TY  - CONF
AU  - Ponjavić, Marijana
AU  - Jeremić, Sanja
AU  - Malagurski, Ivana
AU  - Babu P., Ramesh
AU  - Rajasekaran, Divya
AU  - Topakas, Evangelos
AU  - Nikodinović-Runić, Jasmina
PY  - 2023
UR  - https://afea.eventsair.com/10th-conference-of-mikrobiokosmos/abstract-book
UR  - https://imagine.imgge.bg.ac.rs/handle/123456789/2236
AB  - The rapid increase in global plastics production is
also causing an accelerated environmental
pollution. Recently, biotechnological solutions and
enzymatic recycling of poly(ethylene terephthalate)
(PET) waste stream have been put forward and
commercialized1. Increasing recycling and
upcycling rates is the most effective model
approach to plastic circularity. However, mixed
plastic waste is still quite a challenge for both
recycling and upcycling technologies. This study is
focused on the eco-conversion of plastic waste
containing poly(ethylene terephthalate), PET, into
biopolymer, bacterial nanocellulose. Polymer mix
contained selection of commercial biodegradable
plastics (poly(lactic acid), PLA, poly(ε-caprolactone),
PCL, poly(hyoxyl butyrate), PHB) and PET. This
mixture was hydrolysed under aqueous conditions
and hydrolysate was used as carbon source for
Komagataeibacter medellinensis ID13488 and
bacterial nanocellulose (BNC) production. HPLC
analysis confirmed the presence of monomers and
dimers of polymer mix components indicating
existence of potential substrates for BNC
production. BNC production by K. medellinensis
was investigated and optimized in ter of the
amount of carbon source and growth conditions.
Under the most efficient rate in ter of yield, BNC
production was scaled up and the obtained
biopolymer was characterized. The structure of
produced BNC was confirmed by FTIR analysis,
thermal properties by DSC/TG analysis, and the
morphology of material by optical microscopy and
SEM analysis. This research demonstrates how to
put the mixed plastic waste stream into a circular
loop through the biotechnological conversion into
valuable biopolymer.
C3  - 10th Conference of Mikrobiokosmos
T1  - Conversion of mixed plastic waste containing PET into biopolymer bacterial nanocellulose
UR  - https://hdl.handle.net/21.15107/rcub_imagine_2236
ER  - 

@conference{
author = "Ponjavić, Marijana and Jeremić, Sanja and Malagurski, Ivana and Babu P., Ramesh and Rajasekaran, Divya and Topakas, Evangelos and Nikodinović-Runić, Jasmina",
year = "2023",
abstract = "The rapid increase in global plastics production is
also causing an accelerated environmental
pollution. Recently, biotechnological solutions and
enzymatic recycling of poly(ethylene terephthalate)
(PET) waste stream have been put forward and
commercialized1. Increasing recycling and
upcycling rates is the most effective model
approach to plastic circularity. However, mixed
plastic waste is still quite a challenge for both
recycling and upcycling technologies. This study is
focused on the eco-conversion of plastic waste
containing poly(ethylene terephthalate), PET, into
biopolymer, bacterial nanocellulose. Polymer mix
contained selection of commercial biodegradable
plastics (poly(lactic acid), PLA, poly(ε-caprolactone),
PCL, poly(hyoxyl butyrate), PHB) and PET. This
mixture was hydrolysed under aqueous conditions
and hydrolysate was used as carbon source for
Komagataeibacter medellinensis ID13488 and
bacterial nanocellulose (BNC) production. HPLC
analysis confirmed the presence of monomers and
dimers of polymer mix components indicating
existence of potential substrates for BNC
production. BNC production by K. medellinensis
was investigated and optimized in ter of the
amount of carbon source and growth conditions.
Under the most efficient rate in ter of yield, BNC
production was scaled up and the obtained
biopolymer was characterized. The structure of
produced BNC was confirmed by FTIR analysis,
thermal properties by DSC/TG analysis, and the
morphology of material by optical microscopy and
SEM analysis. This research demonstrates how to
put the mixed plastic waste stream into a circular
loop through the biotechnological conversion into
valuable biopolymer.",
journal = "10th Conference of Mikrobiokosmos",
title = "Conversion of mixed plastic waste containing PET into biopolymer bacterial nanocellulose",
url = "https://hdl.handle.net/21.15107/rcub_imagine_2236"
}

Ponjavić, M., Jeremić, S., Malagurski, I., Babu P., R., Rajasekaran, D., Topakas, E.,& Nikodinović-Runić, J.. (2023). Conversion of mixed plastic waste containing PET into biopolymer bacterial nanocellulose. in 10th Conference of Mikrobiokosmos.
https://hdl.handle.net/21.15107/rcub_imagine_2236

Ponjavić M, Jeremić S, Malagurski I, Babu P. R, Rajasekaran D, Topakas E, Nikodinović-Runić J. Conversion of mixed plastic waste containing PET into biopolymer bacterial nanocellulose. in 10th Conference of Mikrobiokosmos. 2023;.
https://hdl.handle.net/21.15107/rcub_imagine_2236 .

