Development of bone-like composites via the polymer-induced liquid-precursor (PILP) process. Part 1: Influence of polymer molecular weight

Bone is an organic–inorganic composite consisting primarily of collagen fibrils and hydroxyapatite crystals intricately interlocked to provide skeletal and metabolic functions. Non-collagenous proteins (NCPs) are also present, and although only a minor component, the NCPs are thought to play an important role in modulating the mineralization process. During secondary bone formation, an interpenetrating structure is created by intrafibrillar mineralization of the collagen matrix. Many researchers have tried to develop bone-like collagen–hydroxyapatite (HA) composites via the conventional crystallization process of nucleation and growth. While those methods have been successful in inducing heterogeneous nucleation of HA on the surface of collagen scaffolds, they have failed to produce a composite with the interpenetrating nanostructured architecture of bone. Our group has shown that intrafibrillar mineralization of type I collagen can be achieved using a polymer-induced liquid-precursor (PILP) process. In this process, acidic polypeptides are included in the mineralization solution to mimic the function of the acidic NCPs, and in vitro studies have found that acidic peptides such as polyaspartate induce a liquid-phase amorphous mineral precursor. Using this PILP process, we have been able to prepare collagen–HA composites with the fundamental nanostructure of bone, wherein HA nanocrystals are embedded within the collagen fibrils. This study shows that through further optimization a very high degree of mineralization can be achieved, with compositions matching that of bone. Synthetic collagen sponges were mineralized with calcium phosphate while analyzing various parameters of the reaction, with the focus of this report on the molecular weight of the polymeric process-directing agent. In order to determine whether intrafibrillar mineralization was achieved, an in-depth characterization of the mineralized composites was performed, including wide-angle X-ray diffraction, electron microscopy and thermogravimetric analyses. The results of this work lead us closer to the development of bone-like collagen–HA composites that could become the next generation of synthetic bone grafts.     

Multifunctional role of osteopontin in directing intrafibrillar mineralization of collagen and activation of osteoclasts

Mineralized collagen composites are of interest because they have the potential to provide a bone-like scaffold that stimulates the natural processes of resorption and remodeling. Working towards this goal, our group has previously shown that the nanostructure of bone can be reproduced using a polymer-induced liquid-precursor (PILP) process, which enables intrafibrillar mineralization of collagen with hydroxyapatite to be achieved. This prior work used polyaspartic acid (pASP), a simple mimic for acidic non-collagenous proteins, to generate nanodroplets/nanoparticles of an amorphous mineral precursor which can infiltrate the interstices of type-I collagen fibrils. In this study we show that osteopontin (OPN) can similarly serve as a process-directing agent for the intrafibrillar mineralization of collagen, even though OPN is generally considered a mineralization inhibitor. We also found that inclusion of OPN in the mineralization process promotes the interaction of mouse marrow-derived osteoclasts with PILP-remineralized bone that was previously demineralized, as measured by actin ring formation. While osteoclast activation occurred when pASP was used as the process-directing agent, using OPN resulted in a dramatic effect on osteoclast activation, presumably because of the inherent arginine–glycine–aspartate acid ligands of OPN. By capitalizing on the multifunctionality of OPN, these studies may lead the way to producing biomimetic bone substitutes with the capability of tailorable bioresorption rates.     

Morphology of the osteonal cement line in human bone

While current consensus suggests the absence of collagen in osteonal cement lines, the extent of cement line mineralization and the nature of the ground substance within the cement line are unclear. Samples of human radius were examined by using scanning electron microscopy, electron microprobe, and histochemical techniques. X-ray intensities were used to compare the amount of calcium, phosphorus, and sulfur in cement lines with amounts in surrounding lamellar bone. The results indicate that cement lines contain significantly less calcium and phosphorus, but significantly more sulfur, than surrounding bone matrix. The Ca/P ratio of cement lines was significantly greater than that of lamellar bone, suggesting that the mineral in cement lines may not be in the form of mature hydroxyapatite. No selective staining of the cement lines could be demonstrated by using periodic acid-Schiff, Sudan black B, or alcian blue critical electrolyte concentration techniques.     

