Impact of heat and chloramphenicol pretreatments on sludge anaerobic bioconversion: Insights into physicochemical and microbial disruption

This study examines impact of heat and chloramphenicol pretreatments on sludge characteristics to improve anaerobic bioconversion under mesophilic conditions. Physicochemical, microbial, and biogas analyses were conducted to evaluate the effect of each pretreatment. Elemental composition analysis revealed that chloramphenicol pretreatment reduced the C/N ratio to 12.8 ± 0.18, whereas heat treatment maintained a more balanced ratio of 15.0 ± 0.12, compared to 13.83 in the control. Macromolecular analysis revealed extensive microbial lysis in chloramphenicol-treated sludge, reflected by significant increases in protein (43.5 ± 0.6 %) and lipid (12.0 ± 0.5 %) contents, whereas moderate changes were observed in heat-pretreated samples. The lowest VS/TS ratio (0.60 ± 0.02) in the chloramphenicol group indicated enhanced organic solubility. Biogas assays revealed that heat-pretreated sludge produced the highest cumulative yield (35.0 mL/g VS) and CH₄ content (61 %), while chloramphenicol treatment yielded slightly less gas (33.0 mL/g VS) but with an elevated H₂ content (18 %), higher than that of the control (20.4 mL/g VS). COD and TVFA reductions of 20.0 % and 77.8 %, respectively, were also notable under chloramphenicol stress. Microbial analysis revealed an enrichment of spore-forming Firmicutes following heat pretreatment and a hydrogenogenic shift toward Chloroflexi and Actinobacteriota under antibiotic stress. Overall, these findings demonstrated how targeted pretreatment alters sludge composition and microbial ecology to optimize biogas quality, particularly by enhancing hydrogen production for sustainable bioenergy recovery.