Aim of work was to locate a simple, reproducible protocol for uniform seeding and optimal cellularization of biodegradable patch minimizing the risk of structural damages of patch and its contamination in long-term culture. Two seeding procedures are exploited, namely static seeding procedures on biodegradable and biocompatible patches incubated as free floating (floating conditions) or supported by CellCrownTM insert (fixed conditions) and engineered by porcine bone marrow MSCs (p-MSCs). Scaold prototypes having specific structural features with regard to pore size, pore orientation, porosity, and pore distribution were produced using two dierent techniques, such as temperature-induced precipitation method and electrospinning technology. The investigation on dierent prototypes allowed achieving several implementations in terms of cell distribution uniformity, seeding eciency, and cellularization timing. The cell seeding protocol in stating conditions demonstrated to be the most suitable method, as these conditions successfully improved the cellularization of polymeric patches. Furthermore, the investigation provided interesting information on patches’ stability in physiological simulating experimental conditions. Considering the in vitro results, it can be stated that the in vitro protocol proposed for patches cellularization is suitable to achieve homogeneous and complete cellularizations of patch. Moreover, the protocol turned out to be simple, repeatable, and reproducible.
Tissue Engineered Esophageal Patch by Mesenchymal Stromal Cells: Optimization of Electrospun Patch Engineering
Silvia Pisani;Enrica Chiesa;Rossella Dorati;Elisa Lenta;Ida Genta;Giovanna Bruni;Simone Mauramati;Alberto Benazzo;Lorenzo Cobianchi;Patrizia Morbini;Laura Caliogna;Marco Benazzo;Bice Conti
2020-01-01
Abstract
Aim of work was to locate a simple, reproducible protocol for uniform seeding and optimal cellularization of biodegradable patch minimizing the risk of structural damages of patch and its contamination in long-term culture. Two seeding procedures are exploited, namely static seeding procedures on biodegradable and biocompatible patches incubated as free floating (floating conditions) or supported by CellCrownTM insert (fixed conditions) and engineered by porcine bone marrow MSCs (p-MSCs). Scaold prototypes having specific structural features with regard to pore size, pore orientation, porosity, and pore distribution were produced using two dierent techniques, such as temperature-induced precipitation method and electrospinning technology. The investigation on dierent prototypes allowed achieving several implementations in terms of cell distribution uniformity, seeding eciency, and cellularization timing. The cell seeding protocol in stating conditions demonstrated to be the most suitable method, as these conditions successfully improved the cellularization of polymeric patches. Furthermore, the investigation provided interesting information on patches’ stability in physiological simulating experimental conditions. Considering the in vitro results, it can be stated that the in vitro protocol proposed for patches cellularization is suitable to achieve homogeneous and complete cellularizations of patch. Moreover, the protocol turned out to be simple, repeatable, and reproducible.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.