Refining Solid State Fermentation of Fusarium oxysporum for Enhanced Polyethylene Terephthalate Biodegradation Efficiency

Yogasri Chandren; Wan Zarina; Noor Fazreen; V Siracusa; I Blanco; V Pirillo; L Pollegioni; G Molla; W Wan Zarina; F Noor Fazreen; M; R Nistic; E Melchor-Martnez; R Macas-Garbett; L Alvarado-Ramrez; R Arajo; J Sosa-Hernndez; D Ramrez-Gamboa; L Parra-Arroyo; A Alvarez; R Monteverde; K Cazares; A Reyes-Mayer; M Lino; R Parra-Saldvar; C Fernndez; M Castillo; S Prez; L Rodrguez; A Ekanayaka; S Tibpromma; D Dai; R Xu; N Suwannarach; S Stephenson; C Dao; S Karunarathna; S Ahmaditabatabaei; G Kyazze; H Iqbal; T Keshavarz; S Mahgoub; E Kedra; H Abdelfattah; H Abdelbasit; S Alamoudi; D Al-Quwaie; S Selim; S Alsharari; W Saber; R El-Mekkawy; J Ibarruri; I Goiri; M Cebrin; A Garca-Rodrguez; R Verduzco-Oliva; J Gutierrez-Uribe; J Liu; G Xu; W Dong; N Xu; F Xin; J Ma; Y Fang; J Zhou; M Jiang; N Mohanan; Z Montazer; P Sharma; D Levin; H Wei; Y Shang; S Zhang; L L; I Norazlina; K Ku Halim; S Abd Manaf; M Abu Bakar; M Yadav; M Kale; K Hicks; K Hanah; R Abi-Akl; E Ledieu; T Enke; O Cordero; T Cohen; F Martelli; M Cirlini; C Lazzi; E Neviani; V Bernini

doi:10.55373/mjchem.v27i3.272

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Refining Solid State Fermentation of Fusarium oxysporum for Enhanced Polyethylene Terephthalate Biodegradation Efficiency

Malaysian Journal of Chemistry 2025 1 citation ? Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count. Score: 43 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.

Yogasri Chandren, Wan Zarina, Noor Fazreen, V Siracusa, I Blanco, V Pirillo, L Pollegioni, G Molla, W Wan Zarina, F Noor Fazreen, M, R Nistic, E Melchor-Martnez, R Macas-Garbett, L Alvarado-Ramrez, R Arajo, J Sosa-Hernndez, D Ramrez-Gamboa, L Parra-Arroyo, A Alvarez, R Monteverde, K Cazares, A Reyes-Mayer, M Lino, R Parra-Saldvar, C Fernndez, M Castillo, S Prez, L Rodrguez, A Ekanayaka, S Tibpromma, D Dai, R Xu, N Suwannarach, S Stephenson, C Dao, S Karunarathna, S Ahmaditabatabaei, G Kyazze, H Iqbal, T Keshavarz, S Mahgoub, E Kedra, H Abdelfattah, H Abdelbasit, S Alamoudi, D Al-Quwaie, S Selim, S Alsharari, W Saber, R El-Mekkawy, J Ibarruri, I Goiri, M Cebrin, A Garca-Rodrguez, R Verduzco-Oliva, J Gutierrez-Uribe, J Liu, G Xu, W Dong, N Xu, F Xin, J Ma, Y Fang, J Zhou, M Jiang, N Mohanan, Z Montazer, P Sharma, D Levin, H Wei, Y Shang, S Zhang, L L, I Norazlina, K Ku Halim, S Abd Manaf, M Abu Bakar, M Yadav, M Kale, K Hicks, K Hanah, R Abi-Akl, E Ledieu, T Enke, O Cordero, T Cohen, F Martelli, M Cirlini, C Lazzi, E Neviani, V Bernini

Summary

PET plastic — the material in water bottles and food packaging — breaks down slowly in the environment, contributing to long-lasting microplastic pollution. This study optimized a solid-state fermentation process using the fungus Fusarium oxysporum to enhance its enzyme output and improve its ability to degrade PET plastic. Fine-tuning fungal biodegradation systems like this could offer a scalable biological approach to breaking down PET waste before it fragments into environmental microplastics.

Polymers

PE PET

Plastic pollution, especially from polyethylene terephthalate (PET), poses a serious environmental threat due to its extensive use and persistence in ecosystems.This research explores the enhancement of PET degradation using the fungus Fusarium oxysporum through solid-state fermentation (SSF).F. oxysporum was chosen for its known capacity to produce enzymes that can be a marker of complex polymer degradation.The SSF process was refined by adjusting key variables such as moisture content, fermentation weeks, and inoculum size.The effectiveness of degradation was tracked by assessing weight loss and the production of degradation by-products as enzymes.The results indicated that over four weeks, the weight loss of PET increased with higher volumes of F. oxysporum inoculum, reaching a peak weight loss of around 2.5% with 15 mL inoculum.Additionally, xylanase activity, a marker of enzymatic degradation, increased over time, with absorbance values nearing 0.45 U/mL at four weeks for both 10 and 15 mL inoculum volumes.These outcomes demonstrate that F. oxysporum, under optimized conditions, can substantially improve PET degradation, suggesting its potential in biodegradation efforts to combat plastic pollution.This study lays the groundwork for developing sustainable solutions to the growing issue of plastic waste in the environment.

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