Early bone apposition in vivo on plasma-sprayed and electrochemically deposited hydroxyapatite coatings on titanium alloy

Three different implants, bare Ti-6Al-4V alloy, Ti-6Al-4V alloy coated with plasma-sprayed hydroxyapatite (PSHA), and Ti-6Al-4V alloy coated with electrochemically deposited hydroxyapatite (EDHA), were implanted into canine trabecular bone for 6 h, 7, and 14 days, respectively. Environmental scanning electron microscopy study showed that PSHA coatings had higher bone apposition ratios than those exhibited by bare Ti-6Al-4V and EDHA coatings after 7 days; however, at 14 days after implantation, EDHA and PSHA coatings exhibited similar bone apposition ratios, much higher than that for bare Ti-6Al-4V. The ultrastructure of the bone/implant interface observed by transmission electron microscope showed that the earliest mineralization (6 h-7 days) was in the form of nano-ribbon cluster mineral deposits with a Ca/P atomic ratio lower than that of hydroxyapatite. Later-stage mineralization (7-14 days) resulted in bone-like tissue with the characteristic templating of self-assembled collagen fibrils by HA platelets. Though adhesion of EDHA coatings to Ti-6Al-4V substrate proved problematical and clearly needs to be addressed through appropriate manipulation of electrodepositon parameters, the finely textured microstructure of EDHA coatings appears to provide significant advantage for the integration of mineralized bone tissue into the coatings.     

Preparation of bone-like apatite-collagen nanocomposites by a biomimetic process with phosphorylated collagen

By imitating in vivo bone mineralization, bone-like apatite-collagen nanocomposites were prepared by chemical phosphorylation of collagen and subsequent biomimetic growth of bone-like nanoapatite on collagen nanofibers. Two steps were employed in the composites preparation. First, the collagen was phosphorylated by chemical treatment, which provides the nucleation sites for bone-like apatite mineralization. The subsequent growth of bone-like nanoapatite on the phosphorylated collagen nanofibers was performed in simulated body fluid (SBF). The characterization of the composites showed that the composites were composed of nanoapatite mineralized collagen nanofibers that exhibit similarity to natural bone in composition and crystal morphology.     

纳米羟基磷灰石前体与胶原自组装成类骨质复合材料的表征

文题释义： 纳米羟基磷灰石前体：纳米羟基磷灰石的悬浮液,制备方程为10Ca(NO₃)₂+6(NH₄)₂HPO₄+8NH₃•H₂O=Ca₁₀(PO₄)₆(OH)₂+ 20NH₄NO₃+6H₂O,反应时pH值10左右,反应完成后静置、洗涤,得到pH值8.0-9.0的纳米羟基磷灰石悬浮液。 自组装：是指基本的结构单元(分子、纳米材料、微米或更大尺度的物质)自发形成有序结构的一种技术。自组装过程中,基本结构单元在非共价键的相互作用下自发的成为一个稳定、外观具有一定规则的结构。 背景：制作类似于天然骨的材料来修复骨缺损,或者作为组织工程支架材料是研究的热点。 目的：探讨以纳米羟基磷灰石的前体及胶原为材料自组装成类骨质复合材料的可行性。 方法：将胶原材料分别浸泡于0.25%戊二醛溶液中0.5 h(A组),24 h(B组),72 h(C组)进行交联反应,D组将胶原浸泡于碳化二亚胺中交联4 h,将交联后的各组胶原浸泡于纳米羟基磷灰石前体溶液中7 d,制备类骨质复合材料。分析各组复合材料与天然骨的矿化物物相分析、组成成分及微观结构。 结果与结论：①X射线衍射分析：复合材料的非晶象衍射峰稍高于天然骨,各组复合物中非晶象变化不明显;随戊二醛交联时间的延长,材料晶体峰值有增高趋势;碳化二亚胺交联后材料的晶体衍射峰值较戊二醛交联材料稍低;②傅里叶转换红外光谱分析：复合材料的化学组成与天然骨的组成相似,都是由胶原和羟基磷灰石组成,其中羟基磷灰石中部分PO₄^3-被CO₃^2-离子取代;不同交联方法对材料无机相改变的影响差别不明显;③扫描电镜：胶原的不同交联方法对所形成晶体的形貌影响不明显：胶原纤维互相缠绕,其上有大量的细针样晶体沉积,聚成团,晶体分布均匀,晶体尺寸是纳米量级;④结果表明,以纳米羟基磷灰石前体及胶原为材料可制作自组装成类骨质复合材料。 ORCID: 0000-0003-1620-3673(张雪梅) 中国组织工程研究杂志出版内容重点：生物材料;骨生物材料; 口腔生物材料; 纳米材料; 缓释材料; 材料相容性;组织工程     

