Pretreatment of spiramycin fermentation residue by thermally activated peroxydisulfate for improving biodegradability: Insights into matrix disintegration and antibiotics degradation

•TAP effectively promoted the disintegration and solubilization of SFR.•The high level of residual SPM could be completely eliminated by TAP.•The antibacterial activity of SPM was greatly reduced after TAP treatment.•The Antibiotic resistance genes could be almost inactivated. Spiramycin fermentatio...

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Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2022-01, Vol.427, p.130973, Article 130973
Main Authors: Wang, Gang, Liu, Huiling, Wang, Jing, Gong, Picheng, Cai, Chen, Dai, Xiaohu, Wang, Peng
Format: Article
Language:English
Subjects:
Antibiotic resistance genes
Degradation
Disintegration
Spiramycin fermentation residue
Thermally activated peroxydisulfate
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Summary:•TAP effectively promoted the disintegration and solubilization of SFR.•The high level of residual SPM could be completely eliminated by TAP.•The antibacterial activity of SPM was greatly reduced after TAP treatment.•The Antibiotic resistance genes could be almost inactivated. Spiramycin fermentation residue (SFR) can be managed to recycle organic substances through bioprocesses. However, its rigid matrix structure and high residual antibiotic of spiramycin (SPM) are not conducive to the high efficiency of bioprocesses. The pretreatment of SFR by thermally activated peroxydisulfate (TAP) was first employed for improving its biodegradability by matrix structure disintegration and residual SPM degradation. The results demonstrated that the SFR were efficiently disintegrated to smaller particles. The effective destruction of SFR matrix structure was predicted by the release of carbohydrates and proteins, and was intuitively confirmed by scanning electron microscopy (SEM). The production of dissolved organic matters was clearly enhanced by TAP treatment, but the increment decreased with the increase of PDS dosage due to the mineralization of radicals. The degradation of SPM fitted to first-order kinetics model, and its degradation rate was promoted by increasing PDS dosage, increasing activation temperature and decreasing pH. The degradation pathway of SPM was mainly the separation of sugar groups (mycarose, mycaminose and forosamine) from the lactone ring, and the final oxidation product of SPM that have been identified was predicted to be harmless. The efficient and powerful TAP might be a suitable pretreatment approach for improving the biodegradability of SFR.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2021.130973