Ex vivo construction of human primary 3D–networked osteocytes

Sun, Qiaoling; Choudhary, Saba; Mannion, Ciaran; Kissin, Yair; Zilberberg, Jenny; Lee, Woo Y.

doi:10.1016/j.bone.2017.09.012

Cited by 29 publications

(42 citation statements)

References 46 publications

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“…The OB proliferated after three weeks in culture and secreted a mineralized extracellular matrix, the cells being inter-connected through dendritic processes and gap junctions, as previously described in literature [45][46][47]. This network of OB could constitute the premise for early differentiation of these cells grown onto the surfaces of BHA and BHA:LiP coatings in vitro and, consequently, for a better osteointegration in vivo [48,49]. This is in line with other studies showing that primary human osteoblastic cells were enabled to produce extracellular matrix and form an ex vivo 3D network of osteocytes, which are the terminally differentiated bone cells, via biomimetic assembly using microfluidic perfusion culture [48].…”

Section: Structural Morphology Of Obsupporting

confidence: 69%

“…This network of OB could constitute the premise for early differentiation of these cells grown onto the surfaces of BHA and BHA:LiP coatings in vitro and, consequently, for a better osteointegration in vivo [48,49]. This is in line with other studies showing that primary human osteoblastic cells were enabled to produce extracellular matrix and form an ex vivo 3D network of osteocytes, which are the terminally differentiated bone cells, via biomimetic assembly using microfluidic perfusion culture [48]. Chen et al [49] reported on mineralized matrix morphology in 3D culture of osteoblasts and revealed by SEM a synergistic cross-talk between 1alpha, 25 (OH) 2 vitamin D3, and bone morphogenetic protein-2 that sustained improved osteogenesis and mineral deposition.…”

Section: Structural Morphology Of Obmentioning

confidence: 99%

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Lithium-Doped Biological-Derived Hydroxyapatite Coatings Sustain In Vitro Differentiation of Human Primary Mesenchymal Stem Cells to Osteoblasts

et al. 2019

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This study is focused on the adhesion and differentiation of the human primary mesenchymal stem cells (hMSC) to osteoblasts lineage on biological-derived hydroxyapatite (BHA) and lithium-doped BHA (BHA:LiP) coatings synthesized by Pulsed Laser Deposition. An optimum adhesion of the cells on the surface of BHA:LiP coatings compared to control (uncoated Ti) was demonstrated using immunofluorescence labelling of actin and vinculin, two proteins involved in the initiation of the cell adhesion process. BHA:LiP coatings were also found to favor the differentiation of the hMSC towards an osteoblastic phenotype in the presence of osteoinductive medium, as revealed by the evaluation of osteoblast-specific markers, osteocalcin and alkaline phosphatase. Numerous nodules of mineralization secreted from osteoblast cells grown on the surface of BHA:LiP coatings and a 3D network-like organization of cells interconnected into the extracellular matrix were evidenced. These findings highlight the good biocompatibility of the BHA coatings and demonstrate that the use of lithium as a doping agent results in an enhanced osteointegration potential of the synthesized biomaterials, which might therefore represent viable candidates for future in vivo applications.

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Section: Structural Morphology Of Obsupporting

confidence: 69%

Section: Structural Morphology Of Obmentioning

confidence: 99%

Lithium-Doped Biological-Derived Hydroxyapatite Coatings Sustain In Vitro Differentiation of Human Primary Mesenchymal Stem Cells to Osteoblasts

et al. 2019

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“…The low quantity needed for bone-on-a-chip experiments and the stability in the expression of the most critical genes during in vitro culture (Sun et al, 2017) favored the choice of primary human osteoblasts (HOBs) for the bone tissue model presented in this study.…”

Section: Cell Culturementioning

confidence: 99%

“…However, osteoblasts can have three other possible fates but the mechanism regulating this transition is not clearly understood yet: they can become bone-lining cells (inactive osteoblasts), undergo apoptosis, or transdifferentiate into chondroid-depositing cells (Dallas and Bonewald, 2010). Gene expression profiles (Boukhechba et al, 2009;Sun et al, 2017) and immunohistochemistry stainings (Uchihashi et al, 2013;Sun et al, 2015;McGarrigle et al, 2016) in traditional 3D culture systems showed that the expression of osteoblast and osteocyte markers in vitro corresponded to the in vivo expression at the same differentiation stages (Franz-Odendaal et al, 2006).…”

Section: Introductionmentioning

confidence: 99%

Primary Human Osteoblasts Cultured in a 3D Microenvironment Create a Unique Representative Model of Their Differentiation Into Osteocytes

Nasello

Alamán‐Díez

Schiavi

et al. 2020

Front. Bioeng. Biotechnol.