Porous beta-tricalcium phosphate/collagen composites prepared in an alkaline condition

Bone substitute materials with natural bone-like structure are considered to be favorable for bone regeneration. In this work, porous beta-tricalcium phosphate (beta-TCP)/collagen composite consisting of bone-like microstructural units was prepared using nanosized beta-TCP particles and alkaline-disassembled collagen. The resulting composite showed a good interconnecting porous structure with approximately 90% porosity and 100 approximately 300 microm pore size. The pore walls were dense, and the combination status of collagen and nanosized beta-TCP particles demonstrated that nanosized beta-TCP particles tightly connected collagen microfibrils as a bone-like microstructural unit. MTT and alkaline phosphatase (ALP) assays showed that the porous composite had enhanced effects on cellular proliferation and activity of osteoblast compared with a control of pure collagen. It is suggested that the adoption of nanosized beta-TCP particles is a main contribution to the formation of the composite with a bone-like microstructural unit, and the unique microstructure could be a main role for the composite to have the positive influence on osteoblast cell proliferation.     

Hydroxyapatite grafting promotes new bone formation and osseointegration of smooth titanium implants

Titanium is the ideal metal for intra-osseous dental implants. It permits the natural formation of an oxide layer on its surface and thereby it prevents the release of potentially toxic molecules. New formation of bone around implants, partially placed into the bone marrow cavity, is a gradual process that runs from the endosteum to the surface of the implant. Deposition of hydroxyapatite crystals on collagen type I fibrils is initiated by acidic proteins and leads to bone mineralization. This study analyzed the effects of hydroxyapatite upon peri-implant bone formation after insertion of smooth titanium implants. Screw-shaped smooth titanium implants of 3.75 mm thickness and 8.5 mm length were inserted into the metaphysis of rabbit tibia, either together with bovine hydroxyapatite into the right tibia or in controls without hydroxyapatite into the left tibia. Polyfluorochrome tracers (alizarin complex, calcein, tetracycline) were injected subcutaneously at different time intervals after implantation to evaluate the time frame of bone new formation over a period of 8 weeks. All samples were processed for histology and analyzed by fluorescence and polarizing microscopy. Our results showed a higher quantity of mature type I collagen fibers around implants and an acceleration of bone formation in the presence of hydroxyapatite. Mainly immature organic matrix was formed at the surface of implants in controls. The presence of hydroxyapatite seems to promote the maturation of collagen fibers surrounding the titanium implants and to support osteoconduction. Moreover, new formation of bone was faster in all samples where implants were inserted together with hydroxyapatite.     

Engineering bone-like tissue in vitro using human bone marrow stem cells and silk scaffolds

