Browsing by Subject "Osteogenesis"
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Item A scaffold-free multicellular three-dimensional in vitro model of osteogenesis(Springer, 2011) Gurkan, Umut A.; Kishore, Vipuil; Condon, Keith W.; Bellido, Teresita M.; Akkus, Ozan; Anatomy, Cell Biology and Physiology, School of MedicineIn vitro models of osteogenesis are essential for investigating bone biology and the effects of pharmaceutical, chemical, and physical cues on bone formation. Osteogenesis takes place in a complex three-dimensional (3D) environment with cells from both mesenchymal and hematopoietic origins. Existing in vitro models of osteogenesis include two-dimensional (2D) single type cell monolayers and 3D cultures. However, an in vitro scaffold-free multicellular 3D model of osteogenesis is missing. We hypothesized that the self-inductive ossification capacity of bone marrow tissue can be harnessed in vitro and employed as a scaffold-free multicellular 3D model of osteogenesis. Therefore, rat bone marrow tissue was cultured for 28 days in three settings: 2D monolayer, 3D homogenized pellet, and 3D organotypic explant. The ossification potential of marrow in each condition was quantified by micro-computed tomography. The 3D organotypic marrow explant culture resulted in the greatest level of ossification with plate-like bone formations (up to 5 mm in diameter and 0.24 mm in thickness). To evaluate the mimicry of the organotypic marrow explants to newly forming native bone tissue, detailed compositional and morphological analyses were performed, including characterization of the ossified matrix by histochemistry, immunohistochemistry, Raman microspectroscopy, energy dispersive X-ray spectroscopy, backscattered electron microscopy, and micromechanical tests. The results indicated that the 3D organotypic marrow explant culture model mimics newly forming native bone tissue in terms of the characteristics studied. Therefore, this platform holds significant potential to be used as a model of osteogenesis, offering an alternative to in vitro monolayer cultures and in vivo animal models.Item The Axolotl Fibula as a Model for the Induction of Regeneration across Large Segment Defects in Long Bones of the Extremities(Public Library of Science, 2015) Chen, Xiaoping; Song, Fengyu; Jhamb, Deepali; Li, Jiliang; Bottino, Marco C.; Palakal, Mathew J.; Stocum, David L.; Department of Biology, School of ScienceWe tested the ability of the axolotl (Ambystoma mexicanum) fibula to regenerate across segment defects of different size in the absence of intervention or after implant of a unique 8-braid pig small intestine submucosa (SIS) scaffold, with or without incorporated growth factor combinations or tissue protein extract. Fractures and defects of 10% and 20% of the total limb length regenerated well without any intervention, but 40% and 50% defects failed to regenerate after either simple removal of bone or implanting SIS scaffold alone. By contrast, scaffold soaked in the growth factor combination BMP-4/HGF or in protein extract of intact limb tissue promoted partial or extensive induction of cartilage and bone across 50% segment defects in 30%-33% of cases. These results show that BMP-4/HGF and intact tissue protein extract can promote the events required to induce cartilage and bone formation across a segment defect larger than critical size and that the long bones of axolotl limbs are an inexpensive model to screen soluble factors and natural and synthetic scaffolds for their efficacy in stimulating this process.Item Bone Morphogenetic Protein Signaling Is Required for Aortic Valve Calcification(American Heart Association, 2016-07) Gomez-Stallons, M. Victoria; Wirrig-Schwendeman, Elaine E.; Hassel, Keira R.; Conway, Simon J.; Yutzey, Katherine E.; Pediatrics, School of MedicineOBJECTIVE: Calcific aortic valve disease (CAVD) is the most prevalent type of heart valve disease, affecting ≈2% of the US population. CAVD is characterized by the presence of calcific nodules, resulting in aortic valve (AoV) stenosis; however, the underlying mechanisms driving disease remain unknown. Studies of human diseased AoV provide initial evidence that bone morphogenetic protein (BMP) signaling, essential for normal bone formation, is activated during CAVD. Mice deficient in Klotho, an FGF23 transmembrane coreceptor, exhibit premature aging