Electrochemical modification of the Ti-15Mo alloy surface in solutions containing ZnO and Zn3(PO4)2 particles.

This paper reports on the plasma electrolytic oxidation (PEO) of titanium alloy Ti-15Mo in baths containing zinc to obtain biomaterials with bacteriostatic and antibacterial properties. The Ti-15Mo surface was oxidised in a 0.1 M Ca(H2PO2)2 bath containing zinc compound particles: ZnO or Zn3(PO4)2. During the PEO process, the applied voltage was 300 V, and the current density was 150 mA∙cm-2. The surface morphology, roughness and wettability were determined. It has been noted that both roughness and wettability of Ti-15Mo alloy surface increased after PEO. EDX and XPS chemical composition analysis was carried out, and Raman spectroscopy was also performed indicating that Zn has been successfully incorporated into oxide layer. To investigate the antibacterial properties of the PEO oxide coatings, microbial tests were carried out. The bacterial adhesion test was performed using four different bacterial strains: reference Staphylococcus aureus (ATCC 25923), clinical Staphylococcus aureus (MRSA 1030), reference Staphylococcus epidermidis (ATCC 700296) and clinical Staphylococcus epidermidis (15560). Performed zinc-containing oxide coatings did not indicate the bacteria growth inducing effect. Additionally, the cytocompatibility of the formed oxide layers was characterised by MG-63 osteoblast-like live/dead tests. The surface bioactivity and cytocompatibility increased after the PEO process. The zinc was successfully incorporated into the titanium oxide layer. Based on the obtained results of the studies, it can be claimed that zinc-containing PEO layers can be an interesting course of bacteriostatic titanium biomaterials development.

Woven bone overview: structural classification based on its integral role in developmental, repair and pathological bone formation throughout vertebrate groups.

Cortical bone development is characterised by initial formation of woven bone followed by deposition of lamellar bone on the woven scaffold. This occurs in normal bone formation as an integral obligate self-assembly pattern throughout all vertebrate groups, with specific temporal and spatial features. It also occurs in repair bone, modified by the biophysical/mechanical environment, and in pathological bone, modified by the specific disorder and its severity. Two spatially distinct osteoblast cell populations synthesise woven and lamellar bone: mesenchymal osteoblasts surround themselves circumferentially with collagen in a random array to form woven bone; surface osteoblasts align themselves in a linear array on the woven bone surface (or adjacent lamellar bone) to synthesise parallel-fibred lamellar bone. Four specific stages of woven bone formation are defined: stage I, early differentiation of pre-osteoblasts from undifferentiated mesenchymal cells; stage II, mesenchymal osteoblasts surrounding themselves in a 360° arc with randomly oriented matrix fibres; stage III, woven matrix acting as a scaffold on which surface osteoblasts begin to synthesise bone in parallel-fibred lamellar conformation; stage IV, progressive relative diminution of woven bone in the woven bone/lamellar bone complex. Stages II and IV are further subdivided (in a, b and c) by shifting cell area/matrix area and woven bone/lamellar bone relationships. The under-appreciated biological significance of woven bone is that it initiates formation de novo at sites of no previous bone. This information allows for targeted assessment of molecular-biophysical mechanisms underlying woven bone formation and their utilisation for initiating enhanced bone formation.

Influence of Calcium Supplementation against Fluoride-Mediated Osteoblast Impairment in Vitro: Involvement of the Canonical Wnt/ß-Catenin Signaling Pathway.

Fluoride (F) is capable of promoting abnormal proliferation and differentiation in primary cultured mouse osteoblasts (OB cells), although the underlying mechanism responsible remains rare. This study aimed to explore the roles of wingless and INT-1 (Wnt) signaling pathways and screen appropriate doses of calcium (Ca2+) to alleviate the sodium fluoride (NaF)-induced OB cell toxicity. For this, we evaluated the effect of dickkopf-related protein 1 (DKK1) and Ca2+ on mRNA levels of wingless/integrated 3a (Wnt3a), low-density lipoprotein receptor-related protein 5 (LRP5), dishevelled 1 (Dv1), glycogen synthase kinase 3ß (GSK3ß), ß-catenin, lymphoid enhancer binding factor 1 (LEF1), and cellular myelocytomatosis oncogene (cMYC), as well as Ccnd1 (Cyclin D1) in OB cells challenged with 10-6 mol/L NaF for 24 h. The demonstrated data showed that F significantly increased the OB cell proliferation rate. Ectogenic 0.5 mg/L DKK1 significantly inhibited the proliferation of OB cells induced by F. The mRNA expression levels of Wnt3a, LRP5, Dv1, LEF1, ß-catenin, cMYC, and Ccnd1 were significantly increased in the F group, while significantly decreased in the 10-6 mol/L NaF + 0.5 mg/L DKK1 (FY) group. The mRNA expression levels of Wnt3a, LRP5, ß-catenin, and cMYC were significantly decreased in the 10-6 mol/L NaF + 2 mmol/L CaCl2 (F+CaII) group. The protein expression levels of Wnt3a, Cyclin D1, cMYC, and ß-catenin were significantly increased in the F group, whereas they were decreased in the F+CaII group. However, the mRNA and protein expression levels of GSK3ß were significantly decreased in the F group while significantly increased in the F+CaII group. In summary, F activated the canonical Wnt/ß-catenin pathway and changed the related gene expression and ß-catenin protein location in OB cells, promoting cell proliferation. Ca2+ supplementation (2 mmol/L) reversed the expression levels of genes and proteins related to the canonical Wnt/ß-catenin pathway.

