. BBM: 22.51+/-7.28% (P=0.016)). Bone formation was increased near SM (ABC+BBM: 20.7+/-4.5% vs. BBM: 15.43+/-3.62% (P=0.009)) and in the middle zone of the grafting material (ABC+BBM: 31.63+/-7.74% vs. BBM: 22.5+/-7.91% (P=0.001)), but not near the local host bone (ABC+BBM: 37.23+/-8.23% vs. BBM: 28.42+/-12.54% (P=0.15)). These preliminary findings indicate that supplementation of cell-free grafting material with culture expanded ABC can stimulate bone formation in areas with low bone-forming capacity.