and develop AoV calcific nodules as occurs in human CAVD. The role of BMP signaling in the development of CAVD was examined in porcine aortic valve interstitial cells (VICs) and Klotho(-/-) mice. APPROACH AND RESULTS: We show that activation of BMP signaling, as indicated by pSmad1/5/8 expression, precedes and later localizes with AoV calcification in Klotho(-/-) mice. In addition, cellular and extracellular matrix changes resembling features of normal bone formation are accompanied by increased osteochondrogenic gene induction in calcified Klotho(-/-) AoV. Likewise, osteogenic media treatment of porcine VICs results in BMP pathway activation, increased osteochondrogenic gene induction, and formation of calcific nodules in vitro. We demonstrate that genetic inactivation of the BMP type IA receptor in Klotho(-/-) aortic VICs, as well as BMP pathway inhibition of osteogenic media-treated aortic VICs in vitro, results in the inhibition of AoV calcification. CONCLUSIONS: BMP signaling and osteochondrogenic gene induction are active in calcified Klotho(-/-) AoV in vivo and calcified porcine aortic VICs in vitro. Importantly, BMP signaling is required for the development of AoV calcification in vitro and in vivo.Item Cell Kinetics of Osteoblast Histogenesis in Evolving Rabbit Secondary Haversian Systems Using a Double Labeling Technique with [³H]-Thymidine and Bromodeoxyuridine(1995) Sim, Yeongsuk; Roberts, Eugene; Garetto, Lawrence P.; Katona, Thomas R.; McDonald, James L.; Seifert, Mark F.The mechanism for internal cortical bone remodeling is orchestrated by the evolving secondary Haversian systems (SHSs), which originate on the surfaces of Volkmann's canals. During this coupled process, a cortical tunnel advances by the cutting cone of osteoclasts and closes by the bone-forming trail of osteoblasts. This study investigated the hypothesis that osteoblast histogenesis, within evolving SHSs of larger animals, is a vascular-related process, i.e., less differentiated osteogenic cells reside in close proximity to the advancing central blood vessel (CBV) while differentiating osteoblast precursors migrate toward the bone surface and become osteoblasts. Using a double-labeling method with [3 H]-thymidine and bromodeoxyuridine (BrdU), this study examined cell kinetics in 120 SHSs per rabbit at 12 hour intervals up to 72 hours after labeling. A total of 7 rabbits were injected with alizarin complexone (-1 O days: 20 mg/kg/day), tetracycline (-3 days: 10 mg/kg/day), [3H]-thymidine (time zero: 0.25 μCi/gm), and BrdU (1 hour before sacrifice: 25 mg/kg). The femoral midshaft was used for undecalcified fluorescent microscopic analysis of new bone vs. old bone and two adjacent diaphyseal tissues were demineralized for nuclear volume morphometric analysis of cells via light microscopy. Evolving SHSs demonstrating intense remodeling activity were selected for detailed cell kinetic analysis. The results showed that BrdU labeled cells were consistently located at the leading edge of the CBV (within 160 μm of its tip) and that the [3H]thymidine labeled cells were progressively left behind the advancing CBV (160 μm from the tip of CBV by 72 hours). The labeling indices (sampled 1 hour after labeling) between BrdU (10.6 ± 0.3 %) and [3H]-thymidine (14.4 ± 1.3 %) were comparable. Lightly labeled A+A' cells (identified as osteoprogenitor cells) remained in close approximation to the surface of the CBV (within 25 μm) and C+D cells (preosteoblasts) were located closer to bone-forming surfaces (~50 μm away from the CBV). The number of osteoblasts were increased up to 60 hours and about 22.5 ± 6.6 % of them survived to become osteocytes. The B cell compartment, characteristic of osteogenic tissues with a dense connective tissue component such as the periodontal ligament (POL), was essentially absent in the SHSs in this study. Although the direction of evolving SHSs was highly variable (caudally directed: 53.4 ± 11.2 % and rostrally directed: 41.6 ± 8.1 %), the osteogenic process along the advancing CBV was remarkably consistent. These results support the hypothesis that osteoblast histogenesis, associated with cortical bone remodeling, is a vascular-oriented differentiation process closely related to the internal angiogenesis within the evolving SHS. The primary proliferating region supporting osteogenesis was consistently located at the advancing