Identification and characterization of human bone-derived cells.

This study was designed to identify and characterize primary bone-derived cells (BdCs) and investigate the potential role of osteoblast differentiation. Primary BdCs were isolated from surgical bone for comparative analysis with mesenchymal stem cells (MSCs) and fetal osteoblasts (FOBs) and for potential differentiation to mature osteoblasts. Using three different cells, we successfully cultivated human osteoblast differentiation and activity which were evaluated using microarray and biochemical methods. BdCs are more correlated to MSCs in bioinformatics result and similar with FOBs in gene expression. In particular, Osterix, osteoprogenitor marker, was high expressed in BdCs, while the expression in MSCs and FOBs were very low. Furthermore, BdCs exhibited a marked alkaline phosphatase (ALP) expression, early stage of osteogenic marker, and retained osteogenic properties and physiological changes into maturation as in FOBs. BdCs also showed an increase in bone morphogenic protein 2 (BMP2), osteopontin (OPN), and osteocalcin (OCN) mRNA expressions during differentiation. This study suggests that BdCs may be osteoprogenitor cells or undifferentiated preosteoblasts with strong capacity to differentiate toward mature osteoblasts.

Mechanical phenotyping of primary human skeletal stem cells in heterogeneous populations by real-time deformability cytometry.

Skeletal stem cells (SSCs) are a sub-population of mesenchymal stromal cells (MSCs) present in bone marrow with multipotent differentiation potential. A current unmet challenge hampering their clinical translation remains the isolation of homogeneous populations of SSCs, in vitro, with consistent regeneration and differentiation capacities. Cell stiffness has been shown to play an important role in cell separation using microfluidic techniques such as inertial focusing or deterministic lateral displacement. Here we report that the mechanical properties of SSCs, and of a surrogate human osteosarcoma cell line (MG-63), differ significantly from other cell populations found in the bone marrow. Using real-time deformability cytometry, a recently introduced method for cell mechanical characterization, we demonstrate that both MG-63 and SSCs are stiffer than the three primary leukocyte lineages (lymphocytes, monocytes and granulocytes) and also stiffer than HL-60, a human leukemic progenitor cell line. In addition, we show that SSCs form a mechanically distinct sub-population of MSCs. These results represent an important step towards finding the bio-physical fingerprint of human SSCs that will allow their label-free separation from bone marrow with significant physiological and therapeutic implications.

Atividade de novos derivados de tiazolidinodionas sobre a diferenciação de pré-osteoblastos e pré-adipócitos / Activity of new derivatives of thiazolidinediones on differentiation of preosteoblasts and preadipocytes

