TY  - JOUR
AU  - Ferrero, Pablo
AU  - Attallah, Olivia A.
AU  - Angel Valera, Miguel
AU  - Aleksić, Ivana
AU  - Azeem, Muhammad
AU  - Nikodinović-Runić, Jasmina
AU  - Fournet, Margaret Brennan
PY  - 2022
UR  - https://imagine.imgge.bg.ac.rs/handle/123456789/1757
AB  - An energy-efficient high throughput pre-treatment of low-density polyethylene (LDPE) using a fast, reactive extrusion (REX) assisted oxidation technique followed by bacterial attachment as an indicator for bio-amenability was studied. Silicon dioxide (SiO2) was selected as a model oxidizing and catalytic reagent with the REX process demonstrated to be effective both in the presence and absence of the catalyst. Optimized 5-min duration pre-treatment conditions were determined using Box-Behnken design (BBD) with respect to screws speed, operating temperature, and concentration of SiO2. The crystallinity index, carbonyl index and weight loss (%) of LDPE were used as the studied responses for BDD. FTIR and DSC spectra of the residual LDPE obtained after pre-treatment with the REX assisted oxidation technique showed a significant increase in residual LDPE carbonyl index from 0 to 1.04 and a decrease of LDPE crystallinity index from 29 to 18%. Up to fivefold molecular weight reductions were also demonstrated using gel permeation chromatography. Optimum LDPE pre-treatment with a duration of 5 min was obtained at low screw speed (50 rpm), operating temperature of 380-390 degrees C and variable concentration of SiO2 (0 and 2% (w/w)) indicating that effective pre-treatment can occur under noncatalytic and catalysed conditions. Biofilms were successfully formed on pre-treated LDPE samples after 14 days of incubation. Furthermore, the technique proposed in this study is expected to provide a high throughput approach for pre-treatment of pervasive recalcitrant PE-based plastics to reduce their bio inertness.
PB  - Springer, New York
T2  - Journal of Polymers and the Environment
T1  - Rendering Bio-inert Low-Density Polyethylene Amenable for Biodegradation via Fast High Throughput Reactive Extrusion Assisted Oxidation
EP  - 2846
IS  - 7
SP  - 2837
VL  - 30
DO  - 10.1007/s10924-022-02400-w
ER  - 

@article{
author = "Ferrero, Pablo and Attallah, Olivia A. and Angel Valera, Miguel and Aleksić, Ivana and Azeem, Muhammad and Nikodinović-Runić, Jasmina and Fournet, Margaret Brennan",
year = "2022",
abstract = "An energy-efficient high throughput pre-treatment of low-density polyethylene (LDPE) using a fast, reactive extrusion (REX) assisted oxidation technique followed by bacterial attachment as an indicator for bio-amenability was studied. Silicon dioxide (SiO2) was selected as a model oxidizing and catalytic reagent with the REX process demonstrated to be effective both in the presence and absence of the catalyst. Optimized 5-min duration pre-treatment conditions were determined using Box-Behnken design (BBD) with respect to screws speed, operating temperature, and concentration of SiO2. The crystallinity index, carbonyl index and weight loss (%) of LDPE were used as the studied responses for BDD. FTIR and DSC spectra of the residual LDPE obtained after pre-treatment with the REX assisted oxidation technique showed a significant increase in residual LDPE carbonyl index from 0 to 1.04 and a decrease of LDPE crystallinity index from 29 to 18%. Up to fivefold molecular weight reductions were also demonstrated using gel permeation chromatography. Optimum LDPE pre-treatment with a duration of 5 min was obtained at low screw speed (50 rpm), operating temperature of 380-390 degrees C and variable concentration of SiO2 (0 and 2% (w/w)) indicating that effective pre-treatment can occur under noncatalytic and catalysed conditions. Biofilms were successfully formed on pre-treated LDPE samples after 14 days of incubation. Furthermore, the technique proposed in this study is expected to provide a high throughput approach for pre-treatment of pervasive recalcitrant PE-based plastics to reduce their bio inertness.",
publisher = "Springer, New York",
journal = "Journal of Polymers and the Environment",
title = "Rendering Bio-inert Low-Density Polyethylene Amenable for Biodegradation via Fast High Throughput Reactive Extrusion Assisted Oxidation",
pages = "2846-2837",
number = "7",
volume = "30",
doi = "10.1007/s10924-022-02400-w"
}