tip of the CBV, suggesting the presence of a self-renewing, perivascular proliferative pool of cells accompanying the advancing vessel. In addition, a secondary proliferating region of cells trails the advancing CBV, providing for lateral migration of preosteoblasts to bone surfaces where they complete their development into functional osteoblasts. This study provides further insight into the similarities and differences in osteoblast histogenesis within evolving SHSs from adult rabbits and the more extensively studied rat POL model.Item Differentiation and Activity of Murine Derived Stromal Osteoblasts After Electromagnetic Wave Stimulation(2022) Wu, Jennifer L.; Spolnik, Kenneth; Bruzzaniti, Angela; Ehrlich, Ygal; Warner, NedIntroduction: Elimination of bacteria and active infection within an infected root canal system is one of the primary objectives of nonsurgical root canal treatment. One of the measures of successful root canal treatment is subsequent bone healing of periapical lesions caused by previous infection. A previous study by Yumoto et al. showed that electromagnetic wave stimulation can increase proliferation of osteoblastic cells with no cytotoxicity, and it can also up-regulate growth factors such as vascular endothelial growth factor and platelet-derived growth factor.18 They also showed increased proliferation of an immortalized osteoblastic MC3T3-E1 cell line 3 days following electromagnetic stimulation (EMS).18 Previously, Pauly et al. found increased alkaline phosphatase (ALP) activity with 10 mA EMS application to primary murine calvaria-derived osteoblastic cells with 5 pulses at 1 second per pulse, but no significant differences were found for MTS proliferation nor mineral deposition compared to a negative control group.82 Optimization of the different variables including post-treatment incubation time, current delivery, and number of pulses per treatment may be necessary to improve osteogenic activity. The use of mesenchymal stem cells from murine bone marrow may also offer a physiologically relevant model for osteoblastic regeneration of periapical lesions. Objectives: The goal of this study was to investigate and optimize the effects of electromagnetic wave stimulation (EMS) on murine bone marrow mesenchymal stem cells (MSCs) by evaluating the proliferation and differentiation of the cells after exposure to different EMS treatment regimens. Materials and Methods: 5 x104 stromal osteoblasts (SOBs) were cultured in 24-well plates in α-MEM containing 10% fetal bovine serum. Cells were then subjected to pulsed EMS treatments of 1 mA, 10 mA, and 50 mA. EMS was generated using an electromagnetic apical treatment (EMAT) device created by J. Morita MFG Corp. Proliferation was assessed via MTS assay 1 days after treatment. For osteogenic differentiation, ascorbic acid and β-glycerol phosphate were added to the culture media, and SOBs were cultured for 14 days. Afterwards, alkaline phosphatase (ALP) activity and Alizarin-red S mineral deposition were quantified as measures of osteoblast activity. Cells grown in osteogenic media without EMS treatment served as the negative control. Results: Although MSC proliferation was unaffected by different EMS treatment regimens, 50 mA EMS resulted in a decrease in ALP activity and mineral deposition by osteoblasts. Conclusions: Our findings suggest bone healing by EMS may involve a different cellular mechanism, that is not reproduced in vitro in our studies. Utilizing different amperage and EMS regimens may improve osteogenic differentiation.Item Effects of a checkpoint kinase inhibitor, AZD7762, on tumor suppression and bone remodeling(Spandidos Publications, 2018-09) Wang, Luqi; Wang, Yue; Chen, Andy; Jalali, Aydin; Liu, Shengzhi; Guo, Yunxia; Na, Sungsoo; Nakshatri, Harikrishna; Li, Bai-Yan; Yokota, Hiroki; Biomedical Engineering, School of Engineering and TechnologyChemotherapy for suppressing tumor growth and metastasis tends to induce various effects on other organs. Using AZD7762, an inhibitor of checkpoint kinase (Chk) 1 and 2, the present study examined its effect on mammary tumor cells in addition to bone cells (osteoclasts, osteoblasts and osteocytes), using monolayer cell cultures and three-dimensional (3D) cell spheroids. The results revealed that AZD7762 blocked the proliferation of 4T1.2 mammary tumor cells and suppressed the development of RAW264.7 