As tiazolidinodionas (TZDs) são sensibilizadores de insulina utilizados no tratamento do diabetes mellitus tipo 2. Contudo, apesar dos efeitos benéficos sobre a glicemia, importantes efeitos adversos incluindo perda óssea e aumento de adiposidade são relatados com o uso clínico das TZDs. Assim, é necessário o desenvolvimento de novos derivados de TZDs com potenciais efeitos benéficos sobre a hiperglicemia e menos efeitos adversos. Neste estudo, investigamos os efeitos de 5 novos derivados de TZDs (LYSO-7, GQ-89, GQ-150, GQ-177 e SF-3) sobre a diferenciação celular de pré-osteoblastos murinos MC3T3-E1, pré-adipócitos murinos 3T3-L1 e pré-adipócitos SGBS de linhagem humana. Seus potenciais efeitos sobre a utilização de glicose, a produção de adipocinas e mediadores pró-inflamatórios também foram avaliados, utilizando linhagens murinas e humanas de adipócitos, e macrófagos THP-1 de linhagem humana. O principal achado de nosso estudo foi que os novos derivados de TZDs estimulam a utilização celular de glicose, porém não alteram o processo de diferenciação celular de pré-osteoblastos e pré-adipócitos, quando comparados com a TZD clássica Rosiglitazona. Conforme esperado, o tratamento com Rosiglitazona na concentração de 5 µM inibiu a osteogênese de pré-osteoblastos murinos MC3T3-E1. No entanto, o tratamento com 2 novos derivados de TZDs (GQ-89 e GQ-177) na mesma concentração não afetou a diferenciação celular, sendo possível observar níveis de mineralização de matriz extracelular similares aos do grupo controle. Além disso, enquanto a GQ-89 estimulou a atividade da fosfatase alcalina, a GQ-177 não modulou sua atividade enzimática e induziu a expressão gênica de osteocalcina. Contudo, ambos inibiram a expressão de Runx2 e colágeno. Por sua vez, quando os efeitos foram avaliados sobre a diferenciação de adipócitos, foi possível observar que ao contrário do efeito pró-adipogênico constatado com a Rosiglitazona na concentração de 1 µM, as TZDs GQ-150, GQ-177, LYSO-7 e SF-3 foram incapazes de induzir o acúmulo lipídico em pré-adipócitos murinos e humanos. Além disso, a GQ-150 inibiu a expressão gênica de C/EBPα, assim como a expressão gênica e os níveis protéicos de CD36, enquanto que a SF-3 estimulou a expressão gênica de C/EBPα e de FABP4 e diminuiu a expressão gênica e os níveis protéicos de CD36, os quais não foram modificados pela LYSO-7 em pré-adipócitos murinos 3T3-L1. No entanto, em pré-adipócitos SGBS de linhagem humana, nenhum efeito sobre os marcadores de fenótipo adipogênico C/EBPα e FABP4 foi observado com os novos derivados de TZDs. Ademais, os novos derivados de TZDs não interferiram na via de sinalização de Wnt, não apresentaram qualquer efeito sobre a expressão de adipocinas (adiponectina, resistina e leptina) e mediadores pró-inflamatórios (IL-6, CCL2/MCP-1, TNF-α e JNK), bem como não ativaram o fator de transcrição PPARγ no ensaio de gene repórter. Por sua vez, a LYSO-7, GQ-150 e SF-3 aumentaram o consumo de glicose em presença de insulina em adipócitos 3T3-L1 e modificaram a atividade de enzimas mitocondriais em adipócitos SGBS e macrófagos THP-1. Entretanto, o efeito sensibilizador de insulina foi confirmado somente com a GQ-177 pelo aumento da captação de glicose e somente a LYSO-7 e a SF-3 foram capazes de inibir o consumo de oxigênio e modificar a taxa de glicólise em macrófagos, sugerindo que também poderiam alterar os níveis de ATP/ADP. Considerando que baixos níveis de ATP estimulam a via de sinalização de AMPK, essa via também foi investigada em nosso estudo. Entretanto, os resultados sobre a ativação de AMPK foram inconclusivos. Desse modo, nossos resultados apontam que os novos derivados de TZDs não atuam como ligantes de PPARγ, apresentam atividade sensibilizadora de insulina in vitro, e que exercem menores efeitos antiosteoblásticos e adipogênicos quando comparados com a Rosiglitazona. Mais estudos são necessários para elucidar os mecanismos responsáveis por esses efeitos, bem como para estabelecer se os novos derivados de TZDs são mais seguros in vivo, com relação ao risco de fraturas ósseas e ganho de massa adiposa

Thiazolidinediones (TZDs) are insulin sensitizers used in the treatment of type 2 diabetes mellitus. However, despite the beneficial effects on blood glucose, significant adverse effects including bone loss and increased adiposity are reported with the clinical use of TZDs. Thus, it is necessary to develop new derivatives of TZDs with potential beneficial effects on hyperglycemia and fewer adverse effects. In this study, we investigated the effects of 5 new derivatives of TZDs (LYSO-7, GQ-89, GQ-150, GQ-177 e SF-3) on cellular differentiation in murine MC3T3-E1 preosteoblasts, murine 3T3-L1 preadipocytes, and SGBS preadipocytes from human lineage. Potential effects on glucose consumption, adipokines, and pro-inflammatory mediators were also assessed using murine and human strains of adipocytes, and macrophages from human THP-1 lineage. The main finding of this study was that new derivatives of TZDs stimulate glucose consumption, but do not change the cell differentiation process of preosteoblasts and preadipocytes compared to classical TZD Rosiglitazone. As expected, the treatmet with Rosiglitazone, at 5µM, inhibited the osteogenesis in murine MC3T3-E1 preosteoblasts. However, the treatment with 2 new derivatives of TZDs (GQ-89 and GQ-177) at the same concentration did not affect cell differentiation, and levels of mineralization of the extracellular matrix similar to the control group were observed. In addition, whereas the GQ-89 stimulated the activity of alkaline phosphatase, GQ-177 does not modulate its enzymatic activity and induced gene expression of osteocalcin. However, both of them inhibit the expression of Runx2 and collagen. In turn, when the effects were assessed on the adipocyte differentiation, unlike the proadipogenic effect observed with Rosiglitazone at a concentration of 1 µM, the new TZDs GQ-150, GQ-177, LYSO-7 and SF-3 were unable to induce lipid accumulation in human and murine preadipocytes. In addition, GQ-150 inhibited the gene expression of C/EBPα , as well as the gene expression and protein levels of CD36, whereas SF-3 stimulated the gene expression of C/EBPα and FABP4 and decreased gene expression and protein levels of CD36, which was not modified by LYSO-7 on murine 3T3- L1 preadipocytes. However, no effect on markers of adipogenic phenotype C/EBPα and FABP4 has been observed with the novel derivatives of TZDs in human SGBS preadipocytes. Furthermore, the new derivatives of TZDs do not interfere with the Wnt signaling pathway, showed no effect on the adipokines expression (adiponectin, resistin and leptin) and proinflammatory mediators (IL-6, CCL2 / MCP-1, TNF α and JNK) and did not activate the transcription factor PPARγ in the gene reporter assay. In turn, LYSO-7, GQ-150, and SF-3 increased glucose consumption in the presence of insulin in 3T3-L1 adipocytes and modified the activity of mitochondrial enzymes in SGBS adipocytes and THP-1 macrophages. However, the effect on insulin sensitization was confirmed only to GQ-177 that increased glucose uptake and just LYSO-7 and SF-3 were able to inhibit oxygen consumption and modify the rate of glycolysis in macrophages, suggesting that they could also alter the levels of ATP/ADP. Since low levels of ATP could stimulate AMPK pathway, this signaling pathway was also investigated in our study. However, the results on the AMPK activation were inconclusive. Thus, our results demonstrate that the new derivatives of TZDs do not act as PPARγ ligands, present insulin sensitizing activity in vitro, and display minor antiosteoblastic and adipogenic effects when compared to Rosiglitazone. More studies are needed to elucidate the exact mechanisms responsible for these effects, as well as to establish whether the safety of the new TZDs with respect to the risk of bone fractures and body mass gain using in vivo models

