Your search keyword '"Andrea Bagno"' showing total 2 results

1. Small intestinal submucosa-derived extracellular matrix as a heterotopic scaffold for cardiovascular applications

Author

Tiziana Palmosi, Anna Maria Tolomeo, Carmine Cirillo, Debora Sandrin, Manuela Sciro, Susanna Negrisolo, Martina Todesco, Federico Caicci, Michele Santoro, Eleonora Dal Lago, Massimo Marchesan, Michele Modesti, Andrea Bagno, Filippo Romanato, Paolo Grumati, Assunta Fabozzo, and Gino Gerosa

Subjects

cardiac repair, decellularization, cardiac surgery, ECM, extracellular matrix, SIS, Biotechnology, TP248.13-248.65

Abstract

Structural cardiac lesions are often surgically repaired using prosthetic patches, which can be biological or synthetic. In the current clinical scenario, biological patches derived from the decellularization of a xenogeneic scaffold are gaining more interest as they maintain the natural architecture of the extracellular matrix (ECM) after the removal of the native cells and remnants. Once implanted in the host, these patches can induce tissue regeneration and repair, encouraging angiogenesis, migration, proliferation, and host cell differentiation. Lastly, decellularized xenogeneic patches undergo cell repopulation, thus reducing host immuno-mediated response against the graft and preventing device failure. Porcine small intestinal submucosa (pSIS) showed such properties in alternative clinical scenarios. Specifically, the US FDA approved its use in humans for urogenital procedures such as hernia repair, cystoplasties, ureteral reconstructions, stress incontinence, Peyronie’s disease, penile chordee, and even urethral reconstruction for hypospadias and strictures. In addition, it has also been successfully used for skeletal muscle tissue reconstruction in young patients. However, for cardiovascular applications, the results are controversial. In this study, we aimed to validate our decellularization protocol for SIS, which is based on the use of Tergitol 15 S 9, by comparing it to our previous and efficient method (Triton X 100), which is not more available in the market. For both treatments, we evaluated the preservation of the ECM ultrastructure, biomechanical features, biocompatibility, and final bioinductive capabilities. The overall analysis shows that the SIS tissue is macroscopically distinguishable into two regions, one smooth and one wrinkle, equivalent to the ultrastructure and biochemical and proteomic profile. Furthermore, Tergitol 15 S 9 treatment does not modify tissue biomechanics, resulting in comparable to the native one and confirming the superior preservation of the collagen fibers. In summary, the present study showed that the SIS decellularized with Tergitol 15 S 9 guarantees higher performances, compared to the Triton X 100 method, in all the explored fields and for both SIS regions: smooth and wrinkle.

Published

2022

2. Decellularized esophageal tubular scaffold microperforated by quantum molecular resonance technology and seeded with mesenchymal stromal cells for tissue engineering esophageal regeneration

Author

Maurizio Marzaro, Gianantonio Pozzato, Stefano Tedesco, Mattia Algeri, Alessandro Pozzato, Luigi Tomao, Ilaria Montano, Filippo Torroni, Valerio Balassone, Anna Chiara Iolanda Contini, Luciano Guerra, Tommaso D’Angelo, Giovanni Federici di Abriola, Lorenzo Lupoi, Maria Emiliana Caristo, Ivo Boškoski, Guido Costamagna, Paola Francalanci, Giuseppe Astori, Angela Bozza, Andrea Bagno, Martina Todesco, Emanuele Trovalusci, Luigi Dall’ Oglio, Franco Locatelli, and Tamara Caldaro

Subjects

tissue engineering, esophagus, quantum molecular resonance, mesenchymal stromal cells, scaffold, Biotechnology, TP248.13-248.65

Abstract

Current surgical options for patients requiring esophageal replacement suffer from several limitations and do not assure a satisfactory quality of life. Tissue engineering techniques for the creation of customized “self-developing” esophageal substitutes, which are obtained by seeding autologous cells on artificial or natural scaffolds, allow simplifying surgical procedures and achieving good clinical outcomes. In this context, an appealing approach is based on the exploitation of decellularized tissues as biological matrices to be colonized by the appropriate cell types to regenerate the desired organs. With specific regard to the esophagus, the presence of a thick connective texture in the decellularized scaffold hampers an adequate penetration and spatial distribution of cells. In the present work, the Quantum Molecular Resonance® (QMR) technology was used to create a regular microchannel structure inside the connective tissue of full-thickness decellularized tubular porcine esophagi to facilitate a diffuse and uniform spreading of seeded mesenchymal stromal cells within the scaffold. Esophageal samples were thoroughly characterized before and after decellularization and microperforation in terms of residual DNA content, matrix composition, structure and biomechanical features. The scaffold was seeded with mesenchymal stromal cells under dynamic conditions, to assess the ability to be repopulated before its implantation in a large animal model. At the end of the procedure, they resemble the original esophagus, preserving the characteristic multilayer composition and maintaining biomechanical properties adequate for surgery. After the sacrifice we had histological and immunohistochemical evidence of the full-thickness regeneration of the esophageal wall, resembling the native organ. These results suggest the QMR microperforated decellularized esophageal scaffold as a promising device for esophagus regeneration in patients needing esophageal substitution.

Published

2022