Ferrero, P., Attallah, O. A., Angel Valera, M., Aleksić, I., Azeem, M., Nikodinović-Runić, J.,& Fournet, M. B.. (2022). Rendering Bio-inert Low-Density Polyethylene Amenable for Biodegradation via Fast High Throughput Reactive Extrusion Assisted Oxidation. in Journal of Polymers and the Environment
Springer, New York., 30(7), 2837-2846.
https://doi.org/10.1007/s10924-022-02400-w

Ferrero P, Attallah OA, Angel Valera M, Aleksić I, Azeem M, Nikodinović-Runić J, Fournet MB. Rendering Bio-inert Low-Density Polyethylene Amenable for Biodegradation via Fast High Throughput Reactive Extrusion Assisted Oxidation. in Journal of Polymers and the Environment. 2022;30(7):2837-2846.
doi:10.1007/s10924-022-02400-w .

Ferrero, Pablo, Attallah, Olivia A., Angel Valera, Miguel, Aleksić, Ivana, Azeem, Muhammad, Nikodinović-Runić, Jasmina, Fournet, Margaret Brennan, "Rendering Bio-inert Low-Density Polyethylene Amenable for Biodegradation via Fast High Throughput Reactive Extrusion Assisted Oxidation" in Journal of Polymers and the Environment, 30, no. 7 (2022):2837-2846,
https://doi.org/10.1007/s10924-022-02400-w . .

TY  - JOUR
AU  - Topakas, Evangelos
AU  - Nikodinović-Runić, Jasmina
AU  - Qi, Qingsheng
PY  - 2022
UR  - https://imagine.imgge.bg.ac.rs/handle/123456789/1590
PB  - Frontiers Media Sa, Lausanne
T2  - Frontiers in Bioengineering and Biotechnology
T1  - Editorial: Bio-Technological Processes and Enzymes for the Conversion and Valorization of Plastic Wastes
VL  - 10
DO  - 10.3389/fbioe.2022.873068
ER  - 

@article{
author = "Topakas, Evangelos and Nikodinović-Runić, Jasmina and Qi, Qingsheng",
year = "2022",
publisher = "Frontiers Media Sa, Lausanne",
journal = "Frontiers in Bioengineering and Biotechnology",
title = "Editorial: Bio-Technological Processes and Enzymes for the Conversion and Valorization of Plastic Wastes",
volume = "10",
doi = "10.3389/fbioe.2022.873068"
}

Topakas, E., Nikodinović-Runić, J.,& Qi, Q.. (2022). Editorial: Bio-Technological Processes and Enzymes for the Conversion and Valorization of Plastic Wastes. in Frontiers in Bioengineering and Biotechnology
Frontiers Media Sa, Lausanne., 10.
https://doi.org/10.3389/fbioe.2022.873068

Topakas E, Nikodinović-Runić J, Qi Q. Editorial: Bio-Technological Processes and Enzymes for the Conversion and Valorization of Plastic Wastes. in Frontiers in Bioengineering and Biotechnology. 2022;10.
doi:10.3389/fbioe.2022.873068 .

Topakas, Evangelos, Nikodinović-Runić, Jasmina, Qi, Qingsheng, "Editorial: Bio-Technological Processes and Enzymes for the Conversion and Valorization of Plastic Wastes" in Frontiers in Bioengineering and Biotechnology, 10 (2022),
https://doi.org/10.3389/fbioe.2022.873068 . .