Identification of two populations of osteoarthritic osteoblasts according to the 1,25[OH]2 vitamin D3 potency to stimulate osteocalcin.

INTRODUCTION: Few studies have tried to discriminate a differential behavior between osteoarthritic (OA) osteoblasts (Obs). Based on osteocalcin level, we aimed, in the present study, to evaluate the capacity of OA Obs for producing molecules of the Wnt/ß-catenin signaling pathway. METHODS: Human primary OA Obs (n=11) were exposed or not to 50 nM of 1,25 dihydroxyvitamin D3 (VitD3) for 24 h. Osteocalcin (OCN), TGF-ß1, Dickkopf-related protein 2 (DKK2), R-spondin 2 (Rspo2), Wnt5b, and low density lipoprotein related-receptor 1 (LRP1) were evaluated by real time RT-PCR. RESULTS: All samples responded to VitD3 as validated by the increase in OCN expression. However two populations of Obs were discriminated; one called "high responders" whose OCN stimulation was higher than 100 fold (mean 881 fold, p<0.01, n=5) and the second one whose stimulation was inferior to 100 fold (mean 47 fold, p<0.01, n=6), namely "low responders". In fact, high responders have a weaker basal expression of OCN. With regards to these two cell populations and in absence of VitD3 challenge, the expression level of TGF-ß1 (15 fold, p<0.001), DKK2 (2.5 fold, p<0.002) and Wnt5b (5.5 fold, p<0.003) was higher in "high responders", meanwhile Rspo2 and LRP1 expression was unchanged. VitD3 exacerbated this pattern but corrected OCN expression and favored Wnt agonist expression. CONCLUSION: We identified 2 populations of OA Obs according to the OCN expression under the control of VitD3. In addition under basal conditions, these 2 populations expressed differently TGF-ß1, Wnt5b, DKK2, suggesting a heterogeneous differentiation and phenotype in Obs among OA patients.

The differential expression of osteoprotegerin (OPG) and receptor activator of nuclear factor kappaB ligand (RANKL) in human osteoarthritic subchondral bone osteoblasts is an indicator of the metabolic state of these disease cells.

