TY  - CHAP
AU  - Nalbantova, Vanya
AU  - Lukova, Paolina K.
AU  - Pierre, Guillaume
AU  - Benbasat, Niko
AU  - Katsarov, Plamen D.
AU  - Espitia, P. J. P.
AU  - Fuenmayor, Carlos A.
AU  - Nešić, Aleksandra
AU  - Carranza, Mary Stephanie S.
AU  - Michaud, Philippe
AU  - Delattre, Cedric
PY  - 2022
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/10938
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.
T2  - Polysaccharides of Microbial Origin: Biomedical Applications
T1  - 3D Printing of Microbial Polysaccharides
SP  - 1213
EP  - 1245
DO  - 10.1007/978-3-030-42215-8_61
ER  - 

@inbook{
author = "Nalbantova, Vanya and Lukova, Paolina K. and Pierre, Guillaume and Benbasat, Niko and Katsarov, Plamen D. and Espitia, P. J. P. and Fuenmayor, Carlos A. and Nešić, Aleksandra and Carranza, Mary Stephanie S. and Michaud, Philippe and Delattre, Cedric",
year = "2022",
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.",
journal = "Polysaccharides of Microbial Origin: Biomedical Applications",
booktitle = "3D Printing of Microbial Polysaccharides",
pages = "1213-1245",
doi = "10.1007/978-3-030-42215-8_61"
}

Nalbantova, V., Lukova, P. K., Pierre, G., Benbasat, N., Katsarov, P. D., Espitia, P. J. P., Fuenmayor, C. A., Nešić, A., Carranza, M. S. S., Michaud, P.,& Delattre, C.. (2022). 3D Printing of Microbial Polysaccharides. in Polysaccharides of Microbial Origin: Biomedical Applications, 1213-1245.
https://doi.org/10.1007/978-3-030-42215-8_61

Nalbantova V, Lukova PK, Pierre G, Benbasat N, Katsarov PD, Espitia PJP, Fuenmayor CA, Nešić A, Carranza MSS, Michaud P, Delattre C. 3D Printing of Microbial Polysaccharides. in Polysaccharides of Microbial Origin: Biomedical Applications. 2022;:1213-1245.
doi:10.1007/978-3-030-42215-8_61 .

Nalbantova, Vanya, Lukova, Paolina K., Pierre, Guillaume, Benbasat, Niko, Katsarov, Plamen D., Espitia, P. J. P., Fuenmayor, Carlos A., Nešić, Aleksandra, Carranza, Mary Stephanie S., Michaud, Philippe, Delattre, Cedric, "3D Printing of Microbial Polysaccharides" in Polysaccharides of Microbial Origin: Biomedical Applications (2022):1213-1245,
https://doi.org/10.1007/978-3-030-42215-8_61 . .

TY  - JOUR
AU  - Cabrera-Barjas, Gustavo
AU  - González, Cristian
AU  - Nešić, Aleksandra
AU  - Marrugo, Kelly P
AU  - Gómez, Oscar
AU  - Delattre, Cédric
AU  - Valdes, Oscar
AU  - Yin, Heng
AU  - Bravo, Gaston
AU  - Cea, Juan
PY  - 2021
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/9628
AB  - β-chitin was isolated from marine waste, giant Humboldt squid Dosidicus gigas, and further converted to nanofibers by use of a collider machine under acidic conditions (pH 3). The FTIR, TGA, and NMR analysis confirmed the efficient extraction of β-chitin. The SEM, TEM, and XRD characterization results verified that β-chitin crystalline structure were maintained after mechanical treatment. The mean particle size of β-chitin nanofibers was in the range between 10 and 15 nm, according to the TEM analysis. In addition, the β-chitin nanofibers were converted into films by the simple solvent-casting and drying process at 60 °C. The obtained films had high lightness, which was evidenced by the CIELAB color test. Moreover, the films showed the medium swelling degree (250–290%) in aqueous solutions of different pH and good mechanical resistance in the range between 4 and 17 MPa, depending on film thickness. The results obtained in this work show that marine waste can be efficiently converted to biomaterial by use of mild extractive conditions and simple mechanical treatment, offering great potential for the future development of sustainable multifunctional materials for various industrial applications such as food packaging, agriculture, and/or wound dressing.
T2  - Marine Drugs
T1  - Utilization of Marine Waste to Obtain β-Chitin Nanofibers and Films from Giant Humboldt Squid Dosidicus gigas
VL  - 19
IS  - 4
SP  - 184
DO  - 10.3390/md19040184
ER  - 