pre-osteoclast cells by downregulating nuclear factor of activated T cells cytoplasmic 1. AZD7762 also promoted the mineralization of MC3T3 osteoblast-like cells and 3D bio-printed bone constructs of MLO-A5 osteocyte spheroids. While a Chk1 inhibitor, PD407824, suppressed the proliferation of tumor cells and the differentiation of pre-osteoclasts, its effect on gene expression in osteoblasts was markedly different compared with AZD7762. Western blotting indicated that the stimulating effect of AZD7762 on osteoblast development was associated with the inhibition of Chk2 and the downregulation of cellular tumor antigen p53. The results of the present study indicated that in addition to acting as a tumor suppressor, AZD7762 may prevent bone loss by inhibiting osteoclastogenesis and stimulating osteoblast mineralization.Item Effects of PYK2-Deficiency on Midpalatal Suture Expansion in Mice(2015-08) Sun, Jun; Bruzzaniti, Angela; Liu, Sean Shih-Yao; Brown, David T.; Chu, Tien Min; Levon, John A.Background: Suture expansion is a very important clinical approach to correct maxillary width deficiency, but it has a high potential for treatment relapse. Accelerating bone formation and mineralization in the midpalatal suture during suture expansion is beneficial in preventing relapse of the arch width and reducing the retention period. Pyk2 is tyrosine kinase which has been shown to mediate signaling pathways that are involved in the process of bone remodeling. Pyk2 knock-out (KO) mice have augmented bone formation and increased bone mass, suggesting that therapeutic strategies that inhibit Pyk2 may be useful to enhance bone remodeling and prevent suture relapse during suture expansion. Objectives: To determine if Pyk2-deficiency affects midpalatal suture bone mass and bone remodeling with or without suture expansion in mice. Methods: Thirty-six Pyk2-KO and thirty-six wild type (WT) 6 week-old male mice were randomly assigned into three groups: receiving no expansion force (0 g), 10 g or 20 g force of rapid maxillary expansion for 14 days. Half of the mice in each group were used for histology analysis; the other half was assigned for fluorescence analysis. Suture width, maxilla width and bone volume/tissue volume around suture bone edges were measured using micro-CT. Histological analyses of osteoclasts (tartrate resistant acid phosphatase, TRAP), osteoblasts (alkaline phosphatase, ALP) and chondrocytes (alcian blue) were performed. Results: The BV/TV ratio was significantly higher in Pyk2-KO control mice compared to WT control mice. Suture expansion in WT and Pyk2-KO mice led to an increase in bone marrow spaces around the suture edge and significantly reduced BV/TV. Expansion also led to a significant increase in suture width, suture fibrous area, osteoclast number, cartilage area and hypertrophic chondrocyte number. However, BV/TV in Pyk2-KO mice was significantly higher than in WT mice at both the 10 g and 20 g force levels. In addition, Pyk2-KO exhibited reduced suture width, maxilla width, fibrous area and osteoclast number per bone surface (OC.S/BS) compared to WT mice under expansion forces. Cartilage area and hypertrophic chondrocyte number were increased by force but were independent of mouse genotypes. Conclusion: Pyk2-KO mice have higher BV/TV and narrower suture width compared to WT mice, which may be due to decreased osteoclast activity. The higher BV/TV of the midpalatal sutures of Pyk2-KO mice following suture expansion may suggest the presence of a more stable suture that has a reduced potential for relapse. Therapeutic strategies to inhibit Pyk2 during RME may be beneficial in increasing bone mass and preventing relapse of the suture.Item Extract of Artemisia dracunculus L. Modulates Osteoblast Proliferation and Mineralization(MDPI, 2023-08-30) Scott, Matthew C.; Bourgeois, Aleah; Yu, Yongmei; Burk, David H.; Smith, Brenda J.; Floyd, Z. Elizabeth; Obstetrics and Gynecology, School of MedicineThiazolidinediones (TZD) significantly improve insulin sensitivity via action on adipocytes. Unfortunately, TZDs also degrade bone by inhibiting osteoblasts. An extract of Artemisia dracunculus L., termed PMI5011, improves blood glucose and insulin sensitivity via skeletal muscle, rather than fat, and may therefore spare bone. Here, we examine the effects of PMI5011 and an identified active compound within PMI5011 (2′,4′-dihydroxy-4-methoxydihydrochalcone, DMC-2) on pre-osteoblasts. We hypothesized that PMI5011 and DMC-2 will not inhibit osteogenesis. To test our hypothesis, MC3T3-E1 cells were induced in osteogenic media with and without PMI5011 or DMC-2. Cell lysates were probed for osteogenic gene expression and protein content and were stained for osteogenic endpoints. Neither compound had an effect on early stain outcomes for alkaline phosphatase or collagen. Contrary to our hypothesis, PMI5011 at 30 µg/mL significantly increases osteogenic gene expression as early as day 1. Further, osteogenic proteins and cell culture mineralization trend higher for PMI5011-treated wells. Treatment with DMC-2 at 1 µg/mL similarly increased osteogenic gene expression and significantly increased mineralization, although protein content did not trend higher. Our data suggest that PMI5011 and DMC-2 have the potential to promote bone health via improved osteoblast maturation and activity.Item From inside your bones: Osteocytic signaling pathways as therapeutic targets for bone fragility(Springer Nature, 2016-10) Plotkin, Lilian I.; Bellido, Teresita; Anatomy and Cell Biology, IU School of MedicineOsteocytes are differentiated osteoblasts that become surrounded by matrix during the process of bone formation. The acquisition of the osteocyte phenotype is achieved by profound modifications in gene expression that confer adaptation to the changing cellular functions and constitute the molecular signature of osteocytes. The levels of expression of genes characteristic of osteoblasts is altered; and the expression of genes/proteins that impart dendritic cellular morphology, regulate matrix mineralization, and control the function of bone surface cells, is orderly modulated during osteocytogenesis. The discovery of human mutations of osteocytic genes had contributed to a large extent to reveal the role of osteocytes in bone homeostasis. Osteocytes are targets of mechanical force imposed to the skeleton and also play a critical role in integrating mechanosensory pathways with the action of hormones, thereby leading to the orchestrated response of bone to environmental cues. Current, novel therapeutic approaches harness this accumulating knowledge by targeting osteocytic signaling pathways and messengers to improve skeletal health.Item High glucose-induced inhibition of osteoblast like MC3T3-E1 differentiation promotes mitochondrial perturbations(PLOS, 2022-06-17) Medeiros, Claudia; Wallace, Joseph M.; Biomedical Engineering, School of Engineering and TechnologyDiabetes mellitus is a metabolic disorder that causes health concerns worldwide. Patients with diabetes exhibit multisystemic symptoms, including loss of bone quality over time. The progressive deterioration of bone promotes failure to withstand damage and increases the risk of fractures. Much of the molecular and metabolic mechanism(s) in diabetic bone remains unclear. In vitro studies suggest that hyperglycemia inhibits mineralization, affecting bone formation and function. In this study, inhibition of osteoblast differentiation was induced using hyperglycemia to assess whether high glucose promotes mitochondrial impairment along with altered bone matrix formation. It was hypothesized that bone energy metabolism would be altered in these cells as calcium deposition, a key phase for bone function, is suppressed. Early passages of osteoblast like MC3T3-E1 cells were differentiated under normal and high glucose conditions. To investigate osteoblast differentiation, we quantified calcium accumulation by alizarin red staining and analyzed immunoblots of key proteins. To assess mitochondrial function, we quantified mitochondrial DNA (mtDNA), detected expression and function of key proteins from the Tricarboxylic (TCA) cycle, measured mitochondrial respiration, and fuel oxidation of alternative nutrients. Results confirmed previous work showing that mineralization was inhibited and AKT expression was reduced in high glucose-treated bone cells. Unexpectedly, high glucose-treated osteoblast cells utilize both mitochondrial respiration and glycolysis to maintain energy demands with partial help of fatty acid for reliance of baseline bioenergetics. These metabolic shifts suggest that hyperglycemia maintain bone metabolic needs in an early differentiated state concurrent to the inhibition in bone matrix formation.