Exploring biotechnology for plastic recycling, degradation and upcycling for a sustainable future

Xu Liu; Helen Park; Yannic Sebastian Ackermann; Luc Avérous; Hendrik Ballerstedt; Werner Besenmatter; Blas Blázquez; Uwe T. Bornscheuer; Yannick Branson; William Casey; Víctor de Lorenzo; Weiliang Dong; Tilman Floehr; Manuel S. Godoy; Yu Ji; Andreas Jupke; Jürgen Klankermayer; David San León; Luo Liu; Xianrui Liu; Yizhi Liu; Maria T. Manoli; Esteban Martínez-García; Tanja Narancic; Juan Nogales; Kevin O'Connor; Ole Osterthun; Rémi Perrin; M. Auxiliadora Prieto; Eric Pollet; Alexandru Sarbu; Ulrich Schwaneberg; Haijia Su; Zequn Tang; Till Tiso; Zishuai Wang; Ren Wei; Gina Welsing; Nick Wierckx; Birger Wolter; Gang Xiao; Jianmin Xing; Yilin Zhao; Jie Zhou; Tianwei Tan; Lars M. Blank; Min Jiang; Guo Qiang Chen

doi:10.1016/j.biotechadv.2025.108544

Exploring biotechnology for plastic recycling, degradation and upcycling for a sustainable future

Xu Liu, Helen Park, Yannic Sebastian Ackermann, Luc Avérous, Hendrik Ballerstedt, Werner Besenmatter, Blas Blázquez, Uwe T. Bornscheuer, Yannick Branson, William Casey, Víctor de Lorenzo, Weiliang Dong, Tilman Floehr, Manuel S. Godoy, Yu Ji, Andreas Jupke, Jürgen Klankermayer, David San León, Luo Liu, Xianrui LiuYizhi Liu, Maria T. Manoli, Esteban Martínez-García, Tanja Narancic, Juan Nogales, Kevin O'Connor, Ole Osterthun, Rémi Perrin, M. Auxiliadora Prieto, Eric Pollet, Alexandru Sarbu, Ulrich Schwaneberg, Haijia Su, Zequn Tang, Till Tiso, Zishuai Wang, Ren Wei, Gina Welsing, Nick Wierckx, Birger Wolter, Gang Xiao, Jianmin Xing, Yilin Zhao, Jie Zhou, Tianwei Tan, Lars M. Blank, Min Jiang, Guo Qiang Chen

COLLEGE OF BIOTECHNOLOGY AND PHARMACEUTICAL ENGINEERING

Research output: Contribution to journal › Review article › peer-review

Abstract

The persistent demand for plastic commodities, inadequate recycling infrastructure, and pervasive environmental contamination due to plastic waste present a formidable global challenge. Recycling, degradation and upcycling are the three most important ways to solve the problem of plastic pollution. Sequential enzymatic and microbial degradation of mechanically and chemically pre-treated plastic waste can be orchestrated, followed by microbial conversion into value-added chemicals and polymers through mixed culture systems. Furthermore, plastics-degrading enzymes can be optimized through protein engineering to enhance their specific binding capacities, stability, and catalytic efficiency across a broad spectrum of polymer substrates under challenging high salinity and temperature conditions. Also, the production and formulation of enzyme mixtures can be fine-tuned to suit specific waste compositions, facilitating their effective deployment both in vitro, in vivo and in combination with chemical technologies. Here, we emphasized the comprehensive strategy leveraging microbial processes to transform mixed plastics of fossil-derived polymers such as PP, PE, PU, PET, and PS, most notably polyesters, in conjunction with potential biodegradable alternatives such as PLA and PHA. Any residual material resistant to enzymatic degradation can be reintroduced into the process loop following appropriate physicochemical treatment.

Original language	English
Article number	108544
Journal	Biotechnology Advances
Volume	81
DOIs	https://doi.org/10.1016/j.biotechadv.2025.108544
State	Published - 1 Jul 2025

Keywords

Biocatalytic plastic degradation
Biodegradable materials
Circular economy
Enzymatic recycling
Microbial depolymerization
Plastic degradation
Polyethylene terephthalate (PET)
Polyhydroxyalkanoate (PHA)

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.biotechadv.2025.108544

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Liu, X., Park, H., Ackermann, Y. S., Avérous, L., Ballerstedt, H., Besenmatter, W., Blázquez, B., Bornscheuer, U. T., Branson, Y., Casey, W., de Lorenzo, V., Dong, W., Floehr, T., Godoy, M. S., Ji, Y., Jupke, A., Klankermayer, J., León, D. S., Liu, L., ... Chen, G. Q. (2025). Exploring biotechnology for plastic recycling, degradation and upcycling for a sustainable future. Biotechnology Advances, 81, Article 108544. https://doi.org/10.1016/j.biotechadv.2025.108544