TY  - JOUR
AU  - Nikolaivits, Efstratios
AU  - Taxeidis, George
AU  - Gkountela, Christina
AU  - Vouyiouka, Stamatina
AU  - Maslak, Veselin
AU  - Nikodinović-Runić, Jasmina
AU  - Topakas, Evangelos
PY  - 2022
UR  - https://imagine.imgge.bg.ac.rs/handle/123456789/1630
AB  - The uncontrolled release of plastics in the environment has rendered them ubiquitous around the planet, threatening the wildlife and human health. Biodegradation and valorization of plastics has emerged as an ecofriendly alternative to conventional management techniques. Discovery of novel polymer-degrading enzymes with diversified properties is hence an important task in order to explore different operational conditions for plastic-waste upcycling. In the present study, a barely studied psychrophilic enzyme (MoPE) from the Antractic bacterium Moraxella sp. was heterologously expressed, characterized and its potential in polymer degradation was further investigated. Based on its amino acid composition and structure, MoPE resembled PET-degrading enzymes, sharing features from both mesophilic and thermophilic homologues. MoPE hydrolyzes nonbiodegradable plastics, such as polyethylene terephthalate and polyurethane, as well as biodegradable
PB  - Elsevier, Amsterdam
T2  - Journal of Hazardous Materials
T1  - A polyesterase from the Antarctic bacterium Moraxella sp. degrades highly crystalline synthetic polymers
VL  - 434
DO  - 10.1016/j.jhazmat.2022.128900
ER  - 

@article{
author = "Nikolaivits, Efstratios and Taxeidis, George and Gkountela, Christina and Vouyiouka, Stamatina and Maslak, Veselin and Nikodinović-Runić, Jasmina and Topakas, Evangelos",
year = "2022",
abstract = "The uncontrolled release of plastics in the environment has rendered them ubiquitous around the planet, threatening the wildlife and human health. Biodegradation and valorization of plastics has emerged as an ecofriendly alternative to conventional management techniques. Discovery of novel polymer-degrading enzymes with diversified properties is hence an important task in order to explore different operational conditions for plastic-waste upcycling. In the present study, a barely studied psychrophilic enzyme (MoPE) from the Antractic bacterium Moraxella sp. was heterologously expressed, characterized and its potential in polymer degradation was further investigated. Based on its amino acid composition and structure, MoPE resembled PET-degrading enzymes, sharing features from both mesophilic and thermophilic homologues. MoPE hydrolyzes nonbiodegradable plastics, such as polyethylene terephthalate and polyurethane, as well as biodegradable",
publisher = "Elsevier, Amsterdam",
journal = "Journal of Hazardous Materials",
title = "A polyesterase from the Antarctic bacterium Moraxella sp. degrades highly crystalline synthetic polymers",
volume = "434",
doi = "10.1016/j.jhazmat.2022.128900"
}

Nikolaivits, E., Taxeidis, G., Gkountela, C., Vouyiouka, S., Maslak, V., Nikodinović-Runić, J.,& Topakas, E.. (2022). A polyesterase from the Antarctic bacterium Moraxella sp. degrades highly crystalline synthetic polymers. in Journal of Hazardous Materials
Elsevier, Amsterdam., 434.
https://doi.org/10.1016/j.jhazmat.2022.128900

Nikolaivits E, Taxeidis G, Gkountela C, Vouyiouka S, Maslak V, Nikodinović-Runić J, Topakas E. A polyesterase from the Antarctic bacterium Moraxella sp. degrades highly crystalline synthetic polymers. in Journal of Hazardous Materials. 2022;434.
doi:10.1016/j.jhazmat.2022.128900 .

Nikolaivits, Efstratios, Taxeidis, George, Gkountela, Christina, Vouyiouka, Stamatina, Maslak, Veselin, Nikodinović-Runić, Jasmina, Topakas, Evangelos, "A polyesterase from the Antarctic bacterium Moraxella sp. degrades highly crystalline synthetic polymers" in Journal of Hazardous Materials, 434 (2022),
https://doi.org/10.1016/j.jhazmat.2022.128900 . .

