Bone engineering strategies often exploit modulation of the extracellular environment, including delivery of cell and growth factors to repair and regenerate damaged tissues. During bone healing, the expression of endogenous bone morphogenetic proteins is an essential component of the healing response. However, in some situations, the inherent reparative capacity available in the local microenvironment is exceeded by the requirements of the defects. We have recently reported on a novel strategy, that exploits the specificity of antibodies to capture and make available endogenous osteogenic growth factors, referred to as "antibody-mediated osseous regeneration" (AMOR). The objective of the present study was to identify some of the cellular and molecular events involved in AMOR in an effort to begin to elucidate the mechanism of AMOR. The rat critical-sized calvarial defect model was used, where anti-bone morphogenetic protein (BMP)-2 monoclonal antibody (mAb), isotype-control mAb, or recombinant human (rh)BMP-2 were immobilized on absorbable collagen calvarial sponge (ACS) by adsorption, and then implanted into calvarial defects. The results demonstrated persistence of implanted mAbs for short term from 1 to 2 weeks after implantation. Increased cell infiltration was found in defects treated with anti-BMP-2 mAb. Examination of proteins on ACS scaffolds retrieved from defect sites demonstration increased levels of BMP-2, BMP-4, and BMP-7 proteins in sites implanted with anti-BMP-2 mAb. Moreover, BMP-2, BMP-4, and BMP-7 gene expression levels were increased in sites implanted with anti-BMP-2 mAb. Micro-computed tomography and histological analysis demonstrated that the bone within calvarial defects was fully regenerated in sites implanted with either anti-BMP-2 mAb or rhBMP-2. However, rhBMP-2-regenerated bone exhibited aberrant histomorphology with dystrophic calcification and invasion of subjacent areas. Altogether, the results revealed evidence for anti-BMP-2 mAbs to form an immune complex with BMP-2, BMP-4, and BMP-7, and bind to cells to mediate osteogenesis bone regeneration in vivo. This approach suggests a significant role for antibodies in regenerative orthopedic medicine.
Aim To evaluate the efficacy of a non-thermal plasma (NTP) at atmospheric pressure on ex vivo biofilm in root canals of extracted teeth. Methodology Intra-canal contents from three teeth with root canal infections were collected, pooled, and grown in thirty-five microCT-mapped root canals of extracted and instrumented human teeth. One group of teeth was treated with NTP, another with 6% NaOCl, and one set was left untreated. The intra-canal contents from twenty-seven teeth (nine teeth in each group) were plated on agar and colony forming units were determined. Parametric test of one-way Analysis of Variance (ANOVA) was used to analyze statistical significance. The remaining teeth were cut open, stained with LIVE/DEAD® and examined with confocal laser scanning microscopy. Results The untreated root canals were covered with biofilm of varying thickness. The treatment with the non-thermal plasma decreased the number of viable bacteria in these biofilms by one order of magnitude, while the NaOCl control achieved a reduction of more than four magnitudes. Both the NTP and the NaOCl treatment results were significantly different from the negative control (P< 0.05). Conclusion The non-thermal plasma displayed antimicrobial activity against endodontic biofilms in root canals, but was not as effective as the use of 6 % NaOCl.
Endogenous molecular and cellular mediators modulate tissue repair and regeneration. We have recently described antibody mediated osseous regeneration (AMOR) as a novel strategy for bioengineering bone in rat calvarial defect. This entails application of anti-BMP-2 antibodies capable of in vivo capturing of endogenous osteogenic BMPs (BMP-2, BMP-4, and BMP-7). The present study sought to investigate the feasibility of AMOR in other animal models. To that end, we examined the efficacy of a panel of anti-BMP-2 monoclonal antibodies (mAbs) and a polyclonal Ab immobilized on absorbable collagen sponge (ACS) to mediate bone regeneration within rabbit calvarial critical size defects. After 6 weeks, de novo bone formation was demonstrated by micro-CT imaging, histology, and histomorphometric analysis. Only certain anti-BMP-2 mAb clones mediated significant in vivo bone regeneration, suggesting that the epitopes with which anti-BMP-2 mAbs react are critical to AMOR. Increased localization of BMP-2 protein and expression of osteocalcin were observed within defects, suggesting accumulation of endogenous BMP-2 and/or increased de novo expression of BMP-2 protein within sites undergoing bone repair by AMOR. Considering the ultimate objective of translation of this therapeutic strategy in humans, preclinical studies will be necessary to demonstrate the feasibility of AMOR in progressively larger animal models.
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