3D anatomical and perfusion MRI for longitudinal evaluation of biomaterials for bone regeneration of femoral bone defect in rats

Ribot, Emeline J.; Tournier, C.; Aid‐Launais, Rachida; Koonjoo, Néha; Oliveira, Hugo; Trotier, Aurélien J.; Rey, Sylvie; Wecker, Didier; Letourneur, Didier; Vilamitjana, J; Miraux, Sylvain

doi:10.1038/s41598-017-06258-0

Cited by 26 publications

(36 citation statements)

References 35 publications

(45 reference statements)

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“…A homogenous seeding of MC3T3-E1 cells within the pore network was achieved by the simple addition of a cell suspension on freeze-dried scaffolds. Isolated cells of different origins (species, tissues), two or more cell types, or cell clusters can be accommodated in these 3D porous scaffolds [17][18][19]21]. Such scaffolds are suitable for cell culture in 3D (especially when cell clustering and spheroid growth is necessary for studying cell development and differentiation), for tissue engineering or for pharmacological assays in 3D.…”

Section: Discussionmentioning

confidence: 99%

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 Mechanisms of pore formation in hydrogel scaffolds textured by freeze-drying

et al. 2019

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The fabrication of hydrogel scaffolds is an important research area in tissue engineering. Hydrogels are textured to provide a 3D-framework that is favorable for cell proliferation and/or differentiation. Optimum hydrogel pore size depends on its biological application. Producing porous hydrogels is commonly achieved through freeze-drying. However, the mechanisms of pore formation remain to be fully understood. We carefully analyzed scaffolds of a cross-linked polysaccharide-based hydrogel developed for bone tissue engineering, using state-of-the-art microscopic techniques. Our experimental results evidenced the shaping of hydrogel during the freezing step, through a specific ice-templating mechanism. These findings will guide the strategies for controlling the porous structure of hydrogel scaffolds.

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Section: Discussionmentioning

confidence: 99%

“…In this work, we address the mechanisms of pore formation by freeze-drying in a polysaccharide-based hydrogel scaffold designed for bone tissue engineering [16]. This biomaterial is under research and industrial developments [17][18][19][20][21]. The scaffolds are manufactured according to Route 1 with a low cooling rate.…”

Section: Introductionmentioning

confidence: 99%

 Mechanisms of pore formation in hydrogel scaffolds textured by freeze-drying

et al. 2019

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“…It preserves the fracture side without opening of the trauma site, as it has to be performed when using plates or osteotomy models 14,15,19,24 . Some research groups investigating bone structures or bone healing in mice or rats already showed assessment of bone and surrounding tissues with MRI by 4,6,8,9,23,24 . In a recent study by Haffner-Luntzer et al 9 an external fixator was used in an osteotomy model of mice with ceramic mounting pins that allow MR-Imaging.…”

Section: Discussionmentioning

confidence: 99%

“…In clinical studies, advanced imaging technologies like positron-emission-tomography combined with computed-tomography (PET/CT), microcomputer-tomography (µCT) and magnetic-resonance-imaging (MRI) are used frequently and contribute to a new understanding of bone tissue composition, regeneration and disease 1 – 3 . Technical progress with regard to increased resolution and the development of contrast agents and labeling techniques provides new insights also in small animal analysis of musculoskeletal tissues, now 4 – 6 . Zachos et al 7 , Malaval et al 8 and Taha et al 9 used non-invasive MRI and a bone quantification procedure to follow bone regeneration and healing in rodents.…”

Section: Introductionmentioning

confidence: 99%

A novel MRI compatible mouse fracture model to characterize and monitor bone regeneration and tissue composition

Schmitz

Timmen²,

Kostka³

et al. 2020

Sci Rep

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Over the last years, murine in vivo magnetic resonance imaging (MRI) contributed to a new understanding of tissue composition, regeneration and diseases. Due to artefacts generated by the currently used metal implants, MRI is limited in fracture healing research so far. In this study, we investigated a novel MRI-compatible, ceramic intramedullary fracture implant during bone regeneration in mice. Three-point-bending revealed a higher stiffness of the ceramic material compared to the metal implants. Electron microscopy displayed a rough surface of the ceramic implant that was comparable to standard metal devices and allowed cell attachment and growth of osteoblastic cells. MicroCT-imaging illustrated the development of the callus around the fracture site indicating a regular progressing healing process when using the novel implant. In MRI, different callus tissues and the implant could clearly be distinguished from each other without any artefacts. Monitoring fracture healing using MRI-compatible implants will improve our knowledge of callus tissue regeneration by 3D insights longitudinal in the same living organism, which might also help to reduce the consumption of animals for future fracture healing studies, significantly. Finally, this study may be translated into clinical application to improve our knowledge about human bone regeneration.

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“…So far, there are a number of reports evaluating the bone-forming ability of biomaterials using rat models, such as bone defect in calvaria [1,29,33], jaw [39], and long bone [45]. Those defects were surgically created in pre-existing bone tissue.…”

Section: Discussionmentioning

confidence: 99%

Osteogenesis of Multipotent Progenitor Cells using the Epigallocatechin Gallate-Modified Gelatin Sponge Scaffold in Rat Congenital Cleft-Jaw Model

Sasayama¹,

Hara²,

Tanaka³

et al. 2018

Preprint

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Cost-effective and functionalized scaffolds are in high demand for stem-cell-based regenerative medicine to treat refractory bone defects in craniofacial abnormalities and injuries. One potential strategy is to utilize pharmacological and cost-effective plant polyphenols and biocompatible proteins, such as gelatin. Nevertheless, the use of chemically modified proteins with plant polyphenols in this strategy has not been standardized. Here, we demonstrated that gelatin chemically modified with epigallocatechin gallate (EGCG), the major catechin isolated from green tea, can be a useful material for dedifferentiated fat cells and adipose-derived stem cells and can induce bone regeneration in a rat congenial cleft-jaw model in vivo. Vacuum-heated gelatin sponge modified with EGCG (vhEGCG-GS) induced superior osteogenesis from these two cell types compared with vacuum-heated gelatin sponge (vhGS). The EGCG-modification converted the water wettability of vhGS to a hydrophilic property (contact angle: 110° to 3.8°) and the zeta potential to a negative surface charge; the modification enhanced the cell adhesion property and promoted calcium phosphate precipitation. These results suggest that the EGCG-modification with chemical synthesis can be a useful platform to modify the physicochemical property of gelatin. This alteration is likely to provide a preferable microenvironment for multipotent progenitor cells, inducing superior bone formation in vivo.

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3D anatomical and perfusion MRI for longitudinal evaluation of biomaterials for bone regeneration of femoral bone defect in rats

Cited by 26 publications

References 35 publications

Mechanisms of pore formation in hydrogel scaffolds textured by freeze-drying

Mechanisms of pore formation in hydrogel scaffolds textured by freeze-drying

A novel MRI compatible mouse fracture model to characterize and monitor bone regeneration and tissue composition

Osteogenesis of Multipotent Progenitor Cells using the Epigallocatechin Gallate-Modified Gelatin Sponge Scaffold in Rat Congenital Cleft-Jaw Model

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