TY  - JOUR
AU  - Ferrero, Pablo
AU  - Attallah, Olivia A.
AU  - Angel Valera, Miguel
AU  - Aleksić, Ivana
AU  - Azeem, Muhammad
AU  - Nikodinović-Runić, Jasmina
AU  - Fournet, Margaret Brennan
PY  - 2022
UR  - https://imagine.imgge.bg.ac.rs/handle/123456789/1575
AB  - An energy-efficient high throughput pre-treatment of low-density polyethylene (LDPE) using a fast, reactive extrusion (REX) assisted oxidation technique followed by bacterial attachment as an indicator for bio-amenability was studied. Silicon dioxide (SiO2) was selected as a model oxidizing and catalytic reagent with the REX process demonstrated to be effective both in the presence and absence of the catalyst. Optimized 5-min duration pre-treatment conditions were determined using Box-Behnken design (BBD) with respect to screws speed, operating temperature, and concentration of SiO2. The crystallinity index, carbonyl index and weight loss (%) of LDPE were used as the studied responses for BDD. FTIR and DSC spectra of the residual LDPE obtained after pre-treatment with the REX assisted oxidation technique showed a significant increase in residual LDPE carbonyl index from 0 to 1.04 and a decrease of LDPE crystallinity index from 29 to 18%. Up to fivefold molecular weight reductions were also demonstrated using gel permeation chromatography. Optimum LDPE pre-treatment with a duration of 5 min was obtained at low screw speed (50 rpm), operating temperature of 380-390 degrees C and variable concentration of SiO2 (0 and 2% (w/w)) indicating that effective pre-treatment can occur under noncatalytic and catalysed conditions. Biofilms were successfully formed on pre-treated LDPE samples after 14 days of incubation. Furthermore, the technique proposed in this study is expected to provide a high throughput approach for pre-treatment of pervasive recalcitrant PE-based plastics to reduce their bio inertness.
PB  - Springer, New York
T2  - Journal of Polymers and the Environment
T1  - Rendering Bio-inert Low-Density Polyethylene Amenable for Biodegradation via Fast High Throughput Reactive Extrusion Assisted Oxidation
EP  - 2846
IS  - 7
SP  - 2837
VL  - 30
DO  - 10.1007/s10924-022-02400-w
ER  - 

@article{
author = "Ferrero, Pablo and Attallah, Olivia A. and Angel Valera, Miguel and Aleksić, Ivana and Azeem, Muhammad and Nikodinović-Runić, Jasmina and Fournet, Margaret Brennan",
year = "2022",
abstract = "An energy-efficient high throughput pre-treatment of low-density polyethylene (LDPE) using a fast, reactive extrusion (REX) assisted oxidation technique followed by bacterial attachment as an indicator for bio-amenability was studied. Silicon dioxide (SiO2) was selected as a model oxidizing and catalytic reagent with the REX process demonstrated to be effective both in the presence and absence of the catalyst. Optimized 5-min duration pre-treatment conditions were determined using Box-Behnken design (BBD) with respect to screws speed, operating temperature, and concentration of SiO2. The crystallinity index, carbonyl index and weight loss (%) of LDPE were used as the studied responses for BDD. FTIR and DSC spectra of the residual LDPE obtained after pre-treatment with the REX assisted oxidation technique showed a significant increase in residual LDPE carbonyl index from 0 to 1.04 and a decrease of LDPE crystallinity index from 29 to 18%. Up to fivefold molecular weight reductions were also demonstrated using gel permeation chromatography. Optimum LDPE pre-treatment with a duration of 5 min was obtained at low screw speed (50 rpm), operating temperature of 380-390 degrees C and variable concentration of SiO2 (0 and 2% (w/w)) indicating that effective pre-treatment can occur under noncatalytic and catalysed conditions. Biofilms were successfully formed on pre-treated LDPE samples after 14 days of incubation. Furthermore, the technique proposed in this study is expected to provide a high throughput approach for pre-treatment of pervasive recalcitrant PE-based plastics to reduce their bio inertness.",
publisher = "Springer, New York",
journal = "Journal of Polymers and the Environment",
title = "Rendering Bio-inert Low-Density Polyethylene Amenable for Biodegradation via Fast High Throughput Reactive Extrusion Assisted Oxidation",
pages = "2846-2837",
number = "7",
volume = "30",
doi = "10.1007/s10924-022-02400-w"
}

Ferrero, P., Attallah, O. A., Angel Valera, M., Aleksić, I., Azeem, M., Nikodinović-Runić, J.,& Fournet, M. B.. (2022). Rendering Bio-inert Low-Density Polyethylene Amenable for Biodegradation via Fast High Throughput Reactive Extrusion Assisted Oxidation. in Journal of Polymers and the Environment
Springer, New York., 30(7), 2837-2846.
https://doi.org/10.1007/s10924-022-02400-w

Ferrero P, Attallah OA, Angel Valera M, Aleksić I, Azeem M, Nikodinović-Runić J, Fournet MB. Rendering Bio-inert Low-Density Polyethylene Amenable for Biodegradation via Fast High Throughput Reactive Extrusion Assisted Oxidation. in Journal of Polymers and the Environment. 2022;30(7):2837-2846.
doi:10.1007/s10924-022-02400-w .

