Improving PAH-chronically contaminated soil bioremediation using a combined strategy of bioaugmentation and surfactant-enhanced biostimulation

Aged polycyclic aromatic hydrocarbon (PAH)-contaminated soil represents a challenge for the application of an effective bioremediation strategy, as the low PAH bioavailability limits microbial degradation. This study aimed to compare the effect of bioaugmentation (BA) and the coupled strategy of bioaugmentation and biostimulation (BA-SEB) on a chronically hydrocarbon-contaminated soil (IPK). For BA, we compared the performance of three PAH-degrading consortia with increasing diversity: SC AMBk, SC1, SC4. For BA-SEB, we coupled inoculation with these consortia with the addition of Triton X-100 surfactant, at sub-critical micelle concentration dose. In the BA microcosms, inoculation did not result in significant degradation of the determined PAH after 58 days of incubation. Among the BA-SEB microcosms, SC4 inoculated ones and the non-inoculated control showed significant degradation of fluoranthene, chrysene, and pyrene during the incubation period. Notably, BA-SEB microcosms inoculated with SC4 achieved superior pyrene degradation compared to the others. Both inoculation and the addition of surfactant impacted the community assembly, with the surfactant exerting the major effects. The surfactant addition stimulated several genera related to the degradation of PAH ( Novosphingobium, Blastomonas ). In addition, co-occurrence network analysis revealed that in SC4 inoculated microcosms most of these genera were positively correlated with the inoculated genera, particularly with Paraburkholdeira genus. The application of the combined strategy using the SC4 consortium in IPK soil successfully stimulated PAH biodegradation, demonstrating the importance of inoculant diversity and the identity of the consortium members under increased stress conditions (i.e from acute to aged contamination) for the strategy’s success.