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Conversion of bioplastics into poly(3-hydroxybutyrate) via thermochemical depolymerisation and fermentation: A model for post-consumer waste recycling

Chrysanthi Argeiti, Ioannis Marios Iliopoulos, Konstantina Iliopoulou, Anestis Vlysidis, Erminta Tsouko, Apostolis Koutinas

2025Bioresource Technology6 citationsDOIOpen Access PDF

Abstract

This study investigates the thermochemical depolymerisation of commercial bioplastics – including pure poly(3-hydroxybutyrate) powder (PHB P ), PHB-based compounded pellets (PHB CP ) and polylactic acid (PLA) – followed by bioconversion of the resulting monomers into PHB by Paraburkholderia sacchari and Cupriavidus necator . Hydrothermal hydrolysates of PHB P and PHB CP at 200 °C and 5–6 h treatment resulted in 72.9–74.0 % 3-hydroxybutyric acid (3HB) and 21.9–27.1 % crotonic acid (CA) content, whereas PLA fully degraded into lactic acid at 140 °C. Alkaline treatment of PHB P and PHB CP resulted in higher CA:3HB ratio (0.52–0.65) than hydrothermal treatment (0.3–0.37). Shake-flask fermentations using PHB P (2.2 g PHB /L by P. sacchari ) or PLA (3.5 g PHB /L by C. necator ) hydrothermal hydrolysates showed higher polymer production than PHB CP hydrothermal and PHB P alkaline hydrolysates. Hydrothermal co-hydrolysates of PLA and PHB P reduced polymer production (ca. 1.4 g/L) by both strains. Benchmark shake flask fermentations using succinic acid and 1,4-butanediol – representative monomers of poly(butylene succinate) – showed that P. sacchari efficiently converted succinic acid to PHB (2.1 g/L), whereas 1,4-butanediol led to low bacterial growth and polymer formation. Bioreactor fed-batch fermentations with P. sacchari showed that a pH-stat feeding strategy with a concentrated hydrothermal PHB P hydrolysate led to 8.2 g PHB /L (54.8 % w/w intracellular content), 0.29 g/(L·h) productivity, 0.54 g/g yield and 356 kDa weight average molecular weight. This work highlights the importance of depolymerization strategy on hydrolysate composition and microbial conversion efficiency, identifies 3HB and LA as key recyclable monomers for PHB biosynthesis, and presents a framework for thermochemical recycling of post-consumer bioplastic wastes

Topics & Concepts

BioplasticHydrolysateDepolymerizationPolyhydroxybutyrateBioconversionPolylactic acidChemistrySuccinic acidLactic acidPolyhydroxyalkanoatesHydrothermal circulationOrganic chemistryChemical engineeringFermentationHydrolysisMonomerBioreactorNuclear chemistryIndustrial microbiologyMaterials scienceThermophileYield (engineering)BiochemistryBioprocessCupriavidus necatorbiodegradable polymer synthesis and propertiesMicroplastics and Plastic PollutionPolymer crystallization and properties
Conversion of bioplastics into poly(3-hydroxybutyrate) via thermochemical depolymerisation and fermentation: A model for post-consumer waste recycling | Litcius