@article{
author = "Cabrera-Barjas, Gustavo and González, Cristian and Nešić, Aleksandra and Marrugo, Kelly P and Gómez, Oscar and Delattre, Cédric and Valdes, Oscar and Yin, Heng and Bravo, Gaston and Cea, Juan",
year = "2021",
abstract = "β-chitin was isolated from marine waste, giant Humboldt squid Dosidicus gigas, and further converted to nanofibers by use of a collider machine under acidic conditions (pH 3). The FTIR, TGA, and NMR analysis confirmed the efficient extraction of β-chitin. The SEM, TEM, and XRD characterization results verified that β-chitin crystalline structure were maintained after mechanical treatment. The mean particle size of β-chitin nanofibers was in the range between 10 and 15 nm, according to the TEM analysis. In addition, the β-chitin nanofibers were converted into films by the simple solvent-casting and drying process at 60 °C. The obtained films had high lightness, which was evidenced by the CIELAB color test. Moreover, the films showed the medium swelling degree (250–290%) in aqueous solutions of different pH and good mechanical resistance in the range between 4 and 17 MPa, depending on film thickness. The results obtained in this work show that marine waste can be efficiently converted to biomaterial by use of mild extractive conditions and simple mechanical treatment, offering great potential for the future development of sustainable multifunctional materials for various industrial applications such as food packaging, agriculture, and/or wound dressing.",
journal = "Marine Drugs",
title = "Utilization of Marine Waste to Obtain β-Chitin Nanofibers and Films from Giant Humboldt Squid Dosidicus gigas",
volume = "19",
number = "4",
pages = "184",
doi = "10.3390/md19040184"
}

Cabrera-Barjas, G., González, C., Nešić, A., Marrugo, K. P., Gómez, O., Delattre, C., Valdes, O., Yin, H., Bravo, G.,& Cea, J.. (2021). Utilization of Marine Waste to Obtain β-Chitin Nanofibers and Films from Giant Humboldt Squid Dosidicus gigas. in Marine Drugs, 19(4), 184.
https://doi.org/10.3390/md19040184

Cabrera-Barjas G, González C, Nešić A, Marrugo KP, Gómez O, Delattre C, Valdes O, Yin H, Bravo G, Cea J. Utilization of Marine Waste to Obtain β-Chitin Nanofibers and Films from Giant Humboldt Squid Dosidicus gigas. in Marine Drugs. 2021;19(4):184.
doi:10.3390/md19040184 .

Cabrera-Barjas, Gustavo, González, Cristian, Nešić, Aleksandra, Marrugo, Kelly P, Gómez, Oscar, Delattre, Cédric, Valdes, Oscar, Yin, Heng, Bravo, Gaston, Cea, Juan, "Utilization of Marine Waste to Obtain β-Chitin Nanofibers and Films from Giant Humboldt Squid Dosidicus gigas" in Marine Drugs, 19, no. 4 (2021):184,
https://doi.org/10.3390/md19040184 . .

