Efficient Recycling of PET-PE Multilayer Packaging Materials Based on Enzymatic Depolymerization of PET

D.M. van Vliet; J.J. Mateman; R.H.A.M. van de Vondervoort; A.P.H.A. Moers; Lucas Collazo; M.W.T. Werten; S. Thiyagarajan; E.U. Thoden van Velzen; Juan Antonio Tamayo-Ramos; M.K. Julsing; T.A. Ewing

doi:10.1021/acssuschemeng.4c09388

Efficient Recycling of PET-PE Multilayer Packaging Materials Based on Enzymatic Depolymerization of PET

D.M. van Vliet, J.J. Mateman, R.H.A.M. van de Vondervoort, A.P.H.A. Moers, Lucas Collazo, M.W.T. Werten, S. Thiyagarajan, E.U. Thoden van Velzen, Juan Antonio Tamayo-Ramos, M.K. Julsing, T.A. Ewing^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

The transition to a sustainable, circular economy requires more plastic waste to be recycled into high-quality recycled plastics. However, it is challenging to recycle mixed waste fractions or common multilayer materials by using current mechanical recycling technology. Enzymatic hydrolysis potentially offers a solution because of its mild conditions and selectivity. In this study, we show that polyester hydrolases can be applied to recycle PET-PE multilayer packaging waste without costly amorphization pretreatment. Polyester hydrolases were produced by recombinant Pichia pastoris yeast and used to efficiently depolymerize the PET layer of PET-PE multilayer trays. High yields were obtained at laboratory scale with unpurified enzyme and high PET-PE loading (10–20% w/w PET-PE, ≥94% PET depolymerization, and ≥80% terephthalic acid recovery). The enzymatic reaction was scaled up to 4.5 kg of PET-PE production waste. After depolymerization (≥95% PET depolymerized), terephthalic acid was isolated and repolymerized into rPET. The remaining PE layer was recovered, treated with an alkaline cleaning step to remove residual PET contamination, and successfully reprocessed into rPE films with similar properties to virgin low-density PE. This study demonstrates the applicability of enzymatic hydrolysis for the recycling of PET-PE multilayer materials and highlights its general potential for the recycling of polyesters in mixed post-consumer waste.

Original language	Dutch
Pages (from-to)	8212-8219
Journal	ACS Sustainable Chemistry and Engineering
Volume	13
Issue number	22
Early online date	29 May 2025
DOIs	https://doi.org/10.1021/acssuschemeng.4c09388
Publication status	Published - 2025

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Cite this

van Vliet, D. M., Mateman, J. J., van de Vondervoort, R. H. A. M., Moers, A. P. H. A., Collazo, L., Werten, M. W. T., Thiyagarajan, S., Thoden van Velzen, E. U., Tamayo-Ramos, J. A., Julsing, M. K., & Ewing, T. A. (2025). Efficient Recycling of PET-PE Multilayer Packaging Materials Based on Enzymatic Depolymerization of PET. ACS Sustainable Chemistry and Engineering, 13(22), 8212-8219. https://doi.org/10.1021/acssuschemeng.4c09388

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title = "Efficient Recycling of PET-PE Multilayer Packaging Materials Based on Enzymatic Depolymerization of PET",

abstract = "The transition to a sustainable, circular economy requires more plastic waste to be recycled into high-quality recycled plastics. However, it is challenging to recycle mixed waste fractions or common multilayer materials by using current mechanical recycling technology. Enzymatic hydrolysis potentially offers a solution because of its mild conditions and selectivity. In this study, we show that polyester hydrolases can be applied to recycle PET-PE multilayer packaging waste without costly amorphization pretreatment. Polyester hydrolases were produced by recombinant Pichia pastoris yeast and used to efficiently depolymerize the PET layer of PET-PE multilayer trays. High yields were obtained at laboratory scale with unpurified enzyme and high PET-PE loading (10–20% w/w PET-PE, ≥94% PET depolymerization, and ≥80% terephthalic acid recovery). The enzymatic reaction was scaled up to 4.5 kg of PET-PE production waste. After depolymerization (≥95% PET depolymerized), terephthalic acid was isolated and repolymerized into rPET. The remaining PE layer was recovered, treated with an alkaline cleaning step to remove residual PET contamination, and successfully reprocessed into rPE films with similar properties to virgin low-density PE. This study demonstrates the applicability of enzymatic hydrolysis for the recycling of PET-PE multilayer materials and highlights its general potential for the recycling of polyesters in mixed post-consumer waste.",

keywords = "Polyester Hydrolase, Multilayer, PET-PE, Recycling, Enzymatic Hydrolysis, rPET",

author = "{van Vliet}, D.M. and J.J. Mateman and {van de Vondervoort}, R.H.A.M. and A.P.H.A. Moers and Lucas Collazo and M.W.T. Werten and S. Thiyagarajan and {Thoden van Velzen}, E.U. and Tamayo-Ramos, {Juan Antonio} and M.K. Julsing and T.A. Ewing",

year = "2025",

doi = "10.1021/acssuschemeng.4c09388",

language = "Nederlands",

volume = "13",

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publisher = "American Chemical Society",

