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DOI: 10.4121/7b56b29c-eeac-4536-95d8-eb8927aba78c

Jin, Yong; Beckmans, Ralf; de Leeuw, Kasper D.; Strik, David (2025): Data underlying the research of Efficient Hydrothermal Pretreatment of Mixed PHA/PLA and Consequent Continuous Anaerobic Fermentation into VFA. Version 1. 4TU.ResearchData. dataset. https://doi.org/10.4121/7b56b29c-eeac-4536-95d8-eb8927aba78c.v1

Categories

• Environmental Biotechnology
• Environmental Engineering
• Chemical Engineering
• Engineering
• Technology

Keywords

biobased biodegradable plastics chain elongation hydrothermal processing microbial community analysis mixed bioplastic conversion open-culture fermentation

Licence

CC BY 4.0

Interoperability

• RO-Crate Metadata

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by Yong Jin , Ralf Beckmans, Kasper D. de Leeuw, David Strik

Recycling biobased biodegradable plastics such as polyhydroxyalkanoates (PHA) and polylactic acid (PLA) is essential for developing a circular economy. This study presents an integrated strategy that combines batch hydrothermal processing at 150℃ with continuous open-culture fermentation to convert PHA and PLA into C₂-C₆ carboxylates. Co-hydrolysis in a carboxylic acid solution significantly enhanced PHA depolymerization compared to PHA hydrolysis alone. Among various catalytical supplements, PLA addition notably improved PHA hydrolysis, achieving up to 91% dissolution. Throughout fermentation, acetate and n-butyrate were the primary products. In Phase VI, co-fermentation of PHA hydrolysates (~10 g/L 3-hydroxybutyrate) and PLA hydrolysates (5 g/L lactate) yielded acetate (4.4 g/L), n-butyrate (8.0 g/L), and n-caproate (0.3 g/L), while also reducing the need for KOH for pH control. An overall conversion efficiency of 89% from bioplastics to carboxylates was achieved, with a high n-butyrate selectivity of 71%. Supplementing with ethanol (7 g/L) further enhanced chain elongation, increasing n-butyrate concentration to 10.1 g/L, although excess ethanol oxidation was observed. This study demonstrates, for the first time, the successful continuous open-culture fermentation of PHA and PLA hydrolysates into carboxylates. Microbial community analysis identified Clostridium tyrobutyricum as a key species likely responsible for dominant n-butyrate production.

History

• 2025-07-18 first online, published, posted

Publisher

4TU.ResearchData

Format

xlsx/txt

Funding

• China Scholarship Council (CSC)

Organizations

Environmental Technology, Agrotechnology and Food Sciences Group, Wageningen University & Research