@article{f7cd71573d8b435f843265367ad3d959,

title = "Exploring biotechnology for plastic recycling, degradation and upcycling for a sustainable future",

abstract = "The persistent demand for plastic commodities, inadequate recycling infrastructure, and pervasive environmental contamination due to plastic waste present a formidable global challenge. Recycling, degradation and upcycling are the three most important ways to solve the problem of plastic pollution. Sequential enzymatic and microbial degradation of mechanically and chemically pre-treated plastic waste can be orchestrated, followed by microbial conversion into value-added chemicals and polymers through mixed culture systems. Furthermore, plastics-degrading enzymes can be optimized through protein engineering to enhance their specific binding capacities, stability, and catalytic efficiency across a broad spectrum of polymer substrates under challenging high salinity and temperature conditions. Also, the production and formulation of enzyme mixtures can be fine-tuned to suit specific waste compositions, facilitating their effective deployment both in vitro, in vivo and in combination with chemical technologies. Here, we emphasized the comprehensive strategy leveraging microbial processes to transform mixed plastics of fossil-derived polymers such as PP, PE, PU, PET, and PS, most notably polyesters, in conjunction with potential biodegradable alternatives such as PLA and PHA. Any residual material resistant to enzymatic degradation can be reintroduced into the process loop following appropriate physicochemical treatment.",

keywords = "Biocatalytic plastic degradation, Biodegradable materials, Circular economy, Enzymatic recycling, Microbial depolymerization, Plastic degradation, Polyethylene terephthalate (PET), Polyhydroxyalkanoate (PHA)",

author = "Xu Liu and Helen Park and Ackermann, {Yannic Sebastian} and Luc Av{\'e}rous and Hendrik Ballerstedt and Werner Besenmatter and Blas Bl{\'a}zquez and Bornscheuer, {Uwe T.} and Yannick Branson and William Casey and {de Lorenzo}, V{\'i}ctor and Weiliang Dong and Tilman Floehr and Godoy, {Manuel S.} and Yu Ji and Andreas Jupke and J{\"u}rgen Klankermayer and Le{\'o}n, {David San} and Luo Liu and Xianrui Liu and Yizhi Liu and Manoli, {Maria T.} and Esteban Mart{\'i}nez-Garc{\'i}a and Tanja Narancic and Juan Nogales and Kevin O'Connor and Ole Osterthun and R{\'e}mi Perrin and Prieto, {M. Auxiliadora} and Eric Pollet and Alexandru Sarbu and Ulrich Schwaneberg and Haijia Su and Zequn Tang and Till Tiso and Zishuai Wang and Ren Wei and Gina Welsing and Nick Wierckx and Birger Wolter and Gang Xiao and Jianmin Xing and Yilin Zhao and Jie Zhou and Tianwei Tan and Blank, {Lars M.} and Min Jiang and Chen, {Guo Qiang}",

note = "Publisher Copyright: {\textcopyright} 2025 Elsevier Inc.",

year = "2025",

month = jul,

day = "1",

doi = "10.1016/j.biotechadv.2025.108544",

language = "英语",

volume = "81",

journal = "Biotechnology Advances",

issn = "0734-9750",

publisher = "Elsevier Inc.",

}

Liu, X, Park, H, Ackermann, YS, Avérous, L, Ballerstedt, H, Besenmatter, W, Blázquez, B, Bornscheuer, UT, Branson, Y, Casey, W, de Lorenzo, V, Dong, W, Floehr, T, Godoy, MS, Ji, Y, Jupke, A, Klankermayer, J, León, DS, Liu, L, Liu, X, Liu, Y, Manoli, MT, Martínez-García, E, Narancic, T, Nogales, J, O'Connor, K, Osterthun, O, Perrin, R, Prieto, MA, Pollet, E, Sarbu, A, Schwaneberg, U, Su, H, Tang, Z, Tiso, T, Wang, Z, Wei, R, Welsing, G, Wierckx, N, Wolter, B, Xiao, G, Xing, J, Zhao, Y, Zhou, J, Tan, T, Blank, LM, Jiang, M & Chen, GQ 2025, 'Exploring biotechnology for plastic recycling, degradation and upcycling for a sustainable future', Biotechnology Advances, vol. 81, 108544. https://doi.org/10.1016/j.biotechadv.2025.108544

TY - JOUR

T1 - Exploring biotechnology for plastic recycling, degradation and upcycling for a sustainable future

AU - Liu, Xu

AU - Park, Helen

AU - Ackermann, Yannic Sebastian

AU - Avérous, Luc

AU - Ballerstedt, Hendrik

AU - Besenmatter, Werner

AU - Blázquez, Blas

AU - Bornscheuer, Uwe T.