OBJECTIVE: We previously reported that human OA subchondral bone osteoblasts could be discriminated into two subpopulations identified by their levels of endogenous production (low [L] or high [H]) of PGE(2). Here, we investigated the OPG and RANKL expression levels, the histologic analysis of the subchondral bone as well as the osteoclast differentiation effect of osteoblasts on normal and both OA subpopulations (L and H), and further examined on the L OA osteoblasts the modulation of bone remodelling factors on the OPG and RANKL levels, as well as on the resorption activity. METHODS: Gene expression was determined using real-time PCR, PGE2 and OPG levels by specific ELISA, and membranous RANKL by flow cytometry. Histological observation of the subchondral bone was performed on human knee specimens. Osteoclast differentiation and formation was assayed by using the pre-osteoclastic cell line RAW 264.7. OPG and RANKL modulation on L OA osteoblasts was monitored following treatment with osteotropic factors, and the resorption activity was studied by the co-culture of differentiated PBMC/osteoblasts. RESULTS: Human OA subchondral bone osteoblasts expressed less OPG than normal. Compared to normal, RANKL gene expression levels were increased in L OA and decreased in H OA cells. The OPG/RANKL mRNA ratio was significantly diminished in L OA compared to normal or H OA (p<0.02, p<0.03), and markedly increased in H OA compared to normal. Inhibition of endogenous PGE(2) levels by indomethacin markedly decreased the ratio of OPG/RANKL on the H OA. In contrast to H OA osteoblasts, L OA cells induced a significantly higher level of osteoclast differentiation and formation (p<0.05). Histological analysis showed a reduced subchondral bone on the L OA and an increased bone mass on the H OA compared to normal. Treatment of L OA osteoblasts with osteotropic factors revealed that the OPG/RANKL mRNA expression ratio was significantly reduced by vitamin D(3) and significantly increased by TNF-alpha, PTH and PGE(2), while IL-1Beta demonstrated no effect. OPG protein levels showed similar profiles. No true effect was noted on membranous RANKL upon treatment with IL-1Beta, PGE(2) and PTH, but a significant increase was observed with vitamin D3 and TNF-alpha. The resorption activity of the L OA cells was significantly inhibited by all treatments except IL-1Beta, with maximum effect observed with vitamin D(3) and PGE(2). CONCLUSION: OPG and RANKL levels, and consequently the OPG/RANKL ratio, differed according to human OA subchondral bone osteoblast classification; it is decreased in L and increased in H OA. These findings, in addition to those showing that L OA osteoblasts have a reduced subchondral bone mass and induce a higher level of osteoclast differentiation, strongly suggest that the metabolic state of the L OA osteoblasts favours bone resorption.

Molecular and cellular characterization of mouse calvarial osteoblasts derived from neural crest and paraxial mesoderm.

BACKGROUND: Cranial skeletogenic mesenchyme is derived from two distinct embryonic sources: mesoderm and cranial neural crest. Previous studies have focused on molecular and cellular differences of juvenile and adult osteoblasts. METHODS: To further understand the features of mouse-derived juvenile osteoblasts, the authors separated calvarial osteoblasts by their developmental origins: frontal bone-derived osteoblasts from cranial neural crest, and parietal bone-derived osteoblasts from paraxial mesoderm. Cells were harvested from a total of 120 mice. RESULTS: Interestingly, the authors observed distinct morphologies and proliferation potential of the two populations of osteoblasts. Osteogenic genes such as alkaline phosphatase, osteopontin, collagen I, and Wnt5a, which was recently identified as playing a role in skeletogenesis, were abundantly expressed in parietal bone-derived osteoblasts versus frontal bone-derived osteoblasts. In addition, fibroblast growth factor (FGF) receptor 2, and FGF-18 were more highly expressed in the parietal bone-derived osteoblasts, suggesting a more differentiated phenotype. In contrast, FGF-2, and adhesion molecules osteoblast cadherins and bone morphogenetic protein receptor IB, the bone tissue-specific type receptor were overexpressed in frontal bone-derived osteoblasts compared with parietal bone-derived osteoblasts. CONCLUSIONS: The authors observed that although neural crest-derived osteoblasts represented a population of less differentiated, faster growing cells, they formed bone nodules more rapidly than parietal bone-derived osteoblasts. This in vitro study suggests that embryonic tissue derivations influence postnatal in vitro calvarial osteoblast cell biology.

The effects of morphology, confluency, and phenotype on whole-cell mechanical behavior.

Emerging evidence indicates that cellular mechanical behavior can be altered by disease, drug treatment, and mechanical loading. To effectively investigate how disease and mechanical or biochemical treatments influence cellular mechanical behavior, it is imperative to determine the source of large inter-cell differences in whole-cell mechanical behavior within a single cell line. In this study, we used the atomic force microscope to investigate the effects of cell morphological parameters and confluency on whole-cell mechanical behavior for osteoblastic and fibroblastic cells. For nonconfluent cells, projected nucleus area, cell area, and cell aspect ratio were not correlated with mechanical behavior (p>or=0.46), as characterized by a parallel-spring recruitment model. However, measured force-deformation responses were statistically different between osteoblastic and fibroblastic cells (p<0.001) and between confluent and nonconfluent cells (p<0.001). Osteoblastic cells were 2.3-2.8 times stiffer than fibroblastic cells, and confluent cells were 1.5-1.8 times stiffer than nonconfluent cells. The results indicate that structural differences related to phenotype and confluency affect whole-cell mechanical behavior, while structural differences related to global morphology do not. This suggests that cytoskeleton structural parameters, such as filament density, filament crosslinking, and cell-cell and cell-matrix attachments, dominate inter-cell variability in whole-cell mechanical behavior.

Are cementoblasts a subpopulation of osteoblasts or a unique phenotype?