Porous biodegradable silk scaffolds and human bone marrow derived mesenchymal stem cells (hMSCs) were used to engineer bone-like tissue in vitro. Two different scaffolds with the same microstructure were studied: collagen (to assess the effects of fast degradation) and silk with covalently bound RGD sequences (to assess the effects of enhanced cell attachment and slow degradation). The hMSCs were isolated, expanded in culture, characterized with respect to the expression of surface markers and ability for chondrogenic and osteogenic differentiation, seeded on scaffolds, and cultured for up to 4 weeks. Histological analysis and microcomputer tomography showed the development of up to 1.2-mm-long interconnected and organized bonelike trabeculae with cuboid cells on the silk-RGD scaffolds, features still present but to a lesser extent on silk scaffolds and absent on the collagen scaffolds. The X-ray diffraction pattern of the deposited bone corresponded to hydroxyapatite present in the native bone. Biochemical analysis showed increased mineralization on silk-RGD scaffolds compared with either silk or collagen scaffolds after 4 weeks. Expression of bone sialoprotein, osteopontin, and bone morphogenetic protein 2 was significantly higher for hMSCs cultured in osteogenic than control medium both after 2 and 4 weeks in culture. The results suggest that RGD-silk scaffolds are particularly suitable for autologous bone tissue engineering, presumably because of their stable macroporous structure, tailorable mechanical properties matching those of native bone, and slow degradation.     

Identifying compositional and structural changes in spongy and subchondral bone from the hip joints of patients with osteoarthritis using Raman spectroscopy

Raman microspectroscopy was used to examine the biochemical composition and molecular structure of extracellular matrix in spongy and subchondral bone collected from patients with clinical and radiological evidence of idiopathic osteoarthritis of the hip and from patients who underwent a femoral neck fracture, as a result of trauma, without previous clinical and radiological evidence of osteoarthritis. The objectives of the study were to determine the levels of mineralization, carbonate accumulation and collagen quality in bone tissue. The subchondral bone from osteoarthritis patients in comparison with control subject is less mineralized due to a decrease in the hydroxyapatite concentration. However, the extent of carbonate accumulation in the apatite crystal lattice increases, most likely due to deficient mineralization. The alpha helix to random coil band area ratio reveals that collagen matrix in subchondral bone is more ordered in osteoarthritis disease. The hydroxyapatite to collagen, carbonate apatite to hydroxyapatite and alpha helix to random coil band area ratios are not significantly changed in the differently loaded sites of femoral head. The significant differences also are not visible in mineral and organic constituents' content in spongy bone beneath the subchondral bone in osteoarthritis disease.     

Beads of collagen-nanohydroxyapatite composites prepared by a biomimetic process and the effects of their surface texture on cellular behavior in MG63 osteoblast-like cells

The aim of this work was to develop a novel method for preparing a three-dimensional bone-like matrix comprising nanohydroxyapatite crystals and fibrous collagen and to apply it for bone tissue engineering. Hydroxyapatite and collagen are the major components of natural hard bone. Therefore, they have been used extensively in orthopedic surgery as bone-filling materials. According to the principle of complex coacervation, three-dimensional collagen beads can be formed by extruding collagen solution into chondroitin sulfate A (CSA) solution. Subsequently, the collagen beads thus formed are soaked in simulated body-fluid solution to biomimic the formation process of natural bone matrix via the fabrication of collagen-nanohydroxyapatite beads. We also investigate the effect of the collagen-nanohydroxyapatite matrix on the proliferation and differentiation of MG63 cells. The presence of crystalline hydroxyapatite structure on the surface of fibrous collagen was confirmed by X-ray diffraction. MG63 cells cultured on the collagen-nanohydroxyapatite beads proliferate at the normal rate. Moreover, alkaline phosphatase (ALP) activity and the expression levels of three osteogenic genes, namely, type I collagen osteopontin and osteocalcin, in MG63 cells were significantly higher when the cells were cultured on collagen-nanohydroxyapatite beads than when they were cultured on collagen alone. The results of this study reveal that, in the presence of nanohydroxyapatite, the three-dimensional cell beads not only provide a substrate for cell growth but could also enhance the osteoblast-like cell differentiation of MG63 cells.     

