Biological treatment processes for saline organic wastewater and related inhibition mechanisms and facilitation techniques: A comprehensive review

Simultaneous removal of carbamazepine, nitrate, and copper in a biofilm reactor filled with FeMn-modified ceramsite

Mixtures of pollutants are a significant challenge for conventional wastewater treatment processes. In the present work, the potential of a biofilm reactor to simultaneously remove nitrate (NO3--N), carbamazepine (CBZ), and copper ions (Cu2+) was evaluated. The reactor was filled with FeMn-modified ceramsite (CS@FeMn) and inoculated with the strains of Cupriavidus sp. HY129 and Pantoea sp. MFG10, which contributed to the redox cycling of Mn. Under optimum conditions with the HRT, C/N and pH of 9.0 h, 2.0, and 7.0, respectively, the bioreactor incorporating CS@FeMn demonstrated a significant increase in nitrogen removal capacity compared to the CS carrier, achieving a NRE of 96.7 %. Moreover, the removal efficiencies of CBZ and Cu²⁺ reached the values of 91.8 % and 85.6 %, respectively. The experimental results indicated that the removals of CBZ and Cu²⁺ were closely associated with microbial activity, involving the combined effects of microbial metabolism, adsorption of CS@FeMn, and bioprecipitation. Analyses through high-throughput sequencing and KEGG pathway revealed that the presence of CBZ and Cu²⁺ reshaped the structure of microbial community within the bioreactor, driving the regulation of functional genes and nitrogen metabolism-related genes to maintain metabolic stability. These findings indicated that the CS@FeMn bioreactor system presents an effective solution for simultaneously addressing multiple pollutants in water treatment, achieving high efficiencies in NO3--N, CBZ, and Cu2+ removal.

Nitrogen removal characteristics and salt tolerance mechanisms of the novel bacterium Halomonas sp. W07 in saline wastewater treatment

The extremely high osmotic pressure that frequently emerges in industrial wastewater will notably impact microorganisms' survival and nitrogen removal efficiency. A newly isolated Halomonas sp. strain W07 demonstrated the ability to efficiently remove nitrate and nitrite at an average rate of 4.68 and 5.56 mg/L/h, respectively, under an 8 % salinity condition. Whole-genome sequencing and nitrogen balance analysis revealed that W07 utilize the dissimilatory nitrate reduction to ammonium (DNRA) and ammonium assimilation pathways, including genes nap, nar, nasA, nir, glnA, gltBD, and gdhA2, to accomplish efficient nitrogen assimilation and removal in a high-salt environment. Furthermore, the expression of genes associated with salinity tolerance in W07 suggested that the strain can withstand osmotic stress by enhancing extracellular polymer secretion and facilitating the transport and synthesis of compatible solutes. The notable nitrogen removal efficiency and high salinity tolerance exhibited by strain W07 make it a promising candidate for nitrate removal under high-salt conditions.

Insights into the molecular mechanism on high salt tolerance of electroactive microorganisms collaborated by biochar supported cerium dioxide

Electroactive microorganisms are a promising approach for treating high-salinity organic wastewater, however, they are highly susceptible to salt stress, which can compromise their metabolic activity. In this paper, biochar supported nano-cerium dioxide catalyst (BC-CeO2) was prepared to strengthen electroactive microorganisms in high salt environment. It was found that BC-CeO2 significantly improved the bioelectrochemical and metabolic activity of microorganisms in high salt environment (600 mM NaCl) compared with the Control. At the initial stage of the reaction, the maximum power density of microbial fuel cells (MFCs) reached 343.21 mW/m2, and the degradation efficiency of norfloxacin (NOR) was 64.8 %, which was 1.7 times that of the Control. The analysis of microbial antioxidant properties demonstrated that BC-CeO2 could significantly increase the activities of superoxide dismutase (SOD) and catalase (CAT), effectively enhancing the ability of microorganisms to scavenge reactive oxygen species produced by salt stress. Metagenomic analysis revealed that the abundance of KEGG pathways conducive to microbial growth and metabolism under BC-CeO2 was relatively high, such as biosynthesis of amino acids (ko01230), microbial metabolism in diverse environments (ko01120) and so on. The enrichment of salt tolerant genes further illustrated the strengthening effect of BC-CeO2 on microbial adaptation to high salt environment, including genes related to NADH ubiquinone oxidoreductase, Na+/H+ antiporter, intracellular small molecule compatible substance synthesis and transport related enzyme system and K+ transporter related genes. Furthermore, the activity changes of Na+/K+-ATPase, which regulates cell permeability, in different environments also confirmed this point. This paper provides an effective strategy for enhancing the treatment of high-salt organic wastewater by electroactive microorganisms.

