Stem Cells Associated with Macroporous Bioceramics for Long Bone Repair: 6- to 7-Year Outcome of a Pilot Clinical Study

Marcacci, Maurilio; Kon, Elizaveta; Moukhachev, Vladimir; Lavroukov, Andrei; Kutepov, S. M.; Quarto, Rodolfo; Mastrogiacomo, Maddalena; Cancedda, Ranieri

doi:10.1089/ten.2006.0271

Cited by 517 publications

(356 citation statements)

References 51 publications

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“…This could be the reason behind the increased soft and hard tissue formation around the implants loaded with BM compared to those without BM. Similarly to previous research, our study revealed that the combination of bioceramic implants with BM substantially increased the amount of bone growing on the outer implant surface (Kon et al, 2000;Marcacci et al, 2007). Interestingly, even though different amounts of bone grew on the outer surface of all the implants, no bone formation occurred within the inner compartment of any of the implants tested.…”

Section: Oxygen Delivery In Vitrosupporting

confidence: 88%

Perfluorodecalin and bone regeneration

Tamimi

Comeau²,

Nihouannen³

et al. 2013

eCM

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Perfluorodecalin (PFD) is a chemically and biologically inert biomaterial and, as many perfluorocarbons, is also hydrophobic, radiopaque and has a high solute capacity for gases such as oxygen. In this article we have demonstrated, both in vitro and in vivo, that PFD may significantly enhance bone regeneration. Firstly, the potential benefit of PFD was demonstrated by prolonging the survival of bone marrow cells cultured in anaerobic conditions. These findings translated in vivo, where PFD incorporated into bone-marrow-loaded 3D-printed scaffolds substantially improved their capacity to regenerate bone. Secondly, in addition to biological applications, we have also shown that PFD improves the radiopacity of bone regeneration biomaterials, a key feature required for the visualisation of biomaterials during and after surgical implantation. Finally, we have shown how the extreme hydrophobicity of PFD enables the fabrication of highly cohesive self-setting injectable biomaterials for bone regeneration. In conclusion, perfluorocarbons would appear to be highly beneficial additives to a number of regenerative biomaterials, especially those for bone regeneration.

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Section: Oxygen Delivery In Vitrosupporting

confidence: 88%

Perfluorodecalin and bone regeneration

Tamimi

Comeau²,

Nihouannen³

et al. 2013

eCM

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“…These osteoconductive scaffolds are often combined with growth factors (osteoinductive) (9)(10)(11)(12)(13)(14)(15)(16)(17)(18)(19) and/or with cells (osteogenic) (20)(21)(22)(23)(24)(25)(26)(27)(28)(29)(30)(31)(32) to induce active stimulation of bone regeneration. The objective of most of these investigations is to enable bone defect healing, which remains an unsolved clinical problem.…”

mentioning

confidence: 99%

Porous scaffold architecture guides tissue formation

Cipitria

Lange

Schell

et al. 2012

Journal of Bone and Mineral Research

100

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Critical-sized bone defect regeneration is a remaining clinical concern. Numerous scaffold-based strategies are currently being investigated to enable in vivo bone defect healing. However, a deeper understanding of how a scaffold influences the tissue formation process and how this compares to endogenous bone formation or to regular fracture healing is missing. It is hypothesized that the porous scaffold architecture can serve as a guiding substrate to enable the formation of a structured fibrous network as a prerequirement for later bone formation. An ovine, tibial, 30-mm critical-sized defect is used as a model system to better understand the effect of the scaffold architecture on cell organization, fibrous tissue, and mineralized tissue formation mechanisms in vivo. Tissue regeneration patterns within two geometrically distinct macroscopic regions of a specific scaffold design, the scaffold wall and the endosteal cavity, are compared with tissue formation in an empty defect (negative control) and with cortical bone (positive control). Histology, backscattered electron imaging, scanning small-angle X-ray scattering, and nanoindentation are used to assess the morphology of fibrous and mineralized tissue, to measure the average mineral particle thickness and the degree of alignment, and to map the local elastic indentation modulus. The scaffold proves to function as a guiding substrate to the tissue formation process. It enables the arrangement of a structured fibrous tissue across the entire defect, which acts as a secondary supporting network for cells. Mineralization can then initiate along the fibrous network, resulting in bone ingrowth into a critical-sized defect, although not in complete bridging of the defect. The fibrous network morphology, which in turn is guided by the scaffold architecture, influences the microstructure of the newly formed bone. These results allow a deeper understanding of the mode of mineral tissue formation and the way this is influenced by the scaffold architecture. ß

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“…According to the diamond concept [12,[124][125][126][127], the biological elements of these therapies should involve MSCs and growth mediators including those promoting the new vasculature formation. Whether MSCs are delivered within concentrated or not-concentrated mononuclear bone marrow cells [128,129] or as culture-expanded pure population and loaded on matrices [130] or injected subcutaneously [131], their therapeutic use still needs further optimisation. The inflammation status could affect considerably the effectiveness of the regenerative treatments at least in part via their effect on MSCs [132].…”

Section: Therapeutic Implicationsmentioning

confidence: 99%