Effects of crystalline phase on the biological properties of collagen–hydroxyapatite composites

The objective of this study was to investigate the effects of spatial structure and crystalline phase on the biological performance of collagen–hydroxyapatite (Col–HA) composite prepared by biomineralization crystallization. Two types of Col–HA composites were prepared using mineralization crystallization (MC composites) and pre-crystallization (PC composites), respectively. Structural characteristics were analyzed by scanning electron microscopy and transmission electron microscopy. Surface elemental compositions were measured by electron spectroscopy for chemical analysis (ESCA). These composites were used in in vivo repair of bone defects. The effects of the crystalline phase on the biological performance of Col–HA composites were investigated using radionuclide bone scan, histopathology and morphological observation. It was observed that in MC composites, HA was located on the surface of the collagen fibers and aggregated into crystal balls, whereas HA in PC composites was scattered among the collagen fibers. ESCA showed that phosphorus and calcium were 8.99% and 17.56% on MC composite surface, compared with 4.39% and 5.86% on the PC composite surface. In vivo bone defect repair experiments revealed that radionuclide uptake was significantly higher in the area implanted with the PC composite than in the contralateral area implanted with the MC composite. Throughout the whole repair process, the PC composite proved to be superior to the MC composite with regard to capillary-forming capacity and the amount of newly formed bone tissue. So it could be concluded that HA placement on collagen fibers affected the biological performance of Col–HA composites. Pre-crystallization made HA scattered among collagen fibers, creating a better structure for bone defect repair in comparison with MC Col–HA composites.     

Biologically inspired synthesis of bone-like composite: self-assembled collagen fibers/hydroxyapatite nanocrystals

Replacement of bone tissue by graft materials and products of tissue engineering having composition, structure, and biological features that mimic natural tissue is a goal to be pursued. A biomimetic synthesis was performed to prepare new bone-like composites constituted of hydroxyapatite nanocrystals and self-assembled type I collagen fibers. We used a biological inspired approach that proved that the biological systems stored and processed information at the molecular level. Two different methodologies were used: dispersion of synthetic hydroxyapatite in telopeptides free collagen molecules solution and direct nucleation of hydroxyapatite into reconstituted collagen fibers during their assembling. The different preparation techniques were experimented then the composites thoroughly characterized and compared. Composite obtained by direct nucleation showed an intimated interaction of the inorganic and proteic components, which modified the apatitic phase and made its composition, morphology and structure similar to the mineral component of natural bone.     

Preparation and bioactive properties of novel bone-repair bionanocomposites based on hydroxyapatite and bioactive glass nanoparticles

Bionanocomposites based on ceramic nanoparticles and a biodegradable porous matrix represent a promising strategy for bone repair applications. The preparation and bioactive properties of bionanocomposites based on hydroxyapatite (nHA) and bioactive glass (nBG) nanoparticles were presented. nHA and nBG were synthesized with nanometric particle size using sol-gel/precipitation methods. Composite scaffolds were prepared by incorporating nHA and nBG into a porous alginate (ALG) matrix at different particle loads. The ability of the bionanocomposites to induce the crystallization of the apatite phase from simulated body fluid (SBF) was systematically evaluated using X-ray diffraction (XRD), scanning electron microscopy with energy dispersive X-ray analysis, and Fourier transform infrared spectroscopy. Both nHA/ALG and nBG/ALG composites were shown to notably accelerate the process of crystallization and growth of the apatite phase on the scaffold surfaces. For short immersion times in SBF, nBG (25%)-based nanocomposites induced a higher degree of apatite crystallization than nHA (25%)-based nanocomposites, probably due to the more reactive nature of the BG particles. Through a reinforcement effect, the nanoparticles also improve the mechanical properties and stability in SBF of the polymer scaffold matrix. In addition, in vitro biocompatibility tests demonstrated that osteoblast cells are viable and adhere well on the surface of the bionanocomposites. These results indicate that nHA- and nBG-based bionanocomposites present potential properties for bone repair applications, particularly oriented to accelerate the bone mineralization process.     