Ferrero, Pablo, Attallah, Olivia A., Angel Valera, Miguel, Aleksić, Ivana, Azeem, Muhammad, Nikodinović-Runić, Jasmina, Fournet, Margaret Brennan, "Rendering Bio-inert Low-Density Polyethylene Amenable for Biodegradation via Fast High Throughput Reactive Extrusion Assisted Oxidation" in Journal of Polymers and the Environment, 30, no. 7 (2022):2837-2846,
https://doi.org/10.1007/s10924-022-02400-w . .

TY  - JOUR
AU  - Nikolaivits, Efstratios
AU  - Taxeidis, George
AU  - Gkountela, Christina
AU  - Vouyiouka, Stamatina
AU  - Maslak, Veselin
AU  - Nikodinović-Runić, Jasmina
AU  - Topakas, Evangelos
PY  - 2022
UR  - https://imagine.imgge.bg.ac.rs/handle/123456789/1564
AB  - The uncontrolled release of plastics in the environment has rendered them ubiquitous around the planet, threatening the wildlife and human health. Biodegradation and valorization of plastics has emerged as an ecofriendly alternative to conventional management techniques. Discovery of novel polymer-degrading enzymes with diversified properties is hence an important task in order to explore different operational conditions for plastic-waste upcycling. In the present study, a barely studied psychrophilic enzyme (MoPE) from the Antractic bacterium Moraxella sp. was heterologously expressed, characterized and its potential in polymer degradation was further investigated. Based on its amino acid composition and structure, MoPE resembled PET-degrading enzymes, sharing features from both mesophilic and thermophilic homologues. MoPE hydrolyzes nonbiodegradable plastics, such as polyethylene terephthalate and polyurethane, as well as biodegradable
PB  - Elsevier, Amsterdam
T2  - Journal of Hazardous Materials
T1  - A polyesterase from the Antarctic bacterium Moraxella sp. degrades highly crystalline synthetic polymers
VL  - 434
DO  - 10.1016/j.jhazmat.2022.128900
ER  - 

@article{
author = "Nikolaivits, Efstratios and Taxeidis, George and Gkountela, Christina and Vouyiouka, Stamatina and Maslak, Veselin and Nikodinović-Runić, Jasmina and Topakas, Evangelos",
year = "2022",
abstract = "The uncontrolled release of plastics in the environment has rendered them ubiquitous around the planet, threatening the wildlife and human health. Biodegradation and valorization of plastics has emerged as an ecofriendly alternative to conventional management techniques. Discovery of novel polymer-degrading enzymes with diversified properties is hence an important task in order to explore different operational conditions for plastic-waste upcycling. In the present study, a barely studied psychrophilic enzyme (MoPE) from the Antractic bacterium Moraxella sp. was heterologously expressed, characterized and its potential in polymer degradation was further investigated. Based on its amino acid composition and structure, MoPE resembled PET-degrading enzymes, sharing features from both mesophilic and thermophilic homologues. MoPE hydrolyzes nonbiodegradable plastics, such as polyethylene terephthalate and polyurethane, as well as biodegradable",
publisher = "Elsevier, Amsterdam",
journal = "Journal of Hazardous Materials",
title = "A polyesterase from the Antarctic bacterium Moraxella sp. degrades highly crystalline synthetic polymers",
volume = "434",
doi = "10.1016/j.jhazmat.2022.128900"
}

Nikolaivits, E., Taxeidis, G., Gkountela, C., Vouyiouka, S., Maslak, V., Nikodinović-Runić, J.,& Topakas, E.. (2022). A polyesterase from the Antarctic bacterium Moraxella sp. degrades highly crystalline synthetic polymers. in Journal of Hazardous Materials
Elsevier, Amsterdam., 434.
https://doi.org/10.1016/j.jhazmat.2022.128900

Nikolaivits E, Taxeidis G, Gkountela C, Vouyiouka S, Maslak V, Nikodinović-Runić J, Topakas E. A polyesterase from the Antarctic bacterium Moraxella sp. degrades highly crystalline synthetic polymers. in Journal of Hazardous Materials. 2022;434.
doi:10.1016/j.jhazmat.2022.128900 .

