Generation of co-culture spheroids as vascularisation units for bone tissue engineering

Walser, Regina; Metzger, Wolfgang; Görg, Angelika; Pohlemann, Tim; Menger,; Laschke, MW

doi:10.22203/ecm.v026a16

Cited by 73 publications

(57 citation statements)

References 30 publications

(23 reference statements)

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“…Various scaffolds coated with ECs and OBs showed the expression of angiogenic genes, and the formation of vessel‐like structures in vitro . 52 In vivo studies demonstrated that co‐culture systems promoted the formation of vascularized bone tissue, and the vessel‐like network in scaffolds anastomosed well with the host vasculature . In addition, many research groups have studied the co‐culture system of ECs and MSCs.…”

Section: Terminally Differentiated Vascular Cellsmentioning

confidence: 99%

Cell‐based strategies for vascular regeneration

Zou

Fan

Fartash

et al. 2016

J Biomedical Materials Res

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Vascular regeneration is known to play an essential role in the repair of injured tissues mainly through accelerating the repair of vascular injury caused by vascular diseases, as well as the recovery of ischemic tissues. However, the clinical vascular regeneration is still challenging. Cell-based therapy is thought to be a promising strategy for vascular regeneration, since various cells have been identified to exert important influences on the process of vascular regeneration such as the enhanced endothelium formation on the surface of vascular grafts, and the induction of vessel-like network formation in the ischemic tissues. Here are a vast number of diverse cell-based strategies that have been extensively studied in vascular regeneration. These strategies can be further classified into three main categories, including cell transplantation, construction of tissue-engineered grafts, and surface modification of scaffolds. Cells used in these strategies mainly refer to terminally differentiated vascular cells, pluripotent stem cells, multipotent stem cells, and unipotent stem cells. The aim of this review is to summarize the reported research advances on the application of various cells for vascular regeneration, yielding insights into future clinical treatment for injured tissue/organ.

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Section: Terminally Differentiated Vascular Cellsmentioning

confidence: 99%

Cell‐based strategies for vascular regeneration

Zou

Fan

Fartash

et al. 2016

J Biomedical Materials Res

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“…Multicellular spheroids are cultivated as 3D-cell culture models employed in cancer research [37][38][39] and pharmaceutical screening [40,41]; in addition, applications of spheroids as building blocks in tissue engineering have been envisaged [36,[42][43][44]. Thus, rendering multicellular spheroids with magnetic functionality is deemed important for assembly of artificial tissues, and magnetic nanoparticles have been introduced into cells prior to fabrication of spheroids [9].…”

Section: Fabrication Of Layered Planar Tissue Constructs and Multicelmentioning

confidence: 99%

Cell surface engineering with polyelectrolyte-stabilized magnetic nanoparticles: A facile approach for fabrication of artificial multicellular tissue-mimicking clusters

et al. 2015

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Regenerative medicine requires new ways to assemble and manipulate cells for fabrication of tissue-like constructs. Here we report a novel approach for cell surface engineering of human cells using polymer-stabilized magnetic nanoparticles (MNPs). Cationic polyelectrolyte-coated MNPs are directly deposited onto cellular membranes, producing a mesoporous semi-permeable layer and rendering cells magnetically responsive. Deposition of MNPs can be completed within minutes, under cell-friendly conditions (room temperature and physiologic media). Microscopy (TEM, SEM, AFM, and enhanced dark-field imaging) revealed the intercalation of nanoparticles into the cellular microvilli network. A detailed viability investigation was performed and suggested that MNPs do not inhibit membrane integrity, enzymatic activity, adhesion, proliferation, or cytoskeleton formation, and do not induce apoptosis in either cancer or primary cells. Finally, magnetically functionalized cells were employed to fabricate viable layered planar (two-cell layers) cell sheets and 3D multicellular spheroids.

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“…The results of the present study demonstrated that cell spheroids formed from a single or two cell types preserved viability and may have promoted proliferation in the three-dimensional environment. Previous reports have indicated that co-culture spheroids generated by aggregating different combinations of primary human osteoblasts and human dermal microvascular endothelial cells exhibit excellent properties of preserving viability and promoting proliferation and vascularization (26). It may be suggested that the co-culture technique may be used to generate functional units for tissue-engineering purposes.…”

Section: Discussionmentioning

confidence: 99%

Evaluation of the shape, viability, stemness and osteogenic differentiation of cell spheroids formed from human gingiva-derived stem cells and osteoprecursor cells

Lee

Park

2017

Experimental and Therapeutic Medicine

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The present study was performed to create stem cell spheroids from human gingiva-derived stem cells and osteoprecursor cells and to evaluate the maintenance of the stemness, the viability and osteogenic differentiation of the cell spheroids. Gingiva-derived stem cells were isolated, and a total of 6×105 stem cells and osteoprecursor cells were seeded into concave micromolds at various ratios. Gingiva-derived stem cells and/or osteoprecursor cells formed spheroids in concave microwells. The spheroids demonstrated a smaller diameter when the number of osteoprecursor cells seeded was lower. The majority of cells in the spheroids were identified to be live cells and the cell spheroids preserved viability throughout the experimental period. The cell spheroids, which contained stem cells, were positive for stem-cell markers. Cell spheroids in concave microwells demonstrated a statistically significant increase in alkaline phosphatase activity as time progressed (P<0.05). A statistically significant difference in phosphatase activity was observed in the stem cell alone group when compared with the osteoprecursor cell group at day 5 (P<0.05). Mineralized extracellular deposits were observed in each group after Alizarin Red S staining. Within the limits of the present study, cell spheroids from gingival cells and osteoprecursor cells maintained shape, viability, stemness and osteogenic differentiation potential.

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Generation of co-culture spheroids as vascularisation units for bone tissue engineering

Cited by 73 publications

References 30 publications

Cell‐based strategies for vascular regeneration

Cell‐based strategies for vascular regeneration

Cell surface engineering with polyelectrolyte-stabilized magnetic nanoparticles: A facile approach for fabrication of artificial multicellular tissue-mimicking clusters

Evaluation of the shape, viability, stemness and osteogenic differentiation of cell spheroids formed from human gingiva-derived stem cells and osteoprecursor cells

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