Non-immersed zigzag microalgae biofilm overcoming high turbidity and ammonia of wastewater for muti-pollutants bio-purification

Hormetic effect of dissolved organic matter from pig manure anaerobic digestion effluents on Chlorella sp.: Physiological and transcriptomic responses

Microalgae-based biotreatment offers a sustainable and efficient solution for managing pig manure anaerobic digestion effluents (PMADE), a byproduct of intensive agricultural practices. Dissolved organic matter (DOM) in PMADE significantly influences microalgal physiological responses; however, the underlying mechanisms remain poorly understood. Here, we reveal a hormetic effect of DOM in PMADE on Chlorella sp. Moderate DOM concentrations (1000-1500 mg/L of COD) alleviated ammonium toxicity and promoted microalgal growth, whereas higher concentrations (>2000 mg/L of COD) exerted severe inhibitory effects. Through cascade extraction and targeted screening, we identified distinct impacts of five DOM fractions on Chlorella sp. Notably, low-molecular-weight acids and nitrogenous compounds, primarily dipeptides in the fractions, exhibited a promoting effect on growth by serving as carbon sources to enhance energy metabolism and protein synthesis. Among the fractions, antioxidant-active compounds further supported the growth by scavenging reactive oxygen species (ROS) and maintaining redox homeostasis. In contrast, fractions rich in alkanes and alkaloids, induced excessive ROS production under high concentrations, leading to impaired photosynthesis and severe DNA damage. Additionally, the substances such as humic acid and fulvic acid, as key components of PMADE, exhibited hormetic effects: at specific concentrations (humic acid<200 mg TOC/L; fulvic acid<100 mg TOC/L), they enhanced ROS scavenging, growth, photosynthesis and pigment accumulation, whereas exceeding these thresholds shifted their role from promotion to inhibition. Collectively, this study elucidates the dose-response relationship between DOM concentration and composition in relation to microalgal growth, identifies key DOM components influencing growth, and proposes targets for the selective removal of inhibitory DOM in PMADE.

Synergistic treatment of digested wastewater with high ammonia nitrogen concentration using straw and microalgae

Microalgae as a promising approach for wastewater treatment, has challenges in directly treating digested piggery wastewater (DPW) with high ammonia nitrogen (NH4+-N) concentration. To improve the performance of microalgae in DPW treatment, straw was employed as a substrate to form a straw-microalgae biofilm. The results demonstrated that the straw-microalgae biofilm achieved the highest NH4+-N removal rate of 193.2 mg L-1 d-1, which was 28.8 % higher than that of culture system without straw. The final NH4+-N concentration in the effluent met the discharge standard of 5 mg L-1. Furthermore, the total organic carbon (TOC) released from straw facilitated bacterial proliferation and the secretion of extracellular polymeric substances (EPS). The EPS and TOC increased the suspension viscosity and surface tension, thereby enhancing the residence time of CO2 in the liquid phase and promoting CO2 fixation. This study presented a novel method for the biological treatment of high-ammonia-nitrogen DPW.

Attached indigenous microalgal-bacterial consortium with greater stress-resistance facilitated recovery of integrated fixed-film system after experiencing short-term stagnation inhibition

Stability of integrated fixed-film indigenous microalgal-bacterial consortium (IF-IMBC) requires further investigation. This study focused on the influence of short-term stagnation (STS), caused by influent variations or equipment maintenance, on IF-IMBC. Results showed that the IF-IMBC system experienced initial inhibition followed by subsequent recovery during STS treatment. Enhanced organics utilization was believed to contribute to system recovery. It is proposed that the attached IMBC possessed greater stress resistance. On the one hand, a higher increase in bacteria potentially participating in organic degradation was observed. Moreover, the dominant eukaryotic species significantly decreased in suspended IMBC while its abundance remained stable in the attached state. On the other hand, increased abundance for most functional enzymes was primarily observed in the attached bacteria. This fundamental research aims to bridge the knowledge gap regarding the response of IMBC to variations in operational conditions.

Adsorption performance of Ni(II) by KOH-modified biochar derived from different microalgae species

Microalgae biochar is potential adsorbents to remove heavy metals from wastewater due to abundant functional groups, high porosity and wide sources, but performance is not fully developed since it depends on microalgae species attributing to distinct morphology and biomass compositions. Here, two microalgae species Chlorella Pyrenoidosa and Scenedesmus Obliquus were used for biochar preparation via KOH-modification, biochar properties and their influences on Ni(II) adsorption were investigated. Ni(II) adsorption performances responding to biochar properties and operating conditions were upgraded via progressive optimization and response surface methodology. Together, adsorption isotherms and kinetics were analyzed to obtain significant factors for Ni(II) removal. As results, 100 % of Ni(II) removal was achieved under 100 mg/L initial Ni(II) concentration as pH was higher than the biochar zero-charge point of 6.87 with low biochar dosage (0.5 g/L), which provides an efficient approach for heavy metal removal from wastewater with microalgae biochar.