Three-dimensional engineered bone from bone marrow stromal cells and their autogenous extracellular matrix

Most bone tissue-engineering research uses porous three-dimensional (3D) scaffolds for cell seeding. In this work, scaffold-less 3D bone-like tissues were engineered from rat bone marrow stromal cells (BMSCs) and their autogenous extracellular matrix (ECM). The BMSCs were cultured on a 2D substrate in medium that induced osteogenic differentiation. After reaching confluence and producing a sufficient amount of their own ECM, the cells contracted their tissue monolayer around two constraint points, forming scaffold-less cylindrical engineered bone-like constructs (EBCs). The EBCs exhibited alizarin red staining for mineralization and alkaline phosphatase activity and contained type I collagen. The EBCs developed a periosteum characterized by fibroblasts and unmineralized collagen on the periphery of the construct. Tensile tests revealed that the EBCs in culture had a tangent modulus of 7.5 +/- 0.5 MPa at 7 days post-3D construct formation and 29 +/- 9 MPa at 6 weeks after construct formation. Implantation of the EBCs into rats 7 days after construct formation resulted in further bone development and vascularization. Tissue explants collected at 4 weeks contained all three cell types found in native bone: osteoblasts, osteocytes, and osteoclasts. The resulting engineered tissues are the first 3D bone tissues developed without the use of exogenous scaffolding.     

Effects of pyrophosphate on desmal and endochondral mineralization and TNAP activity in organoid culture

During endochondral and desmal osteogenesis, mineralization of bone and cartilage matrix requires an appropriate solubility product of calcium and phosphate, collagen as a nucleator and deactivation of inhibitors, in order to prevent heterotopic calcification. In the 1960s, Fleisch and coworkers detected pyrophosphate (PPi) as an inhibitor of hydroxyapatite crystal growth, which should be removed by cleavage to tissue non-specific alkaline phosphatase (TNAP) activity. This theory had been established by basic experiments performed with collagen gels and demineralized matrices. In order to investigate the effect of PPi on matrix mineralization in bone and cartilage, calcium content and TNAP activity were measured in organoid cultures of mouse calvarial osteoblasts and limb bud cartilage after treatment with PPi and/or levamisole. In organoid cultures, bone and cartilage develop in a clear histotypical manner. PPi did not induce mineralization. Beta-glycerophosphate (β-GP) and inorganic phosphate (Pi) induced mineralization which could be significantly reduced by PPi. Levamisole, an inhibitor of TNAP, also reduced mineralization; the combination with PPi was additive. TNAP activity was increased after treatment with PPi and levamisole in both osteoblast and cartilage cultures. Mineralization induced by β-GP and Pi decreased TNAP activity in the osteoblast but not in cartilage organoid culture. In this culture system, PPi reduced mineralization as predicted by Fleisch's theory. Indications of cleavage of PPi were indirectly found because inhibition of hydrolysis of PPi by levamisole further reduced mineralization, probably due to the higher amounts of PPi available for binding to hydroxyapatite.     

Synthesis and characterization of collagen-chitosan-hydroxyapatite artificial bone matrix

In this study, a new artificial bone matrix was constructed with collagen and Ca(5)(PO(4))(3)OH (hydroxyapatite/HA) which are the main components of natural bone. To improve the property of the artificial bone matrix, chitosan (CS), a kind of positive charged polysaccharide, was crosslinked into the scaffolds. Solid-liquid phase separation method was used to shape 3D porous structure benefited for cells growing into. The artificial bone matrix was investigated by transmission electron microscopy, scanning electron microscopy, and electron spectroscopy for chemical analysis, etc. for structures and characteristics. And its ability of bone repair was investigated by orthotope bone defect reparation in vivo. The results showed that the artificial bone matrix was a porousscaffold with three-dimension interconnected fiber microstructure. HA particles were dispersed evenly among collagen fiber and CS was modified on the surface of collagen fiber. It was indicated that this artificial bone matrix could be used as a bone substitute with outstanding properties.     