Nikolaivits, Efstratios, Taxeidis, George, Gkountela, Christina, Vouyiouka, Stamatina, Maslak, Veselin, Nikodinović-Runić, Jasmina, Topakas, Evangelos, "A polyesterase from the Antarctic bacterium Moraxella sp. degrades highly crystalline synthetic polymers" in Journal of Hazardous Materials, 434 (2022),
https://doi.org/10.1016/j.jhazmat.2022.128900 . .

TY  - JOUR
AU  - Nikolaivits, Efstratios
AU  - Pantelić, Brana
AU  - Azeem, Muhammad
AU  - Taxeidis, George
AU  - Babu, Ramesh
AU  - Topakas, Evangelos
AU  - Fournet, Margaret Brennan
AU  - Nikodinović-Runić, Jasmina
PY  - 2021
UR  - https://imagine.imgge.bg.ac.rs/handle/123456789/1479
AB  - Inspirational concepts, and the transfer of analogs from natural biology to science and engineering, has produced many excellent technologies to date, spanning vaccines to modern architectural feats. This review highlights that answers to the pressing global petroleum-based plastic waste challenges, can be found within the mechanics and mechanisms natural ecosystems. Here, a suite of technological and engineering approaches, which can be implemented to operate in tandem with nature's prescription for regenerative material circularity, is presented as a route to plastics sustainability. A number of mechanical/green chemical (pre)treatment methodologies, which simulate natural weathering and arthropodal dismantling activities are reviewed, including: mechanical milling, reactive extrusion, ultrasonic-, UV- and degradation using supercritical CO2. Akin to natural mechanical degradation, the purpose of the pretreatments is to render the plastic materials more amenable to microbial and biocatalytic activities, to yield effective depolymerization and (re)valorization. While biotechnological based degradation and depolymerization of both recalcitrant and bioplastics are at a relatively early stage of development, the potential for acceleration and expedition of valuable output monomers and oligomers yields is considerable. To date a limited number of independent mechano-green chemical approaches and a considerable and growing number of standalone enzymatic and microbial degradation studies have been reported. A convergent strategy, one which forges mechano-green chemical treatments together with the enzymatic and microbial actions, is largely lacking at this time. An overview of the reported microbial and enzymatic degradations of petroleum-based synthetic polymer plastics, specifically: low-density polyethylene (LDPE), high-density polyethylene (HDPE), polystyrene (PS), polyethylene terephthalate (PET), polyurethanes (PU) and polycaprolactone (PCL) and selected prevalent bio-based or bio-polymers [polylactic acid (PLA), polyhydroxyalkanoates (PHAs) and polybutylene succinate (PBS)], is detailed. The harvesting of depolymerization products to produce new materials and higher-value products is also a key endeavor in effectively completing the circle for plastics. Our challenge is now to effectively combine and conjugate the requisite cross disciplinary approaches and progress the essential science and engineering technologies to categorically complete the life-cycle for plastics.
PB  - Frontiers Media Sa, Lausanne
T2  - Frontiers in Bioengineering and Biotechnology
T1  - Progressing Plastics Circularity: A Review of Mechano-Biocatalytic Approaches for Waste Plastic (Re)valorization
VL  - 9
DO  - 10.3389/fbioe.2021.696040
ER  - 

