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Recycling facilities are currently struggling when dealing with challenging plastic multi-layers, blends, and additives.
Consequently, packaging plastics are mostly landfilled, incinerated or spilled into the environment. The concept of UPLIFT is to introduce biological depolymerization technology as an addition and integration to established recycling practices, by converting persistent plastic waste into more easily recyclable and/or degradable polymers. The project will start by analyzing the value-chains of the future to match and exploit the potential of microbe-and enzyme technology to effectively depolymerize the EoL plastic into monomers. Overall, the project aims at engineering towards greater scale and efficiency.
Moreover, in order to contribute to further innovation, UPLIFT will also make use of an advanced high-throughput screening platform to further explore the potential of new and more efficient biocatalysts, among bacteria, yeasts and fungi. Synergies between genetic and protein engineering, as well as eco-engineering of microbial mixed consortia will be under Uplift’s scope. Furthermore, the knowledge of bio-depolymerization will be strategically applied for the eco-design and development of renewable and easy-recyclable polymers, thus making plastic packaging an available feedstock for the circular economy.
Introducing biological depolymerization to current recycling practices will increase the capability of dealing with large amounts of currently non-recycled plastics. By doing so, UPLIFT will contribute and facilitate the transition to more efficient recycling facilities, thus paving the way to a sustainable plastic system.
Consequently, packaging plastics are mostly landfilled, incinerated or spilled into the environment. The concept of UPLIFT is to introduce biological depolymerization technology as an addition and integration to established recycling practices, by converting persistent plastic waste into more easily recyclable and/or degradable polymers. The project will start by analyzing the value-chains of the future to match and exploit the potential of microbe-and enzyme technology to effectively depolymerize the EoL plastic into monomers. Overall, the project aims at engineering towards greater scale and efficiency.
Moreover, in order to contribute to further innovation, UPLIFT will also make use of an advanced high-throughput screening platform to further explore the potential of new and more efficient biocatalysts, among bacteria, yeasts and fungi. Synergies between genetic and protein engineering, as well as eco-engineering of microbial mixed consortia will be under Uplift’s scope. Furthermore, the knowledge of bio-depolymerization will be strategically applied for the eco-design and development of renewable and easy-recyclable polymers, thus making plastic packaging an available feedstock for the circular economy.
Introducing biological depolymerization to current recycling practices will increase the capability of dealing with large amounts of currently non-recycled plastics. By doing so, UPLIFT will contribute and facilitate the transition to more efficient recycling facilities, thus paving the way to a sustainable plastic system.
Kort titel | UPLIFT |
---|---|
Akronym | UPLIFT |
Status | Igangværende |
Effektiv start/slut dato | 01/02/2021 → 28/02/2025 |
Finansiering
- Horizon Europe: 55.950.000,00 kr.
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Projekter
- 1 Igangværende
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Microbial consortia-mediated polyolefins biodegradation
Lomwongsopon, P. & Varrone, C.
25/10/2021 → 25/10/2024
Projekter: Projekt › Ph.d.-projekt
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Development of microbial consortia for valorizing post-consumer polyethylene via thermal-biological process: The Plastic Biorefinery
Lomwongsopon, P. & Varrone, C., jun. 2023.Publikation: Konferencebidrag uden forlag/tidsskrift › Poster › Forskning › peer review
Fil24 Downloads (Pure) -
Contribution of Fermentation Technology to Building Blocks for Renewable Plastics
Lomwongsopon, P. & Varrone, C., 15 jan. 2022, I: Fermentation. 8, 2, 47.Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review
Åben adgangFil11 Citationer (Scopus)147 Downloads (Pure) -
Critical Review on the Progress of Plastic Bioupcycling Technology as a Potential Solution for Sustainable Plastic Waste Management
Lomwongsopon, P. & Varrone, C., 18 nov. 2022, I: Polymers. 14, 22, 4996.Publikation: Bidrag til tidsskrift › Review (oversigtsartikel) › peer review
Åben adgangFil9 Citationer (Scopus)74 Downloads (Pure)
Presse/medier
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Connection between EU projects on plastic biodegradation and upcycling
04/01/2021
1 Mediebidrag
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NYT RESEARCH-PROJEKT VIL TRANSFORMERE PLASTIKINDUSTRIEN
30/10/2020
1 element af Mediedækning
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