Application of Recellularized Non-Woven Materials from Collagen-Enriched Polylactide for Creation of Tissue-Engineered Diaphragm Constructs

Куевда, Е. В.; Губарева, Е. А.; Grigoriev, T. E.; Krasheninnikov, S. V.; Verevkin, A.; Луканина, К. И.; Puzanov, D. P.; Yegiyev, I.Kh.; Vasiliev, Alexander; Чвалун, С. Н.

doi:10.17691/stm2019.11.2.05

Cited by 2 publications

(1 citation statement)

References 9 publications

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“…Some of the most often used synthetic materials used in patches for diaphragm treatment are expanded polytetrafluoroethylene patches (Grethel et al, 2006; Omura et al, 2020), reinforced silastic sheets (Smith et al, 2004), and polypropylene meshes (Mohsina et al, 2017). However, using synthetic materials may cause an allergic reaction, granulation tissue formation, infection, or mechanical insufficiencies with native tissue thoracic deformity and recurrence of the hernia (Kaarthick et al, 2017; Kuevda et al, 2019; Zhao et al, 2013). In addition, synthetic patches do not grow as the child grows (Fauza, Marler, Koka, Forse, Mayer, & Vacanti, 2001; Lantis Ii et al, 2000); hence, patients need to undergo numerous surgeries as they mature.…”

Section: Introductionmentioning

confidence: 99%

Design and fabrication of polycaprolactone/gelatin composite scaffolds for diaphragmatic muscle reconstruction

Navaei

Milan

Samadikuchaksaraei

et al. 2020

J Tissue Eng Regen Med

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Diaphragmatic wall defects caused by congenital disorders or disease remain a major challenge for physicians worldwide. Polymeric patches have been extensively explored within research laboratories and the clinic for soft tissue and diaphragm reconstruction. However, patch usage may be associated with allergic reaction, infection, granulation, and recurrence of the hernia. In this study, we designed and fabricated a porous scaffold using a combination of 3D printing and freeze‐drying techniques. A 3D printed polycaprolactone (PCL) mesh was used to reinforcegelatin scaffolds, representing an advantage over previously reported examples since it provides mechanical strength and flexibility. In vitro studies showed that adherent cells were anchorage‐dependent and grew as a monolayer attached to the scaffolds. Microscopic observations indicated better cell attachments for the scaffolds with higher gelatin content as compared with the PCL control samples. Tensile testing demonstrated the mechanical strength of samples was significantly greater than adult diaphragm tissue. The biocompatibility of the specimens was investigated in vivo using a subcutaneous implantation method in Bagg albino adult mice for 20 days, with the results indicating superior cellular behavior and attachment on scaffolds containing gelatin in comparison to pure PCL scaffolds, suggesting that the porous PCL/gelatin scaffolds have potential as biodegradable and flexible constructs for diaphragm reconstruction.

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Section: Introductionmentioning

confidence: 99%

Design and fabrication of polycaprolactone/gelatin composite scaffolds for diaphragmatic muscle reconstruction

Navaei

Milan

Samadikuchaksaraei

et al. 2020

J Tissue Eng Regen Med

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Development of method for creating tumor xenograft model with porous metal scaffold

Protasova¹,

Гончарова²,

Lukbanova³

et al. 2021

Problems in oncology

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Aim of the study – the development of a method for obtaining a tumor xenograft model by a subcutaneous transplantation of a porous metal scaffold populated with cultured human lung carcinoma cells. Material and methods. The study included 14 athymic male Balb c/nude mice aged 8-90 weeks, weighing 20-24 g. All animals received injections with cultured human A549 lung carcinoma cells subcutaneously into the right anterolateral area of the back. In animals of the main group (gr.1, n=4), scaffolds with a pore diameter of 0.5 mm made of titanium-aluminum-vanadium alloy using an industrial 3D printer served as carriers of tumor cells. Scaffolds were seeded with 3 million A549 culture cells, and were implanted into the recipient animals after the 7-day incubation. Results were compared with the results of the tumor culture transplantation with Matrigel (100 mcL) in two groups of animals with varying cell suspension dosages: the maximum vaccination dose for in vivo (10×106 cells per mouse, gr.2, n=5) and half the maximum dose (5×106 respectively, gr.3, n=5). Then, the dynamics of tumor growth in the groups of experimental mice was monitored for 55 days: xenograft volumes were calculated using the Shrek’s formula for an ellipsoid. At the end of the experiment, the animals were euthanized by cervical dislocation. Results. Monitoring of the dynamics of xenograft volumes demonstrated the maximal values in mice with implanted scaffolds. The slowest xenograft growth was registered in animals with the maximum vaccination dose of tumor cells with Matrigel. Histological study showed that tumor material obtained from all animals corresponded to A549 lung carcinoma. Conclusions. Porous metal scaffolds, previously incubated with A549 culture cells and implanted subcutaneously in athymic Balb c/nude mice, allows obtaining rapidly growing xenografts with histologically confirmed correspondence to the original tumor.

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Application of Recellularized Non-Woven Materials from Collagen-Enriched Polylactide for Creation of Tissue-Engineered Diaphragm Constructs

Cited by 2 publications

References 9 publications

Design and fabrication of polycaprolactone/gelatin composite scaffolds for diaphragmatic muscle reconstruction

Design and fabrication of polycaprolactone/gelatin composite scaffolds for diaphragmatic muscle reconstruction

Development of method for creating tumor xenograft model with porous metal scaffold

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