Multi-Elemental Profiling of Tibial and Maxillary Trabecular Bone in Ovariectomised Rats.

Atomic minerals are the smallest components of bone and the content of Ca, being the most abundant mineral in bone, correlates strongly with the risk of osteoporosis. Postmenopausal women have a far greater risk of suffering from OP due to low Ca concentrations in their bones and this is associated with low bone mass and higher bone fracture rates. However, bone strength is determined not only by Ca level, but also a number of metallic and non-metallic elements in bone. Thus, in this study, the difference of metallic and non-metallic elements in ovariectomy-induced osteoporosis tibial and maxillary trabecular bone was investigated in comparison with sham operated normal bone by laser ablation inductively-coupled plasma mass spectrometry using a rat model. The results demonstrated that the average concentrations of (25)Mg, (28)Si, (39)K, (47)Ti, (56)Fe, (59)Co, (77)Se, (88)Sr, (137)Ba, and (208)Pb were generally higher in tibia than those in maxilla. Compared with the sham group, Ovariectomy induced more significant changes of these elements in tibia than maxilla, indicating tibial trabecular bones are more sensitive to changes of circulating estrogen. In addition, the concentrations of (28)Si, (77)Se, (208)Pb, and Ca/P ratios were higher in tibia and maxilla in ovariectomised rats than those in normal bone at all time-points. The present study indicates that ovariectomy could significantly impact the element distribution and concentrations between tibia and maxilla.

Effect of ovariectomy on tissue-level changes in rat maxilla.

PURPOSE: It remains unclear whether estrogen deficiency affects the ultrastructure and tissue-level mechanical properties of the maxilla. The hypothesis of this study was that the ovariectomized rat could induce tissue-level changes of the maxilla. MATERIALS AND METHODS: Twelve 3-month-old female Sprague Dawley rats were acquired and randomly divided into two groups: ovariectomized and SHAM (control) (n = 6 for each group). Three months after the ovariectomy, implants were placed; the animals were sacrificed at day 28, and then samples were collected and prepared according to the previously established protocols. Advanced analytical equipment including scanning electron microscope with energy-dispersive spectrometry, transmission electron microscope, and nanoindentation were used to analyze bone quality. RESULTS: The results showed that the mature bone areas in the ovariectomized group were significantly affected in the mineral crystal and the microstructure. The micro-mechanical properties of the mature bone were also affected, showing significantly increased hardness (H) and reduced modulus (Er) in ovariectomized rats compared with the normal rats (P < .05). Differences in H and Er in new bone areas between the normal and ovariectomized rats were less significant. CONCLUSION: Ovariectomy affected maxilla bone tissue-level quality; however, the effects mainly existed in the mature bone areas, which were characterized by higher crystalline mineralization, hardness, and modulus.

The role of organic phosphate in the spatial control of periodontium complex bio-mineralization: an in vitro study.

The periodontal structure is a particularly exquisite model of hierarchical spatial control of mineralization. Extracellular matrix control in the selective mineralization of the periodontium complex remains elusive since the extracellular matrix is a set of mineralization promoters and inhibitors. The phosphorylated proteins, which are ubiquitous in the extracellular matrix of the periodontium complex, are well-documented as primary factors in the regulation of tissue mineralization. Whether organic phosphates are key regulators in defining the interfaces between dentin, cementum, periodontal ligament and alveolar bone is an issue worthy of research. Here, we investigated the in vitro remineralization process of demineralized and dephosphorylated periodontal tissue sections. When exposed to a metastable mineralization solution, a large number of calcospherulites deposited on the surface of the dephosphorylated sections and the tissue selective mineralization were disrupted. Interestingly, on adding a dentin matrix protein-1 analogue named polyacrylic acid, the surface mineralization rate in the dephosphorylated periodontal complex reduced dramatically. In contrast, hierarchical mineralization was displayed by the demineralized section at the tissue collagen fibrillar levels in both alveolar bone and dentin regions. These results demonstrated that the organic phosphate could prevent surface mineral deposition, and the minerals could penetrate the collagen fibrils to initiate a selective and hierarchal tissue mineralization with the assistance of the dentin matrix protein-1 analogue in the periodontal complex. This study enhances our understanding of the mineralization discrepancy in the periodontal tissues, which will provide some insight into the development of biomaterials for the regeneration of soft-hard tissue interfaces.

The osteoimmunomodulatory property of a barrier collagen membrane and its manipulation via coating nanometer-sized bioactive glass to improve guided bone regeneration.

A barrier membrane is a major component of guided bone regeneration (GBR), which is traditionally viewed as a physical barrier. Due to its "foreign body" nature, the implantation of a barrier membrane would inevitably modulate immune response and subsequently affect bone dynamics, which has long been neglected. To bridge this knowledge gap, we investigated the osteoimmunomodulatory effects of barrier collagen membranes. It is found that barrier collagen membranes elicit significant effects on modulating the osteoimmune response of macrophages, by upregulating the expression of pro-inflammatory cytokines (TNFα, IL-1ß, IL-6, and IL-18) and osteogenic factors (BMP2/6, WNT10b, OSM). The modulated-osteoimmune environment was beneficial for the osteogenic differentiation of BMSCs, due to the activation of BMP, canonical WNT/ß-catenin, and OSM signalling pathways. The membrane-mediated osteoimmunomodulation was further modulated to show whether osteogenesis could be enhanced via manipulating the membrane-mediated osteoimmunomodulation. The membrane-mediated osteoimmune response was successfully tuned through coating the collagen membranes with nanometer-sized bioactive glass Ca2ZnSi2O7 by pulsed laser deposition, which is indicated from the change in the expression profile of inflammatory cytokines and the upregulated expression of osteogenic factors. The modulated osteoimmune environment enhanced the osteogenic differentiation of BMSCs, suggesting that collagen membranes with nanometer-sized Ca2ZnSi2O7 coating can be promising for GBR applications. These results collectively imply that barrier membranes are bioactive barriers with an osteoimmunomodulatory effect and not just physical barriers. New generation barrier membranes should be designed with a favourable osteoimmunomodulatory property.