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van Vliet, DM, Mateman, JJ, van de Vondervoort, RHAM, Moers, APHA, Collazo, L, Werten, MWT , Thiyagarajan, S , Thoden van Velzen, EU, Tamayo-Ramos, JA, Julsing, MK & Ewing, TA 2025, 'Efficient Recycling of PET-PE Multilayer Packaging Materials Based on Enzymatic Depolymerization of PET', ACS Sustainable Chemistry and Engineering, vol. 13, no. 22, pp. 8212-8219. https://doi.org/10.1021/acssuschemeng.4c09388

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T1 - Efficient Recycling of PET-PE Multilayer Packaging Materials Based on Enzymatic Depolymerization of PET

AU - van Vliet, D.M.

AU - Mateman, J.J.

AU - van de Vondervoort, R.H.A.M.

AU - Moers, A.P.H.A.

AU - Collazo, Lucas

AU - Werten, M.W.T.

AU - Thiyagarajan, S.

AU - Thoden van Velzen, E.U.

AU - Tamayo-Ramos, Juan Antonio

AU - Julsing, M.K.

AU - Ewing, T.A.

PY - 2025

Y1 - 2025

N2 - The transition to a sustainable, circular economy requires more plastic waste to be recycled into high-quality recycled plastics. However, it is challenging to recycle mixed waste fractions or common multilayer materials by using current mechanical recycling technology. Enzymatic hydrolysis potentially offers a solution because of its mild conditions and selectivity. In this study, we show that polyester hydrolases can be applied to recycle PET-PE multilayer packaging waste without costly amorphization pretreatment. Polyester hydrolases were produced by recombinant Pichia pastoris yeast and used to efficiently depolymerize the PET layer of PET-PE multilayer trays. High yields were obtained at laboratory scale with unpurified enzyme and high PET-PE loading (10–20% w/w PET-PE, ≥94% PET depolymerization, and ≥80% terephthalic acid recovery). The enzymatic reaction was scaled up to 4.5 kg of PET-PE production waste. After depolymerization (≥95% PET depolymerized), terephthalic acid was isolated and repolymerized into rPET. The remaining PE layer was recovered, treated with an alkaline cleaning step to remove residual PET contamination, and successfully reprocessed into rPE films with similar properties to virgin low-density PE. This study demonstrates the applicability of enzymatic hydrolysis for the recycling of PET-PE multilayer materials and highlights its general potential for the recycling of polyesters in mixed post-consumer waste.

AB - The transition to a sustainable, circular economy requires more plastic waste to be recycled into high-quality recycled plastics. However, it is challenging to recycle mixed waste fractions or common multilayer materials by using current mechanical recycling technology. Enzymatic hydrolysis potentially offers a solution because of its mild conditions and selectivity. In this study, we show that polyester hydrolases can be applied to recycle PET-PE multilayer packaging waste without costly amorphization pretreatment. Polyester hydrolases were produced by recombinant Pichia pastoris yeast and used to efficiently depolymerize the PET layer of PET-PE multilayer trays. High yields were obtained at laboratory scale with unpurified enzyme and high PET-PE loading (10–20% w/w PET-PE, ≥94% PET depolymerization, and ≥80% terephthalic acid recovery). The enzymatic reaction was scaled up to 4.5 kg of PET-PE production waste. After depolymerization (≥95% PET depolymerized), terephthalic acid was isolated and repolymerized into rPET. The remaining PE layer was recovered, treated with an alkaline cleaning step to remove residual PET contamination, and successfully reprocessed into rPE films with similar properties to virgin low-density PE. This study demonstrates the applicability of enzymatic hydrolysis for the recycling of PET-PE multilayer materials and highlights its general potential for the recycling of polyesters in mixed post-consumer waste.

KW - Polyester Hydrolase

KW - Multilayer

KW - PET-PE

KW - Recycling

KW - Enzymatic Hydrolysis

KW - rPET

U2 - 10.1021/acssuschemeng.4c09388

DO - 10.1021/acssuschemeng.4c09388

M3 - Article

SN - 2168-0485

VL - 13

SP - 8212

EP - 8219

JO - ACS Sustainable Chemistry and Engineering

JF - ACS Sustainable Chemistry and Engineering

IS - 22

ER -