@article{
author = "Nikolaivits, Efstratios and Pantelić, Brana and Azeem, Muhammad and Taxeidis, George and Babu, Ramesh and Topakas, Evangelos and Fournet, Margaret Brennan and Nikodinović-Runić, Jasmina",
year = "2021",
abstract = "Inspirational concepts, and the transfer of analogs from natural biology to science and engineering, has produced many excellent technologies to date, spanning vaccines to modern architectural feats. This review highlights that answers to the pressing global petroleum-based plastic waste challenges, can be found within the mechanics and mechanisms natural ecosystems. Here, a suite of technological and engineering approaches, which can be implemented to operate in tandem with nature's prescription for regenerative material circularity, is presented as a route to plastics sustainability. A number of mechanical/green chemical (pre)treatment methodologies, which simulate natural weathering and arthropodal dismantling activities are reviewed, including: mechanical milling, reactive extrusion, ultrasonic-, UV- and degradation using supercritical CO2. Akin to natural mechanical degradation, the purpose of the pretreatments is to render the plastic materials more amenable to microbial and biocatalytic activities, to yield effective depolymerization and (re)valorization. While biotechnological based degradation and depolymerization of both recalcitrant and bioplastics are at a relatively early stage of development, the potential for acceleration and expedition of valuable output monomers and oligomers yields is considerable. To date a limited number of independent mechano-green chemical approaches and a considerable and growing number of standalone enzymatic and microbial degradation studies have been reported. A convergent strategy, one which forges mechano-green chemical treatments together with the enzymatic and microbial actions, is largely lacking at this time. An overview of the reported microbial and enzymatic degradations of petroleum-based synthetic polymer plastics, specifically: low-density polyethylene (LDPE), high-density polyethylene (HDPE), polystyrene (PS), polyethylene terephthalate (PET), polyurethanes (PU) and polycaprolactone (PCL) and selected prevalent bio-based or bio-polymers [polylactic acid (PLA), polyhydroxyalkanoates (PHAs) and polybutylene succinate (PBS)], is detailed. The harvesting of depolymerization products to produce new materials and higher-value products is also a key endeavor in effectively completing the circle for plastics. Our challenge is now to effectively combine and conjugate the requisite cross disciplinary approaches and progress the essential science and engineering technologies to categorically complete the life-cycle for plastics.",
publisher = "Frontiers Media Sa, Lausanne",
journal = "Frontiers in Bioengineering and Biotechnology",
title = "Progressing Plastics Circularity: A Review of Mechano-Biocatalytic Approaches for Waste Plastic (Re)valorization",
volume = "9",
doi = "10.3389/fbioe.2021.696040"
}

Nikolaivits, E., Pantelić, B., Azeem, M., Taxeidis, G., Babu, R., Topakas, E., Fournet, M. B.,& Nikodinović-Runić, J.. (2021). Progressing Plastics Circularity: A Review of Mechano-Biocatalytic Approaches for Waste Plastic (Re)valorization. in Frontiers in Bioengineering and Biotechnology
Frontiers Media Sa, Lausanne., 9.
https://doi.org/10.3389/fbioe.2021.696040

Nikolaivits E, Pantelić B, Azeem M, Taxeidis G, Babu R, Topakas E, Fournet MB, Nikodinović-Runić J. Progressing Plastics Circularity: A Review of Mechano-Biocatalytic Approaches for Waste Plastic (Re)valorization. in Frontiers in Bioengineering and Biotechnology. 2021;9.
doi:10.3389/fbioe.2021.696040 .

Nikolaivits, Efstratios, Pantelić, Brana, Azeem, Muhammad, Taxeidis, George, Babu, Ramesh, Topakas, Evangelos, Fournet, Margaret Brennan, Nikodinović-Runić, Jasmina, "Progressing Plastics Circularity: A Review of Mechano-Biocatalytic Approaches for Waste Plastic (Re)valorization" in Frontiers in Bioengineering and Biotechnology, 9 (2021),
https://doi.org/10.3389/fbioe.2021.696040 . .

TY  - JOUR
AU  - Pantelić, Brana
AU  - Ponjavić, Marijana
AU  - Janković, Vukašin
AU  - Aleksić, Ivana
AU  - Stevanović, Sanja
AU  - Murray, James
AU  - Fournet, Margaret Brennan
AU  - Nikodinović-Runić, Jasmina
PY  - 2021
UR  - https://imagine.imgge.bg.ac.rs/handle/123456789/1470
AB  - Meeting the challenge of circularity for plastics requires amenability to repurposing post-use, as equivalent or upcycled products. In a compelling advancement, complete circularity for a biodegradable polyvinyl alcohol/thermoplastic starch (PVA/TPS) food packaging film was demonstrated by bioconversion to high-market-value biopigments and polyhydroxybutyrate (PHB) polyesters. The PVA/TPS film mechanical properties (tensile strength (sigma(u)), 22.2 & PLUSMN; 4.3 MPa; strain at break (epsilon(u)), 325 & PLUSMN; 73%; and Young's modulus (E), 53-250 MPa) compared closely with low-density polyethylene (LDPE) grades used for food packaging. Strong solubility of the PVA/TPS film in water was a pertinent feature, facilitating suitability as a carbon source for bioprocessing and microbial degradation. Biodegradability of the film with greater than 50% weight loss occurred within 30 days of incubation at 37 & DEG;C in a model compost. Up to 22% of the PVA/TPS film substrate conversion to biomass was achieved using three bacterial strains, Ralstonia eutropha H16 (Cupriavidus necator ATCC 17699), Streptomyces sp. JS520, and Bacillus subtilis ATCC6633. For the first time, production of the valuable biopigment (undecylprodigiosin) by Streptomyces sp. JS520 of 5.3 mg/mL and the production of PHB biopolymer at 7.8% of cell dry weight by Ralstonia eutropha H16 from this substrate were reported. This low-energy, low-carbon post-use PVA/TPS film upcycling model approach to plastic circularity demonstrates marked progress in the quest for sustainable and circular plastic solutions.
PB  - MDPI, Basel
T2  - Polymers
T1  - Upcycling Biodegradable PVA/Starch Film to a Bacterial Biopigment and Biopolymer
IS  - 21
VL  - 13
DO  - 10.3390/polym13213692
ER  - 