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Microengineered systems provide an in vitro strategy to explore the variability of individual patient response to tissue engineering products, since they prefer the use of primary cell sources representing the phenotype variability. Traditional in vitro systems already showed that primary human osteoblasts embedded in a 3D fibrous collagen matrix differentiate into osteocytes under specific conditions. Here, we hypothesized that translating this environment to the organ-on-a-chip scale creates a minimal functional unit to recapitulate osteoblast maturation toward osteocytes and matrix mineralization. Primary human osteoblasts were seeded in a type I collagen hydrogel, to establish the role of lower (2.5 × 10 5 cells/ml) and higher (1 × 10 6 cells/ml) cell density on their differentiation into osteocytes. A custom semi-automatic image analysis software was used to extract quantitative data on cellular morphology from brightfield images. The results are showing that cells cultured at a high density increase dendrite length over time, stop proliferating, exhibit dendritic morphology, upregulate alkaline phosphatase (ALP) activity, and express the osteocyte marker dental matrix protein 1 (DMP1). On the contrary, cells cultured at lower density proliferate over time, do not upregulate ALP and express the osteoblast marker bone sialoprotein 2 (BSP2) at all timepoints. Our work reveals that microengineered systems create unique conditions to capture the major aspects of osteoblast differentiation into osteocytes with a limited number of cells. We propose that the microengineered approach is a functional strategy to create a patient-specific bone tissue model and investigate the individual osteogenic potential of the patient bone cells.

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“…Ex vivo bone explants have the advantage of allowing the study of living osteocytes within their natural setting and are particularly well suited to investigating the response to mechanical loading (Kogawa et al 2018, Morrell et al 2018. More recently, advances have been made in the 3D culture of osteocytes using biomimetic assemblies, which allow formation of an inter-osteocyte connection network that replicates mechanostransduction responses (Sun et al 2017(Sun et al , 2018. Since sclerostin expression is regulated by mechanical loading, access to such systems, which more faithfully reproduce the osteocyte's native environment, will prove highly useful in the future.…”

Section: Osteoblast Lineagementioning

confidence: 99%

Novel actions of sclerostin on bone

Holdsworth

Roberts

2019

Journal of Molecular Endocrinology

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The discovery that two rare autosomal recessive high bone mass conditions were caused by the loss of sclerostin expression prompted studies into its role in bone homeostasis. In this article, we aim to bring together the wealth of information relating to sclerostin in bone though discussion of rare human disorders in which sclerostin is reduced or absent, sclerostin manipulation via genetic approaches and treatment with antibodies that neutralise sclerostin in animal models and in human. Together, these findings demonstrate the importance of sclerostin as a regulator of bone homeostasis and provide valuable insights into its biological mechanism of action. We summarise the current state of knowledge in the field, including the current understanding of the direct effects of sclerostin on the canonical WNT signalling pathway and the actions of sclerostin as an inhibitor of bone formation. We review the effects of sclerostin, and its inhibition, on bone at the cellular and tissue level and discuss new findings that suggest that sclerostin may also regulate adipose tissue. Finally, we highlight areas in which future research is expected to yield additional insights into the biology of sclerostin.

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Ex vivo construction of human primary 3D–networked osteocytes

Cited by 29 publications

References 46 publications

Lithium-Doped Biological-Derived Hydroxyapatite Coatings Sustain In Vitro Differentiation of Human Primary Mesenchymal Stem Cells to Osteoblasts

Lithium-Doped Biological-Derived Hydroxyapatite Coatings Sustain In Vitro Differentiation of Human Primary Mesenchymal Stem Cells to Osteoblasts

Primary Human Osteoblasts Cultured in a 3D Microenvironment Create a Unique Representative Model of Their Differentiation Into Osteocytes

Novel actions of sclerostin on bone

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