Role of fibrillar structure of collagenous carrier in bone sialoprotein-mediated matrix mineralization and osteoblast differentiation

To investigate the effects of the microstructure of collagenous carriers on the in vivo function of bone sialoprotein (BSP) in mineralization and osteoblast differentiation, we examined the ultrastructure of reconstituted type I collagen (collagen) and heat-denatured collagen (gelatin) and the in vivo responses to purified bone-derived BSP that was implanted with collagen or gelatin into surgically created 8-mm rat calvarial bone defects. Scanning and transmission electron microscopies revealed that the collagen displayed a fine fibrillar structure with interconnecting spaces between the fibrils/fibers, while the gelatin completely lost this unique three-dimensional structure after denaturation. The rates of in vivo release of BSP from the collagen scaffold were significantly lower than those from the gelatin. Collagen-BSP, but not gelatin-BSP, induced early mineral deposition in the matrix of proliferating repair cells in the calvarial defects at approximately 4-7 days after implantation. Expression levels of osteoblast markers, alkaline phosphatase activity and amounts of new bone synthesized in the collagen-BSP treated defects were significantly greater than that in the gelatin-BSP treated defects (p<0.001). The data suggest that the fibrillar microstructure of reconstituted collagen is essential for retaining BSP at a higher concentration within the defects, which enhances BSP-mediated matrix mineralization and osteoblast differentiation during the repair of rat calvarial defects.     

Transmission electron microscopic study of interface between bioactive bone cement and bone: comparison of apatite and wollastonite containing glass-ceramic filler with hydroxyapatite and beta-tricalcium phosphate fillers.

We developed a bioactive bone cement that consists of apatite and wollastonite containing glass-ceramic (AW-GC) powder and bisphenol-a-glycidyl methacrylate (Bis-GMA) based resin. In this study, we made three types of cement (designated AWC, HAC, and TCPC) consisting of either AW-GC, hydroxyapatite (HA), or beta-tricalcium phosphate (beta-TCP) powder as the inorganic filler and Bis-GMA based resin as the organic matrix. These cements were implanted into rat tibiae and cured in situ. Specimens were prepared 1, 2, 4, and 8 weeks after the operation and observed using transmission electron microscopy. Each of the bone cements was in direct contact with the bone. In AWC-implanted tibiae, the uncured surface layer of Bis-GMA based resin was completely filled with newly formed bone-like tissue 2 weeks after implantation. The AW-GC particles were surrounded by bone and were in contact with bone through an apatite layer. No intervening soft tissue was seen. In HAC-implanted tibiae, it took 4 weeks for the uncured layer to completely fill with newly formed bonelike tissue. The HA particles were also in contact with bone through an apatite layer. In TCPC-implanted tibiae, it took 8 weeks for the uncured layer to fill with newly formed bone-like tissue. The new bone that formed on the TCPC was not as dense as that on the AWC or HAC, and an intervening apatite layer was not evident. Results indicated that AWC had higher bioactivity than either HAC or TCPC.     

Hypermineralized Whale Rostrum as the Exemplar for Bone Mineral

Abstract

Although bone is a nanocomposite of mineral and collagen, mineral has been the more elusive component of study. A standard for bone mineral is clearly needed. We hypothesized that the most natural, least-processed bone mineral could be retrieved from the most highly mineralized bone. We therefore studied the rostrum of the toothed whale Mesoplodon densirostris, which has the densest recognized bone. Essential to establishment of a standard for bone mineral is the documentation that the proposed tissue is bone-like in all properties except for its remarkably high concentration of mineral. Transmitted-light microscopy of unstained sections of rostral material shows normal bone morphology in osteon geometry, lacunae concentration, and vasculature development. Stained sections reveal extremely low density of thin collagen fibers in most of the bone, but enrichment of thicker collagen fibers around vascular holes and in a minority of osteons. Field-emission scanning electron microscopy shows the rostrum mostly consists of dense mineral prisms. Most rostral areas have the same chemical–structural features, i.e., Raman spectroscopically dominated by strong bands at ～962 Δcm^–1 and weak bands at ～2940 Δcm^–1. Spectral features indicate that the rostrum is composed mainly of the calcium phosphate mineral apatite and has only about 4 wt.% organic content. The degree of carbonate substitution (～8.5 wt.% carbonate) in the apatite is in the upper range found in most types of bone. We conclude that, despite its enamel-like extraordinarily high degree of mineralization, the rostrum is in all other features bone-like. Its mineral component is the long-sought uncontaminated, unaltered exemplar of bone mineral.