Experimental studies have shown a great potential for periodontal regeneration. The limitations of periodontal regeneration largely depend on the regenerative potential at the root surface. Cellular intrinsic fiber cementum (CIFC), so-called bone-like tissue, may form instead of the desired acellular extrinsic fiber cementum (AEFC), and the interfacial tissue bonding may be weak. The periodontal ligament harbors progenitor cells that can differentiate into periodontal ligament fibroblasts, osteoblasts, and cementoblasts, but their precise location is unknown. It is also not known whether osteoblasts and cementoblasts arise from a common precursor cell line, or whether distinct precursor cell lines exist. Thus, there is limited knowledge about how cell diversity evolves in the space between the developing root and the alveolar bone. This review supports the hypothesis that AEFC is a unique tissue, while CIFC and bone share some similarities. Morphologically, functionally, and biochemically, however, CIFC is distinctly different from any bone type. There are several lines of evidence to propose that cementoblasts that produce both AEFC and CIFC are unique phenotypes that are unrelated to osteoblasts. Cementum attachment protein appears to be cementum-specific, and the expression of two proteoglycans, fibromodulin and lumican, appears to be stronger in CIFC than in bone. A theory is presented that may help explain how cell diversity evolves in the periodontal ligament. It proposes that Hertwig's epithelial root sheath and cells derived from it play an essential role in the development and maintenance of the periodontium. The role of enamel matrix proteins in cementoblast and osteoblast differentiation and their potential use for tissue engineering are discussed.

Characterization of the cellular origin of a tissue-engineered human phalanx model by in situ hybridization.

Tissue-engineered models of human phalanges have previously been fabricated from a combination of bovine periosteum, cartilage, tendon, and biodegradable polyglycolic acid and poly-L-lactic acid scaffolds. Resulting constructs implanted in athymic mice for more than 40 weeks developed new bone, cartilage, and tendon and became vascularized, but cell types comprising the constructs were unidentified. The origin of cells in middle phalanx models implanted for 20 weeks in nude mice has been studied by in situ hybridization analyzing species-specific gene expression. Oligonucleotide probes homologous to species-specific gene sequences of bovine type II and X collagen, aggrecan, bone sialoprotein, biglycan, and osteopontin, and mouse decorin were labeled with (35)S and hybridized to respective serial sections of bovine tissue, mouse tissue, and phalanx constructs. In situ hybridization showed positive message and tissue-specific localization for all bovine-specific probes examined within cartilaginous and midshaft portions of constructs and negative message for the mouse-specific decorin probe. These data show that osteoblasts and chondrocytes comprising constructs are derived exclusively from their original bovine sources over 20 weeks of implantation. Defining the cellular origin of the models lends insight into their biological, chemical, and physical nature and their growth and development. Maintenance of their initial genotype is crucial for future application of the models in augmenting impaired human phalanges and related tissues.

Complex permittivity measurement as a new noninvasive tool for monitoring in vitro tissue engineering and cell signature through the detection of cell proliferation, differentiation, and pretissue formation.

In in vitro tissue engineering, microporous scaffolds are commonly used to promote cell proliferation and differentiation in three-dimensional structures. Classic measurement methods are particularly time consuming, difficult to handle, and destructive. In this study, a new nondestructive method based on complex permittivity measurement (CPM) is proposed to monitor and track the osteoblast and macrophage differentiation through their morphological variation upon cell attachment and proliferation inside the microporous scaffolds. CPM is performed using a vector network analyzer and a dielectric probe under sterile conditions in a laminar-flow hood. A suitable effective medium approximation (EMA) is applied to fit the data in order to extract the parameters of the different constituents. Our data show that the EMA depolarization factor can be monitored to assess the variation of cell morphology characterizing cell attachment. Discrimination between two batches of scaffolds seeded, respectively, with 2 million and 1 million osteoblast cells is possible; the ratio of their CPM-derived cell volume fractions is in agreement with the ratio of their cell seeding numbers. In addition, cell proliferation inside scaffolds seeded with osteoblasts cultured in alpha minimum essential medium and inside scaffolds seeded with osteoblasts cultured in alpha minimum essential medium supplemented to induce the formation of extracellular matrix is monitored via CPM over several days. CPM-determined cell volume fraction is compared to DNA assay cell counts. Extracellular matrix formation and cell presence was confirmed by scanning electron microscopy. A set of three signature parameters (epsilon'mem, epsilon'cyt, kappa'cyt) characteristic of cell line is extracted from CPM. Distinct signatures are recorded for osteoblasts and macrophages, thus confirming the ability of CPM to discriminate between different cell types. This study demonstrates the potential of CPM as a diagnostic tool to monitor quickly and noninvasively cell growth and differentiation inside microporous scaffolds. Our findings suggest that the use of CPM could be extended to many biomedical applications, such as drug detection and automation of tissue and bacterial cultures in bioreactors.

Isolation, proliferation and differentiation of osteoblastic cells to study cell/biomaterial interactions: comparison of different isolation techniques and source.

