Validation of an in vitro 3D bone culture model with perfused and mechanically stressed ceramic scaffold

Bouet, Guénaëlle; Cruel, Magali; Laurent, Coralie; Vico, Laurence; Malaval, Luc; Marchat, David

doi:10.22203/ecm.v029a19

Cited by 31 publications

(30 citation statements)

References 64 publications

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“…No doubt, considering the short history for FMOD reprogramming investigation, many more studies are warranted to enrich our knowledge about FReP cells to the levels that we understand currently available stem cells, including further clarifying the FMOD reprogramming mechanism, and revealing the potential immune-modulation and paracrine function of FReP cells. Additionally, more extensive investigation will be required to translate FReP cell investigation from bench characterization to clinical application, including, but not limited to, optimizing the cell seeding density and culture procedure [83–86], minimizing the xenogeneic exposure for in vitro osteogenic initiation, enhancing the properties of the supporting osteoconductive scaffold(s), improving the interaction between FReP cells and scaffolds [85, 86], and large animal efficacy and safety tests.…”

Section: Discussionmentioning

confidence: 99%

Fibromodulin reprogrammed cells: A novel cell source for bone regeneration

Yang

Ting

et al. 2016

Biomaterials

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Pluripotent or multipotent cell-based therapeutics are vital for skeletal reconstruction in non-healing critical-sized defects since the local endogenous progenitor cells are not often adequate to restore tissue continuity or function. However, currently available cell-based regenerative strategies are hindered by numerous obstacles including inadequate cell availability, painful and invasive cell-harvesting procedures, and tumorigenesis. Previously, we established a novel platform technology for inducing a quiescent stem cell-like stage using only a single extracellular proteoglycan, fibromodulin (FMOD), circumventing gene transduction. In this study, we further purified and significantly increased the reprogramming rate of the yield multipotent FMOD reprogrammed (FReP) cells. We also exposed the ‘molecular blueprint’ of FReP cell osteogenic differentiation by gene profiling. Radiographic analysis showed that implantation of FReP cells into a critical-sized SCID mouse calvarial defect, contributed to the robust osteogenic capability of FReP cells in a challenging clinically relevant traumatic scenario in vivo. The persistence, engraftment, and osteogenesis of transplanted FReP cells without tumorigenesis in vivo were confirmed by histological and immunohistochemical staining. Taken together, we have provided an extended potency, safety, and molecular profile of FReP cell-based bone regeneration. Therefore, FReP cells present a high potential for cellular and gene therapy products for bone regeneration.

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Section: Discussionmentioning

confidence: 99%

Fibromodulin reprogrammed cells: A novel cell source for bone regeneration

Yang

Ting

et al. 2016

Biomaterials

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“…Most of the previous cyclic loading studies have focused on loading parameters (strains ranging from 1 to 10%) that are much different from the physiological range . Furthermore, the substrate on which the cells are attached should replicate mechanical properties of native osteoinductive environment of the tissues to extract appropriate physiological response …”

Section: Introductionmentioning

confidence: 99%

In vitro cyclic compressive loads potentiate early osteogenic events in engineered bone tissue

et al. 2016

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Application of dynamic mechanical loads on bone and bone explants has been reported to enhance osteogenesis and mineralization. To date, published studies have incorporated a range of cyclic strains on 3D scaffolds and platforms to demonstrate the effect of mechanical loading on osteogenesis. However, most of the loading parameters used in these studies do not emulate the in vivo loading conditions. In addition, the scaffolds/platforms are not representative of the native osteoinductive environment of bone tissue and hence may not be entirely accurate to study the in vivo mechanical loading. We hypothesized that biomimicry of physiological loading will potentiate accelerated osteogenesis in bone grafts. In this study, we present a compression bioreactor system that applies cyclic compression to cellular grafts in a controlled manner. Polycaprolactone-β Tricalcium Phosphate (PCL-TCP) scaffolds seeded with Mesenchymal Stem Cells (MSC) were cyclically compressed in bioreactor for a period of 4 weeks at 1 Hz and physiological strain value of 0.22% for 4 h per day. Gene expression studies revealed increased expressions of osteogenesis-related genes (Osteonectin and COL1A1) on day 7 of cyclic loading group relative to its static controls. Cyclic compression resulted in a 3.76-fold increase in the activity of Alkaline Phosphatase (ALP) on day 14 when compared to its static group (p < 0.001). In addition, calcium deposition of cyclic loading group was found to attain saturation on day 14 (1.96 fold higher than its static scaffolds). The results suggested that cyclic, physiological compression of stem cell-seeded scaffolds generated highly mineralized bone grafts. © 2016 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 105B: 2366-2375, 2017.

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“…On the whole, the flowrate value remains a confounding variable scattered across four orders of magnitude (from 2 µl/min; Bouet, Cruel, et al, to 60 ml/min; Chen et al, ) without clear patterns between the selected flowrate and observed osteogenic effects. Selected flowrates in perfusion studies do not necessarily rely on experimental design and are often seemingly arbitrarily fixed to 0.1 or 1 ml/min (Allori et al, ; Gardel et al, ; Gomes et al, ; Holtorf, Datta, Jansen, & Mikos, ; Jaasma & O'Brien, ; Sinlapabodin, Amornsudthiwat, Damrongsakkul, & Kanokpanont, ; Van Gordon et al, ) or refer to different setups.…”

Section: Flow Effectsmentioning

confidence: 99%

“…Another popular stimulation methodology is to submit cells to the dual effect of perfusion and cyclic mechanical loading of the scaffold; submitting cells to both flow‐induced shear stresses and substrate deformation is an attempt to better reproduce in vivo stimuli (Bouet, Cruel, et al, ; David et al, ; Dumas et al, ; Stops, Heraty, Browne, O'Brien, & McHugh, ; Zong ming et al, ). Nonetheless, to our best knowledge, fluid movement due to substrate deformation has never been quantified, making the resulting cell responses much more arduous to interpret as the flow patterns remain unknown.…”

Section: Obstacles In Defining Optimal Flow Effectsmentioning

confidence: 99%

Strategy for achieving standardized bone models

Hadida

Marchat

2019

Biotech & Bioengineering

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Reliably producing functional in vitro organ models, such as organ‐on‐chip systems, has the potential to considerably advance biology research, drug development time, and resource efficiency. However, despite the ongoing major progress in the field, three‐dimensional bone tissue models remain elusive. In this review, we specifically investigate the control of perfusion flow effects as the missing link between isolated culture systems and scientifically exploitable bone models and propose a roadmap toward this goal.

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Validation of an in vitro 3D bone culture model with perfused and mechanically stressed ceramic scaffold

Cited by 31 publications

References 64 publications

Fibromodulin reprogrammed cells: A novel cell source for bone regeneration

Fibromodulin reprogrammed cells: A novel cell source for bone regeneration

In vitro cyclic compressive loads potentiate early osteogenic events in engineered bone tissue

Strategy for achieving standardized bone models

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