Scaffolds for epithelial tissue engineering customized in elastomeric molds

Abdallah, Mohamed‐Nur; Abdollahi, Sara; Laurenti, Marco; Fang, Dongdong; Tran, Simon D.; Cerruti, Marta; Tamimi, Faleh

doi:10.1002/jbm.b.33897

Cited by 7 publications

(5 citation statements)

References 61 publications

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“…In the work of Peyton et al, the pore size from 7 to 17 µm was studied, which is preferred by MSCs, and it turned out that the highest probability for substantive cell movement through the pores was observed for the mean pore diameter of about 12 µm [ 30 ]. As for the soft tissues, for example, the gingival epithelial tissue optimally regenerated with a matrix pore size of about 100

m [ 31 ], and the MSCs under conditions of adipogenic differentiation grew well and proliferated on the scaffolds with pore sizes ranging from 200 to 580

m [ 32 ].…”

Section: Results and Discussionmentioning

confidence: 99%

Poly(3-hydroxybutyrate) 3D-Scaffold–Conduit for Guided Tissue Sprouting

Zharkova

Волков

Мураев³

et al. 2023

IJMS

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Scaffold biocompatibility remains an urgent problem in tissue engineering. An especially interesting problem is guided cell intergrowth and tissue sprouting using a porous scaffold with a special design. Two types of structures were obtained from poly(3-hydroxybutyrate) (PHB) using a salt leaching technique. In flat scaffolds (scaffold-1), one side was more porous (pore size 100–300 μm), while the other side was smoother (pore size 10–50 μm). Such scaffolds are suitable for the in vitro cultivation of rat mesenchymal stem cells and 3T3 fibroblasts, and, upon subcutaneous implantation to older rats, they cause moderate inflammation and the formation of a fibrous capsule. Scaffold-2s are homogeneous volumetric hard sponges (pore size 30–300 μm) with more structured pores. They were suitable for the in vitro culturing of 3T3 fibroblasts. Scaffold-2s were used to manufacture a conduit from the PHB/PHBV tube with scaffold-2 as a filler. The subcutaneous implantation of such conduits to older rats resulted in gradual soft connective tissue sprouting through the filler material of the scaffold-2 without any visible inflammatory processes. Thus, scaffold-2 can be used as a guide for connective tissue sprouting. The obtained data are advanced studies for reconstructive surgery and tissue engineering application for the elderly patients.

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m [ 31 ], and the MSCs under conditions of adipogenic differentiation grew well and proliferated on the scaffolds with pore sizes ranging from 200 to 580

m [ 32 ].…”

Section: Results and Discussionmentioning

confidence: 99%

Poly(3-hydroxybutyrate) 3D-Scaffold–Conduit for Guided Tissue Sprouting

Zharkova

Волков

Мураев³

et al. 2023

IJMS

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“…Herein, only the synthetic elastomers that have already been investigated for tissue engineering purposes are discussed. This review does not include polymers that are not classified as elastomers, such as poly(lactic acid) (PLA) [97][98][99] or poly(ethylene glycol) (PEG) [100,101].…”

Section: Synthetic Elastomersmentioning

confidence: 99%

Elastic materials for tissue engineering applications: Natural, synthetic, and hybrid polymers

et al. 2018

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Tissue engineered scaffolds are being developed as treatment options for malfunctioning tissues throughout the body. It is essential that the scaffold is a close mimic of the native tissue with regards to both mechanical and biological functionalities. Therefore, the production of elastic scaffolds is of key importance to fabricate tissue engineered scaffolds of the elastic tissues such as heart valves and blood vessels. Combining naturally derived and synthetic materials to reach this goal proves to be an interesting area where a highly tunable material that unites mechanical and biological functionalities can be obtained.

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“…In addition to cytotoxicity, as reviewed by Mondschein et al [ 3 ], the consideration of factors, e.g., hydrolytic and enzymatic degradation properties, as well as the mechanical properties of soft polymer-based material, are needed for their adoption in biological studies. Various fabrication approaches for soft polymeric materials have been developed regarding biological applications, including moulding [ 4 , 5 ], casting [ 6 ], particulate leaching [ 7 ], electrospinning [ 8 ], gas foaming [ 9 ], and 3D printing [ 10 , 11 ]. Each of these fabrication processes has unique advantages and limitations in various aspects key to applying soft polymer-based materials in cellular force sensing, such as architecture, dimension, porosity, permeability and diffusion capabilities.…”

Section: Introductionmentioning

confidence: 99%

Soft Polymer-Based Technique for Cellular Force Sensing

Liu

2021

Polymers

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Soft polymers have emerged as a vital type of material adopted in biomedical engineering to perform various biomechanical characterisations such as sensing cellular forces. Distinct advantages of these materials used in cellular force sensing include maintaining normal functions of cells, resembling in vivo mechanical characteristics, and adapting to the customised functionality demanded in individual applications. A wide range of techniques has been developed with various designs and fabrication processes for the desired soft polymeric structures, as well as measurement methodologies in sensing cellular forces. This review highlights the merits and demerits of these soft polymer-based techniques for measuring cellular contraction force with emphasis on their quantitativeness and cell-friendliness. Moreover, how the viscoelastic properties of soft polymers influence the force measurement is addressed. More importantly, the future trends and advancements of soft polymer-based techniques, such as new designs and fabrication processes for cellular force sensing, are also addressed in this review.

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Scaffolds for epithelial tissue engineering customized in elastomeric molds

Cited by 7 publications

References 61 publications

Poly(3-hydroxybutyrate) 3D-Scaffold–Conduit for Guided Tissue Sprouting

Poly(3-hydroxybutyrate) 3D-Scaffold–Conduit for Guided Tissue Sprouting

Elastic materials for tissue engineering applications: Natural, synthetic, and hybrid polymers

Soft Polymer-Based Technique for Cellular Force Sensing

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