A sufficient amount of easily obtained and well-characterized osteoblastic cells is a useful tool to study biomaterial/cell interactions essential for bone tissue engineering. Osteoblastic cells were derived from adult and fetal rat via different isolation techniques. The isolation and in vitro proliferation of primary cultures were compared. The osteogenic potential of subcultures was studied by culturing them in osteogenic medium and compared with respect to alkaline phosphatase activity, nodule formation and mineralization potential. Calvaria cells were easier to obtain and the amount of cells released by enzymatic isolation was higher than for the long bone cells. The expansion of the cells in primary culture was highest for fetal calvaria cells compared to fetal and adult long bone cells. All cultures expressed high alkaline phosphatase activity except for calvaria cells obtained by spontaneous outgrowth. Enzymatic isolation of fetal calvaria and long bone cells favoured the osteogenic differentiation. Enzymatically isolated calvaria cells formed well-defined three-dimensional nodules which mineralized restricted to this area. On the contrary, cultures derived from fetal as well as adult long bones mineralized in ill-defined deposits throughout the culture and only formed occasionally nodular-like structures. The mineral phase of all osteoblastic cultures was identified as a carbonate-containing apatite. The present study demonstrates that considering the isolation method, proliferation capacity and the osteogenic potential, the enzymatically released fetal calvaria cells are most satisfactory to study cell/biomaterial interactions.

Changes of bone remodeling immediately after parathyroidectomy for secondary hyperparathyroidism.

BACKGROUND: Successful parathyroidectomy for secondary hyperparathyroidism alleviates bone pain and is followed by the development of hypophosphatemia and hypocalcemia, as well as an increase in bone mineral density. An increase in osteoblast surface (Ob.S/BS) is not observed several months after surgery. In this study, we investigated early bone changes at 1 week after parathyroidectomy and the mechanism underlying an increase in bone mineral density. METHODS: Fourteen patients with severe secondary hyperparathyroidism underwent iliac bone biopsy before and 1 week after parathyroidectomy. Changes in histomorphometric parameters, including osteoclast surface (Oc.S/BS), eroded surface (ES/BS), erosion depth (E.De), fibrosis volume (Fb.V/TV), Ob.S/BS, osteoid volume (OV/BV), osteoid surface (OS/BS), and osteoid thickness (O.Th), were investigated. Changes in texture of mineralized bone and osteoid seams were also investigated. RESULTS: Oc.S/BS (P < 0.001), ES/BS (P < 0.01), and E.De (P < 0.001) decreased, but Fb.V/TV did not change at 1 week postoperatively. In particular, osteoclasts disappeared in almost all patients. Ob.S/BS (P < 0.001) increased, and cuboidal osteoblasts were proliferating on the trabecular surface where osteoclasts had existed before parathyroidectomy. As a result, newly developed osteoblasts coexisted with fibrous tissue after surgery. OV/BV (P < 0.005), OS/BS (P < 0.005), and O.Th (P < 0.005) increased, with lamellar osteoid volume showing a particular increase. Bone mineralization continued despite the low postoperative serum parathyroid hormone level. CONCLUSION: A rapid decrease in serum parathyroid hormone level after parathyroidectomy appears to suppress bone resorption, as well as cause a transient marked increase in bone formation and an increase in normal lamellar osteoid seams.

The effects of enamel matrix derivative (EMD) on osteoblastic cells in culture and bone regeneration in a rat skull defect.

OBJECTIVE: Enamel matrix derivative (EMD) has been clinically used to promote periodontal tissue regeneration. The purpose of the present study is to clarify EMD affects on osteoblastic cells and bone regeneration. MATERIALS AND METHODS: Mouse osteoblastic cells (ST2 cells and KUSA/A1 cells) are used in culture experiments. After cells were treated with EMD, cell growth was evaluated with DNA measurement, 5-bromo-2'-deoxyurydine (BrdU) incorporation assay. Measurement of alkaline phosphatase (ALP) activity and mineralized-nodule (MN) formation, Northern blotting analysis and zymography are also performed. In addition, EMD was applied to a rat skull defect and the defect was radiographically and histologically evaluated 2 weeks after the application. RESULTS: EMD did not stimulate ST2 cell growth; however, it enhanced KUSA/A1 cell proliferation. Although EMD stimulated ALP activity in both the cells, ALP activity in KUSA/A1 cells was affected to a much greater degree. Corresponding to the increase in ALP activity, MN formation in KUSA/A1 cells was enhanced by EMD. EMD stimulated osteoblastic phenotype expression of KUSA/A1 cells such as type I collagen, osteopontin, transforming growth factor beta 1 and osteocalcin. EMD treatment also stimulated matrix metalloproteinase production in KUSA/A1 cells. Although the effects of EMD on osteoblastic cells depend on cell type, the overall effect of EMD on osteoblastic cells is stimulatory rather than inhibitory. Finally, EMD application to a rat skull defect accelerated new bone formation. CONCLUSION: These results indicate that EMD affects osteoblastic cells and has potential as a therapeutic material for bone healing.

cAMP binding protein assay for widespread use in cell signaling studies.