@article{
author = "Pantelić, Brana and Ponjavić, Marijana and Janković, Vukašin and Aleksić, Ivana and Stevanović, Sanja and Murray, James and Fournet, Margaret Brennan and Nikodinović-Runić, Jasmina",
year = "2021",
abstract = "Meeting the challenge of circularity for plastics requires amenability to repurposing post-use, as equivalent or upcycled products. In a compelling advancement, complete circularity for a biodegradable polyvinyl alcohol/thermoplastic starch (PVA/TPS) food packaging film was demonstrated by bioconversion to high-market-value biopigments and polyhydroxybutyrate (PHB) polyesters. The PVA/TPS film mechanical properties (tensile strength (sigma(u)), 22.2 & PLUSMN; 4.3 MPa; strain at break (epsilon(u)), 325 & PLUSMN; 73%; and Young's modulus (E), 53-250 MPa) compared closely with low-density polyethylene (LDPE) grades used for food packaging. Strong solubility of the PVA/TPS film in water was a pertinent feature, facilitating suitability as a carbon source for bioprocessing and microbial degradation. Biodegradability of the film with greater than 50% weight loss occurred within 30 days of incubation at 37 & DEG;C in a model compost. Up to 22% of the PVA/TPS film substrate conversion to biomass was achieved using three bacterial strains, Ralstonia eutropha H16 (Cupriavidus necator ATCC 17699), Streptomyces sp. JS520, and Bacillus subtilis ATCC6633. For the first time, production of the valuable biopigment (undecylprodigiosin) by Streptomyces sp. JS520 of 5.3 mg/mL and the production of PHB biopolymer at 7.8% of cell dry weight by Ralstonia eutropha H16 from this substrate were reported. This low-energy, low-carbon post-use PVA/TPS film upcycling model approach to plastic circularity demonstrates marked progress in the quest for sustainable and circular plastic solutions.",
publisher = "MDPI, Basel",
journal = "Polymers",
title = "Upcycling Biodegradable PVA/Starch Film to a Bacterial Biopigment and Biopolymer",
number = "21",
volume = "13",
doi = "10.3390/polym13213692"
}

Pantelić, B., Ponjavić, M., Janković, V., Aleksić, I., Stevanović, S., Murray, J., Fournet, M. B.,& Nikodinović-Runić, J.. (2021). Upcycling Biodegradable PVA/Starch Film to a Bacterial Biopigment and Biopolymer. in Polymers
MDPI, Basel., 13(21).
https://doi.org/10.3390/polym13213692

Pantelić B, Ponjavić M, Janković V, Aleksić I, Stevanović S, Murray J, Fournet MB, Nikodinović-Runić J. Upcycling Biodegradable PVA/Starch Film to a Bacterial Biopigment and Biopolymer. in Polymers. 2021;13(21).
doi:10.3390/polym13213692 .

Pantelić, Brana, Ponjavić, Marijana, Janković, Vukašin, Aleksić, Ivana, Stevanović, Sanja, Murray, James, Fournet, Margaret Brennan, Nikodinović-Runić, Jasmina, "Upcycling Biodegradable PVA/Starch Film to a Bacterial Biopigment and Biopolymer" in Polymers, 13, no. 21 (2021),
https://doi.org/10.3390/polym13213692 . .