Ponjavić, Marijana, Jeremić, Sanja, Malagurski, Ivana, Babu P., Ramesh, Rajasekaran, Divya, Topakas, Evangelos, Nikodinović-Runić, Jasmina, "Conversion of mixed plastic waste containing PET into biopolymer bacterial nanocellulose" in 10th Conference of Mikrobiokosmos (2023),
https://hdl.handle.net/21.15107/rcub_imagine_2236 .

TY  - CONF
AU  - Ponjavić, Marijana
AU  - Babu P., Ramesh
AU  - Rajasekaran, Divya
AU  - Pantelić, Brana
AU  - Nikodinović-Runić, Jasmina
PY  - 2023
UR  - https://www.accelevents.com/e/circular-bioeconomy-2023#about
UR  - https://imagine.imgge.bg.ac.rs/handle/123456789/1924
AB  - Large amounts of polymers are discarded worldwide each year, leading to a significant
polymer waste in natural environment. The upcycling has been found as an efficient way to
transform polymer waste into high-value biomaterials meeting the conditions required for
circularity by being indefinitely recyclable, without reduction in value or usability.
The presented study refers to the upcycling of commercial biopolymers into bacterial
nanocellulose. Polymer blends, consisted of biodegradable polymers, such as poly(lactic acid),
PLA, poly(butylene succinate), PBS, and poly(ε-caprolactone), PCL. Polymers were hydrolyzed
and the obtained hydrolysates were investigated as potential carbon source for
K. medellinensis ID13488 growth and nanocellulose production. Degradation products were
analyzed using HPLC analysis. Different growth media, including tap water, HS medium,
absence / presence of glucose, were tested and bacterial nanocellulose growth was
confirmed under the most of the tested conditions. Once the BNC growth was set up, the BNC
production was scaled up and the obtained material was investigated in terms of structure
confirmation (FTIR analysis), thermal properties (DSC/TG analysis), morphology (optical
microscopy, AFM analysis) and crystallinity (XRD analysis). Finally, the full life cycle of mixed
biopolymers: from biodegradation to revalorization of end products into bacterial
nanocellulose appeared as perfect model approach to plastic circularity.
C3  - Biotechnology for a circular bioeconomy: carbon capture, waste recycling and mitigation of global warming
T1  - Revalorization of biodegradable polymers to valuable bacterial nanocellulose
SP  - 55
UR  - https://hdl.handle.net/21.15107/rcub_imagine_1924
ER  - 

@conference{
author = "Ponjavić, Marijana and Babu P., Ramesh and Rajasekaran, Divya and Pantelić, Brana and Nikodinović-Runić, Jasmina",
year = "2023",
abstract = "Large amounts of polymers are discarded worldwide each year, leading to a significant
polymer waste in natural environment. The upcycling has been found as an efficient way to
transform polymer waste into high-value biomaterials meeting the conditions required for
circularity by being indefinitely recyclable, without reduction in value or usability.
The presented study refers to the upcycling of commercial biopolymers into bacterial
nanocellulose. Polymer blends, consisted of biodegradable polymers, such as poly(lactic acid),
PLA, poly(butylene succinate), PBS, and poly(ε-caprolactone), PCL. Polymers were hydrolyzed
and the obtained hydrolysates were investigated as potential carbon source for
K. medellinensis ID13488 growth and nanocellulose production. Degradation products were
analyzed using HPLC analysis. Different growth media, including tap water, HS medium,
absence / presence of glucose, were tested and bacterial nanocellulose growth was
confirmed under the most of the tested conditions. Once the BNC growth was set up, the BNC
production was scaled up and the obtained material was investigated in terms of structure
confirmation (FTIR analysis), thermal properties (DSC/TG analysis), morphology (optical
microscopy, AFM analysis) and crystallinity (XRD analysis). Finally, the full life cycle of mixed
biopolymers: from biodegradation to revalorization of end products into bacterial
nanocellulose appeared as perfect model approach to plastic circularity.",
journal = "Biotechnology for a circular bioeconomy: carbon capture, waste recycling and mitigation of global warming",
title = "Revalorization of biodegradable polymers to valuable bacterial nanocellulose",
pages = "55",
url = "https://hdl.handle.net/21.15107/rcub_imagine_1924"
}

Ponjavić, M., Babu P., R., Rajasekaran, D., Pantelić, B.,& Nikodinović-Runić, J.. (2023). Revalorization of biodegradable polymers to valuable bacterial nanocellulose. in Biotechnology for a circular bioeconomy: carbon capture, waste recycling and mitigation of global warming, 55.
https://hdl.handle.net/21.15107/rcub_imagine_1924

Ponjavić M, Babu P. R, Rajasekaran D, Pantelić B, Nikodinović-Runić J. Revalorization of biodegradable polymers to valuable bacterial nanocellulose. in Biotechnology for a circular bioeconomy: carbon capture, waste recycling and mitigation of global warming. 2023;:55.
https://hdl.handle.net/21.15107/rcub_imagine_1924 .

Ponjavić, Marijana, Babu P., Ramesh, Rajasekaran, Divya, Pantelić, Brana, Nikodinović-Runić, Jasmina, "Revalorization of biodegradable polymers to valuable bacterial nanocellulose" in Biotechnology for a circular bioeconomy: carbon capture, waste recycling and mitigation of global warming (2023):55,
https://hdl.handle.net/21.15107/rcub_imagine_1924 .