TY  - JOUR
AU  - Cabrera-Barjas, Gustavo
AU  - Nešić, Aleksandra
AU  - Bravo-Arrepol, Gaston
AU  - Rodríguez-Llamazares, Saddys
AU  - Valdés, Oscar
AU  - Banerjee, Aparna
AU  - Castaño, Johanna
AU  - Delattre, Cédric
PY  - 2021
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/10100
AB  - This study investigated the biocomposite pectin films enriched with murta (Ugni molinae T.) seed polyphenolic extract and reinforced by chitin nanofiber. The structural, morphological, mechanical, barrier, colorimetric, and antioxidant activity of films were evaluated. The obtained data clearly demonstrated that the addition of murta seed extract and the high load of chitin nanofibers (50%) provided more cohesive and dense morphology of films and improved the mechanical resistance and water vapor barrier in comparison to the control pectin film. The antioxidant activity ranged between 71% and 86%, depending on the film formulation and concentration of chitin nanofibers. The presented results highlight the potential use of chitin nanofibers and murta seed extract in the pectin matrix to be applied in functional food coatings and packaging, as a sustainable solution.
T2  - Molecules
T1  - Bioactive Pectin-Murta (Ugni molinae T.) Seed Extract Films Reinforced with Chitin Fibers
VL  - 26
IS  - 24
SP  - 7477
DO  - 10.3390/molecules26247477
ER  - 

@article{
author = "Cabrera-Barjas, Gustavo and Nešić, Aleksandra and Bravo-Arrepol, Gaston and Rodríguez-Llamazares, Saddys and Valdés, Oscar and Banerjee, Aparna and Castaño, Johanna and Delattre, Cédric",
year = "2021",
abstract = "This study investigated the biocomposite pectin films enriched with murta (Ugni molinae T.) seed polyphenolic extract and reinforced by chitin nanofiber. The structural, morphological, mechanical, barrier, colorimetric, and antioxidant activity of films were evaluated. The obtained data clearly demonstrated that the addition of murta seed extract and the high load of chitin nanofibers (50%) provided more cohesive and dense morphology of films and improved the mechanical resistance and water vapor barrier in comparison to the control pectin film. The antioxidant activity ranged between 71% and 86%, depending on the film formulation and concentration of chitin nanofibers. The presented results highlight the potential use of chitin nanofibers and murta seed extract in the pectin matrix to be applied in functional food coatings and packaging, as a sustainable solution.",
journal = "Molecules",
title = "Bioactive Pectin-Murta (Ugni molinae T.) Seed Extract Films Reinforced with Chitin Fibers",
volume = "26",
number = "24",
pages = "7477",
doi = "10.3390/molecules26247477"
}

Cabrera-Barjas, G., Nešić, A., Bravo-Arrepol, G., Rodríguez-Llamazares, S., Valdés, O., Banerjee, A., Castaño, J.,& Delattre, C.. (2021). Bioactive Pectin-Murta (Ugni molinae T.) Seed Extract Films Reinforced with Chitin Fibers. in Molecules, 26(24), 7477.
https://doi.org/10.3390/molecules26247477

Cabrera-Barjas G, Nešić A, Bravo-Arrepol G, Rodríguez-Llamazares S, Valdés O, Banerjee A, Castaño J, Delattre C. Bioactive Pectin-Murta (Ugni molinae T.) Seed Extract Films Reinforced with Chitin Fibers. in Molecules. 2021;26(24):7477.
doi:10.3390/molecules26247477 .

Cabrera-Barjas, Gustavo, Nešić, Aleksandra, Bravo-Arrepol, Gaston, Rodríguez-Llamazares, Saddys, Valdés, Oscar, Banerjee, Aparna, Castaño, Johanna, Delattre, Cédric, "Bioactive Pectin-Murta (Ugni molinae T.) Seed Extract Films Reinforced with Chitin Fibers" in Molecules, 26, no. 24 (2021):7477,
https://doi.org/10.3390/molecules26247477 . .