AU - Branson, Yannick

AU - Casey, William

AU - de Lorenzo, Víctor

AU - Dong, Weiliang

AU - Floehr, Tilman

AU - Godoy, Manuel S.

AU - Ji, Yu

AU - Jupke, Andreas

AU - Klankermayer, Jürgen

AU - León, David San

AU - Liu, Luo

AU - Liu, Xianrui

AU - Liu, Yizhi

AU - Manoli, Maria T.

AU - Martínez-García, Esteban

AU - Narancic, Tanja

AU - Nogales, Juan

AU - O'Connor, Kevin

AU - Osterthun, Ole

AU - Perrin, Rémi

AU - Prieto, M. Auxiliadora

AU - Pollet, Eric

AU - Sarbu, Alexandru

AU - Schwaneberg, Ulrich

AU - Su, Haijia

AU - Tang, Zequn

AU - Tiso, Till

AU - Wang, Zishuai

AU - Wei, Ren

AU - Welsing, Gina

AU - Wierckx, Nick

AU - Wolter, Birger

AU - Xiao, Gang

AU - Xing, Jianmin

AU - Zhao, Yilin

AU - Zhou, Jie

AU - Tan, Tianwei

AU - Blank, Lars M.

AU - Jiang, Min

AU - Chen, Guo Qiang

PY - 2025/7/1

Y1 - 2025/7/1

N2 - The persistent demand for plastic commodities, inadequate recycling infrastructure, and pervasive environmental contamination due to plastic waste present a formidable global challenge. Recycling, degradation and upcycling are the three most important ways to solve the problem of plastic pollution. Sequential enzymatic and microbial degradation of mechanically and chemically pre-treated plastic waste can be orchestrated, followed by microbial conversion into value-added chemicals and polymers through mixed culture systems. Furthermore, plastics-degrading enzymes can be optimized through protein engineering to enhance their specific binding capacities, stability, and catalytic efficiency across a broad spectrum of polymer substrates under challenging high salinity and temperature conditions. Also, the production and formulation of enzyme mixtures can be fine-tuned to suit specific waste compositions, facilitating their effective deployment both in vitro, in vivo and in combination with chemical technologies. Here, we emphasized the comprehensive strategy leveraging microbial processes to transform mixed plastics of fossil-derived polymers such as PP, PE, PU, PET, and PS, most notably polyesters, in conjunction with potential biodegradable alternatives such as PLA and PHA. Any residual material resistant to enzymatic degradation can be reintroduced into the process loop following appropriate physicochemical treatment.

AB - The persistent demand for plastic commodities, inadequate recycling infrastructure, and pervasive environmental contamination due to plastic waste present a formidable global challenge. Recycling, degradation and upcycling are the three most important ways to solve the problem of plastic pollution. Sequential enzymatic and microbial degradation of mechanically and chemically pre-treated plastic waste can be orchestrated, followed by microbial conversion into value-added chemicals and polymers through mixed culture systems. Furthermore, plastics-degrading enzymes can be optimized through protein engineering to enhance their specific binding capacities, stability, and catalytic efficiency across a broad spectrum of polymer substrates under challenging high salinity and temperature conditions. Also, the production and formulation of enzyme mixtures can be fine-tuned to suit specific waste compositions, facilitating their effective deployment both in vitro, in vivo and in combination with chemical technologies. Here, we emphasized the comprehensive strategy leveraging microbial processes to transform mixed plastics of fossil-derived polymers such as PP, PE, PU, PET, and PS, most notably polyesters, in conjunction with potential biodegradable alternatives such as PLA and PHA. Any residual material resistant to enzymatic degradation can be reintroduced into the process loop following appropriate physicochemical treatment.

KW - Biocatalytic plastic degradation

KW - Biodegradable materials

KW - Circular economy

KW - Enzymatic recycling

KW - Microbial depolymerization

KW - Plastic degradation

KW - Polyethylene terephthalate (PET)

KW - Polyhydroxyalkanoate (PHA)

UR - http://www.scopus.com/inward/record.url?scp=105000171441&partnerID=8YFLogxK

U2 - 10.1016/j.biotechadv.2025.108544

DO - 10.1016/j.biotechadv.2025.108544

M3 - 文献综述

AN - SCOPUS:105000171441

SN - 0734-9750

VL - 81

JO - Biotechnology Advances

JF - Biotechnology Advances

M1 - 108544

ER -

Exploring biotechnology for plastic recycling, degradation and upcycling for a sustainable future

Abstract

Keywords

UN SDGs

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