Your search keyword '"Mauro Comes Franchini"' showing total 6 results

1. Synthesis and functionalization of casein nanoparticles with aptamers for triple-negative breast cancer targeting

Author

Chiara Spanu, Simona Camorani, Silvia Tortorella, Lisa Agnello, Mirko Maturi, Mauro Comes Franchini, Laura Cerchia, and Erica Locatelli

Subjects

Materials Chemistry, General Chemistry, Catalysis

Abstract

This work shows the synthesis of a drug delivery system made of casein nanoparticles able to host hydrophobic molecules and be functionalized with aptamers targeting the epidermal growth factor receptor.

Published

2022

2. Biocompatible pectin-based hybrid hydrogels for tissue engineering applications

Author

Mario Chiariello, Giovanni Inzalaco, Mauro Comes Franchini, Silvia Tortorella, Veronica Vetri Buratti, Erica Locatelli, Mirko Maturi, Francesca Dapporto, Letizia Sambri, Tortorella S., Inzalaco G., Dapporto F., Maturi M., Sambri L., Vetri Buratti V., Chiariello M., Comes Franchini M., and Locatelli E.

Subjects

3D bioprinting, food.ingredient, Biocompatibility, Chemistry, technology, industry, and agriculture, General Chemistry, complex mixtures, Gelatin, Catalysis, law.invention, hydrogel, gelatin, toxicity, tissue engineering, food, Tissue engineering, Chemical engineering, law, Self-healing hydrogels, Materials Chemistry, medicine, Swelling, medicine.symptom, Cell encapsulation, Xanthan gum, medicine.drug

Abstract

Hybrid hydrogels made of chemically modified pectin, gelatin and xanthan gum have been formulated and processed through a double crosslinking step, aimed at wound healing applications. The formulation of hybrid hydrogels finds its cornerstone in the possibility to create a supportive environment for cell adhesion and proliferation, ensuring the transport of nutrients via porous structures, together with mechanical properties closely comparable to the native tissue. The hydrogels present a good swelling behavior, resistance to dissolution and fragmentation in simulated biological environment (PBS 1× and DMEM) for up to 20 days and the porous structure, as pictured via scanning electron microscopy, has been foreseen to help cell migration and the exchange of biomolecules. Rheological characterization showed desired mechanical features, while the biocompatibility has been assessed via live/dead assay on murine fibroblasts. Finally, the hybrid hydrogels have also been proved suitable for mechanical extrusion, demonstrating the possibility of cell encapsulation in the future perspective of 3D bioprinting applications.

Published

2021

3. Contents list.

Subjects

CERIUM oxides, SODIUM borohydride, CATIONIC polymers, COUMARINS, QUANTUM dot synthesis, SERS spectroscopy

Published

2022

4. Synthesis and functionalization of casein nanoparticles with aptamers for triple-negative breast cancer targeting.

Author

Spanu, Chiara, Camorani, Simona, Tortorella, Silvia, Agnello, Lisa, Maturi, Mirko, Comes Franchini, Mauro, Cerchia, Laura, and Locatelli, Erica

Subjects

TRIPLE-negative breast cancer, APTAMERS, EPIDERMAL growth factor receptors, DRUG delivery systems, CASEINS, DRUG synthesis, NANOPARTICLES, GROWTH factors

Abstract

This work shows the synthesis of a drug delivery system made of casein nanoparticles able to host hydrophobic molecules and be functionalized with aptamers targeting the epidermal growth factor receptor. In vitro cell viability and uptake analyses, performed on triple-negative breast cancer cells, confirmed the safety profile and the target selectivity. [ABSTRACT FROM AUTHOR]

Published

2022

5. Contents list.

Subjects

ARYL chlorides, TRANSITION metal complexes, FORMIC acid, CONTROLLED release drugs, CEMENTITE

Published

2021

6. Biocompatible pectin-based hybrid hydrogels for tissue engineering applications.

Author

Tortorella, Silvia, Inzalaco, Giovanni, Dapporto, Francesca, Maturi, Mirko, Sambri, Letizia, Vetri Buratti, Veronica, Chiariello, Mario, Comes Franchini, Mauro, and Locatelli, Erica

Subjects

PECTINS, WOUND healing, BIOPRINTING, TISSUE engineering, HYDROGELS, XANTHAN gum, SCANNING electron microscopy

Abstract

Hybrid hydrogels made of chemically modified pectin, gelatin and xanthan gum have been formulated and processed through a double crosslinking step, aimed at wound healing applications. The formulation of hybrid hydrogels finds its cornerstone in the possibility to create a supportive environment for cell adhesion and proliferation, ensuring the transport of nutrients via porous structures, together with mechanical properties closely comparable to the native tissue. The hydrogels present a good swelling behavior, resistance to dissolution and fragmentation in simulated biological environment (PBS 1× and DMEM) for up to 20 days and the porous structure, as pictured via scanning electron microscopy, has been foreseen to help cell migration and the exchange of biomolecules. Rheological characterization showed desired mechanical features, while the biocompatibility has been assessed via live/dead assay on murine fibroblasts. Finally, the hybrid hydrogels have also been proved suitable for mechanical extrusion, demonstrating the possibility of cell encapsulation in the future perspective of 3D bioprinting applications. [ABSTRACT FROM AUTHOR]

Published

2021