TY  - CHAP
AU  - Nalbantova, Vanya
AU  - Lukova, Paolina K.
AU  - Pierre, Guillaume
AU  - Benbasat, Niko
AU  - Katsarov, Plamen D.
AU  - Espitia, P. J. P.
AU  - Fuenmayor, Carlos A.
AU  - Nešić, Aleksandra
AU  - Carranza, Mary Stephanie S.
AU  - Michaud, Philippe
AU  - Delattre, Cedric
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, Vanya and Lukova, Paolina K. and Pierre, Guillaume and Benbasat, Niko and Katsarov, Plamen D. and Espitia, P. J. P. and Fuenmayor, Carlos A. and Nešić, Aleksandra and Carranza, Mary Stephanie S. and Michaud, Philippe and Delattre, Cedric",
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. K., Pierre, G., Benbasat, N., Katsarov, P. D., Espitia, P. J. P., Fuenmayor, C. A., Nešić, A., Carranza, M. S. 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 PK, Pierre G, Benbasat N, Katsarov PD, Espitia PJP, Fuenmayor CA, Nešić A, Carranza MSS, 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, Vanya, Lukova, Paolina K., Pierre, Guillaume, Benbasat, Niko, Katsarov, Plamen D., Espitia, P. J. P., Fuenmayor, Carlos A., Nešić, Aleksandra, Carranza, Mary Stephanie S., Michaud, Philippe, Delattre, Cedric, "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 . .

TY  - JOUR
AU  - Nešić, Aleksandra
AU  - Cabrera-Barjas, Gustavo
AU  - Dimitrijević-Branković, Suzana I.
AU  - Davidović, Slađana Z.
AU  - Radovanović, Neda
AU  - Delattre, Cédric
PY  - 2019
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/8800
AB  - The use of polysaccharide-based materials presents an eco-friendly technological solution, by reducing dependence on fossil resources while reducing a product’s carbon footprint, when compared to conventional plastic packaging materials. This review discusses the potential of polysaccharides as a raw material to produce multifunctional materials for food packaging applications. The covered areas include the recent innovations and properties of the polysaccharide-based materials. Emphasis is given to hemicelluloses, marine polysaccharides, and bacterial exopolysaccharides and their potential application in the latest trends of food packaging materials, including edible coatings, intelligent films, and thermo-insulated aerogel packaging.
T2  - Molecules
T1  - Prospect of Polysaccharide-Based Materials as Advanced Food Packaging
VL  - 25
IS  - 1
SP  - 135
DO  - 10.3390/molecules25010135
ER  - 

@article{
author = "Nešić, Aleksandra and Cabrera-Barjas, Gustavo and Dimitrijević-Branković, Suzana I. and Davidović, Slađana Z. and Radovanović, Neda and Delattre, Cédric",
year = "2019",
abstract = "The use of polysaccharide-based materials presents an eco-friendly technological solution, by reducing dependence on fossil resources while reducing a product’s carbon footprint, when compared to conventional plastic packaging materials. This review discusses the potential of polysaccharides as a raw material to produce multifunctional materials for food packaging applications. The covered areas include the recent innovations and properties of the polysaccharide-based materials. Emphasis is given to hemicelluloses, marine polysaccharides, and bacterial exopolysaccharides and their potential application in the latest trends of food packaging materials, including edible coatings, intelligent films, and thermo-insulated aerogel packaging.",
journal = "Molecules",
title = "Prospect of Polysaccharide-Based Materials as Advanced Food Packaging",
volume = "25",
number = "1",
pages = "135",
doi = "10.3390/molecules25010135"
}

Nešić, A., Cabrera-Barjas, G., Dimitrijević-Branković, S. I., Davidović, S. Z., Radovanović, N.,& Delattre, C.. (2019). Prospect of Polysaccharide-Based Materials as Advanced Food Packaging. in Molecules, 25(1), 135.
https://doi.org/10.3390/molecules25010135

Nešić A, Cabrera-Barjas G, Dimitrijević-Branković SI, Davidović SZ, Radovanović N, Delattre C. Prospect of Polysaccharide-Based Materials as Advanced Food Packaging. in Molecules. 2019;25(1):135.
doi:10.3390/molecules25010135 .

Nešić, Aleksandra, Cabrera-Barjas, Gustavo, Dimitrijević-Branković, Suzana I., Davidović, Slađana Z., Radovanović, Neda, Delattre, Cédric, "Prospect of Polysaccharide-Based Materials as Advanced Food Packaging" in Molecules, 25, no. 1 (2019):135,
https://doi.org/10.3390/molecules25010135 . .