3D Printing of Microbial Polysaccharides

Nalbantova, V.; Lukova, P.; Pierre, G.; Benbasat, N.; Katsarov, P.; Espitia, P. J. P.; Fuenmayor, C. A.; Nešić, Aleksandra; Carranza, M. S.; Michaud, P.; Delattre, C.

doi:10.1007/978-3-030-35734-4_61-1

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Authors

Nalbantova, V.
Lukova, P.
Pierre, G.
Benbasat, N.
Katsarov, P.
Espitia, P. J. P.
Fuenmayor, C. A.
Nešić, Aleksandra

Carranza, M. S.
Michaud, P.
Delattre, C.

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Abstract

From the last three decades, innovative 3D printing processes have been progressively more investigated for food and regenerative medicine topics due to modern technological advances of 3D printers. In tissue engineering, 3D bioprinting technologies are increasingly improved by the continuous development of efficient bioinks. In this area, biodegradable, cell-biocompatible and nontoxic biopolymers such as microbial polysaccharides have been successfully used as hydrogel biomaterial for bone, skin, etc., tissue regeneration. This chapter, specially dedicated to 3D bioprinting of biopolymers, aims to give a recent overview on the main chemical characterization (monosaccharide compositions, glycosyl linkage…) and physicochemical properties (gelling properties…) of bacterial polysaccharides used as promising bioinks bioprintable materials for tissue engineering fields.

Keywords:

Microbial Polysaccharide / 3D-bioprinting / Regenerative medicine / Hydrogel / Nanocellulose

Source:
Polysaccharides of Microbial Origin, 2020, 1-34

DOI: 10.1007/978-3-030-35734-4_61-1

TY  - CHAP
AU  - Nalbantova, V.
AU  - Lukova, P.
AU  - Pierre, G.
AU  - Benbasat, N.
AU  - Katsarov, P.
AU  - Espitia, P. J. P.
AU  - Fuenmayor, C. A.
AU  - Nešić, Aleksandra
AU  - Carranza, M. S.
AU  - Michaud, P.
AU  - Delattre, C.
PY  - 2020
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/10719
AB  - From the last three decades, innovative 3D printing processes have been progressively more investigated for food and regenerative medicine topics due to modern technological advances of 3D printers. In tissue engineering, 3D bioprinting technologies are increasingly improved by the continuous development of efficient bioinks. In this area, biodegradable, cell-biocompatible and nontoxic biopolymers such as microbial polysaccharides have been successfully used as hydrogel biomaterial for bone, skin, etc., tissue regeneration.  This chapter, specially dedicated to 3D bioprinting of biopolymers, aims to give a recent overview on the main chemical characterization (monosaccharide compositions, glycosyl linkage…) and physicochemical properties (gelling properties…) of bacterial polysaccharides used as promising bioinks bioprintable materials for tissue engineering fields.
T2  - Polysaccharides of Microbial Origin
T1  - 3D Printing of Microbial Polysaccharides
SP  - 1
EP  - 34
DO  - 10.1007/978-3-030-35734-4_61-1
ER  -

@inbook{
author = "Nalbantova, V. and Lukova, P. and Pierre, G. and Benbasat, N. and Katsarov, P. and Espitia, P. J. P. and Fuenmayor, C. A. and Nešić, Aleksandra and Carranza, M. S. and Michaud, P. and Delattre, C.",
year = "2020",
abstract = "From the last three decades, innovative 3D printing processes have been progressively more investigated for food and regenerative medicine topics due to modern technological advances of 3D printers. In tissue engineering, 3D bioprinting technologies are increasingly improved by the continuous development of efficient bioinks. In this area, biodegradable, cell-biocompatible and nontoxic biopolymers such as microbial polysaccharides have been successfully used as hydrogel biomaterial for bone, skin, etc., tissue regeneration.  This chapter, specially dedicated to 3D bioprinting of biopolymers, aims to give a recent overview on the main chemical characterization (monosaccharide compositions, glycosyl linkage…) and physicochemical properties (gelling properties…) of bacterial polysaccharides used as promising bioinks bioprintable materials for tissue engineering fields.",
journal = "Polysaccharides of Microbial Origin",
booktitle = "3D Printing of Microbial Polysaccharides",
pages = "1-34",
doi = "10.1007/978-3-030-35734-4_61-1"
}

Nalbantova, V., Lukova, P., Pierre, G., Benbasat, N., Katsarov, P., Espitia, P. J. P., Fuenmayor, C. A., Nešić, A., Carranza, M. S., Michaud, P.,& Delattre, C.. (2020). 3D Printing of Microbial Polysaccharides. in Polysaccharides of Microbial Origin, 1-34.
https://doi.org/10.1007/978-3-030-35734-4_61-1

Nalbantova V, Lukova P, Pierre G, Benbasat N, Katsarov P, Espitia PJP, Fuenmayor CA, Nešić A, Carranza MS, Michaud P, Delattre C. 3D Printing of Microbial Polysaccharides. in Polysaccharides of Microbial Origin. 2020;:1-34.
doi:10.1007/978-3-030-35734-4_61-1 .

Nalbantova, V., Lukova, P., Pierre, G., Benbasat, N., Katsarov, P., Espitia, P. J. P., Fuenmayor, C. A., Nešić, Aleksandra, Carranza, M. S., Michaud, P., Delattre, C., "3D Printing of Microbial Polysaccharides" in Polysaccharides of Microbial Origin (2020):1-34,
https://doi.org/10.1007/978-3-030-35734-4_61-1 . .