cAMP plays a critical role in intracellular signaling pathways that regulate proliferation or differentiation. The cAMP binding protein assay, using a naturally derived cAMP binding protein, is one of the most widely used methods for cAMP determination. The major steps of this binding assay include purification of the binding protein, cAMP extraction from samples, and quantification of the cAMP Most purification methods of the cAMP binding protein were published before 1975, and many of the materials and methods are outdated. Here we describe an updated method of purification of cAMP binding protein from bovine skeletal muscle with the advantages of simplicity, low cost, and high yield The isolation procedures can be completed in two days using commercially available materials and equipment. The cAMP binding properties of the isolated protein can be utilizedfor more than two years. Binding protein isolatedfrom 1 kg bovine muscle is sufficientfor at least 3 x10(4) assay tubes. Furthemore, we describe the techniques of cAMP extraction and quantification that have been used successfully in studying parathyroid hormone signaling as an example of a G protein-linked seven transmembrane domain receptor that signals through the protein kinase A pathway.

Use of type I collagen green fluorescent protein transgenes to identify subpopulations of cells at different stages of the osteoblast lineage.

Green fluorescent protein (GFP)-expressing transgenic mice were produced containing a 3.6-kilobase (kb; pOBCol3.6GFPtpz) and a 2.3-kb (pOBCol2.3GFPemd) rat type I collagen (Col1a1) promoter fragment. The 3.6-kb promoter directed strong expression of GFP messenger RNA (mRNA) to bone and isolated tail tendon and lower expression in nonosseous tissues. The 2.3-kb promoter expressed the GFP mRNA in the bone and tail tendon with no detectable mRNA elsewhere. The pattern of fluorescence was evaluated in differentiating calvarial cell (mouse calvarial osteoblast cell [mCOB]) and in marrow stromal cell (MSC) cultures derived from the transgenic mice. The pOBCol3.6GFPtpz-positive cells first appeared in spindle-shaped cells before nodule formation and continued to show a strong signal in cells associated with bone nodules. pOBCol2.3GFPemd fluorescence first appeared in nodules undergoing mineralization. Histological analysis showed weaker pOBCol3.6GFPtpz-positive fibroblastic cells in the periosteal layer and strongly positive osteoblastic cells lining endosteal and trabecular surfaces. In contrast, a pOBCol2.3GFPemd signal was limited to osteoblasts and osteocytes without detectable signal in periosteal fibroblasts. These findings suggest that Col1a1GFP transgenes are marking different subpopulations of cells during differentiation of skeletal osteoprogenitors. With the use of other promoters and color isomers of GFP, it should be possible to develop experimental protocols that can reflect the heterogeneity of cell differentiation in intact bone. In primary culture, this approach will afford isolation of subpopulations of these cells for molecular and cellular analysis.

Intercellular adhesion molecule 1 discriminates functionally different populations of human osteoblasts: characteristic involvement of cell cycle regulators.

The concept of differential regulation of certain adhesion molecules on different cell subsets and their relevance to cell functions has emerged in recent years. The initial event in bone remodeling is an increase in osteoclastic bone resorption and cell adhesion between osteoclastic precursors and bone marrow stromal cells or osteoblasts is known to commit the osteoclast development. Here, we show that human osteoblasts can be divided into two subsets based on the expression of the intercellular adhesion molecule (ICAM)-1; ICAM-1+ osteoblasts highly adhered to monocytes, including osteoclast precursors, produced osteoclast differentiation factor (ODF), and induced multinuclear osteoclast-like cell formation. Anti-ODF monoclonal antibody (mAb) did not inhibit the adhesion of monocytes to osteoblastic cells, whereas anti-leukocyte function-associated antigen (LFA)-1, a receptor for ICAM-1, mAb blocked the adhesion. We thereby propose that the higher affinity adhesion via LFA-1/ICAM-1 is prerequisite for efficient function of membrane-bound ODF during osteoclast maturation. The functional characteristics of ICAM-1+ osteoblasts were emphasized further by cell cycle regulation, as manifested by (i) up-regulation of p53 and p21, (ii) reduction of activity of cyclin-dependent kinase (cdk) 6, (iii) underphosphorylation of retinoblastoma protein, (iv) increased Fas but reduced bcl-2 expression, and (v) majority of cells remained at G0/G1 phase. Furthermore, ICAM-1+ osteoblasts were induced by interleukin-1beta (IL-1beta). Taken together, we propose that the differentiation of osteoblasts to ICAM-1+ subpopulation by inflammatory cytokines plays an important role in osteoporosis, which is observed in patients with chronic inflammation, because ICAM-1+ osteoblasts can bias bone turnover to bone resorption, committing osteoclast maturation through cell adhesion with its precursor, and the majority of ICAM-1+ osteoblasts arrested at G0/G1 phase. Such regulation of cell cycle arrest also is an important determinant of the life span of cells in bone in which continuous bone remodeling maintains its homeostasis.