Effects of salinity on anaerobic digestion: Performance, microbial physiology, and community dynamics

Anaerobic digestion (AD) is widely applied to treatment and energy recovery from organic wastewater/wastes, while the efficiency of AD can be limited by salinity stress. This paper reviews the effects of salinity on AD. First of all, the effects of salinity on AD performance were compared, revealing that methane production is more susceptible to salinity stress. Secondly, the influence of salinity on microbial physiology and intracellular molecules was examined, demonstrating that salinity stress reduces the activity of key enzymes and increases the concentration of extracellular polymeric substances during AD. Thirdly, variations in microbial community structure under salinity stress were discussed, with archaeal communities showing more significant restructuring, including reduced dominance of acetoclastic methanogens. At last, strategies to mitigate salinity inhibition were presented, along with prospects for future research directions. This review provides theoretical guidance for engineering applications and strategies for enhancing AD in treating saline substrates.

Study on the effect of volatile organic compounds on the treatment of high-salt wastewater by low-temperature evaporation

High-salinity wastewater, owing to its intricate composition and challenging treatment requirements, poses a significant hurdle in water environmental governance. In this study, low-temperature evaporation technology is used to tackle wastewater containing the volatile organic compound such as N,N-dimethylacetamide (DMAC). Utilisation of comprehensive approaches involving experimental testing, mathematical modelling, and Aspen Plus software simulations, The influence of DMAC on evaporation efficiency is researched through the following factors which encompassing its effects on boiling point elevation, partial molar activation energy, and the formation of by-products. Additionally, the comparation of the impact of temperature, ionic strength, intermolecular interactions on the evaporation rate and the concentration of the volatile component DMAC in the condensate is also conducted in this study. After conducting a multiple linear regression analysis of evaporation efficiency using the Statistical Product and Service Solutions (SPSS) tool, it was discovered that temperature serves as the primary determinant influencing the evaporation rate. Additionally, ionic strength impacts solution viscosity, intermolecular interactions, and saturated vapour pressure by altering the intermolecular forces, thereby indirectly influencing both the evaporation rate and the quality of condensate water. The comparative analysis of single-effect and double-effect evaporation indicates that the optimal operating condition for double-effect evaporation yields an evaporation rate of 70%, with a remarkable 88% reduction in steam consumption compared to single one. Based on heat and mass balance principles, the mathematical model for double-effect evaporation is established to offer crucial data support for practical industrial applications.

Unraveling microbial community ecology and its effects on function and structure of halophilic aerobic granular sludge under varying salinities

Halophilic aerobic granular sludge (HAGS) can effectively treat saline wastewater characterized as high salinity and change of salinity, which was discharged from various industries. The stable microbial community ecology is the key to successful operation of HAGS, while its change and outcome under varying salinities is unexplored. In this study, HAGS systems under different salinities were studied to elucidate microbial community ecology process and its effects on HAGS. The study found that the salinity variation intensified competition interaction of bacteria and fungi due to the niche overlap. The decreased salinity from 40 to 0 g/L resulted in functional bacteria loss and fungal population increase by 94.46 %. The HAGS disintegration was caused by insufficient extracellular polymeric substances, which were secreted by bacteria and fed by fungi. This study is the first to reveal role of microbial community ecology on stability and function of HAGS in response to salinity variation.

Creating a Halotolerant Degrader for Efficient Mineralization of p-Nitrophenol-Substituted Organophosphorus Pesticides in High-Saline Wastewater

The bioaugmentation performance is severely reduced in the treatment of high-saline pesticide wastewater because the growth and degradation activity of pesticide degraders are significantly inhibited by high salt concentrations. In this study, a heterologous biodegradation pathway comprising the seven genes mpd/pnpABCDEF responsible for the bioconversion of p-nitrophenol (PNP)-substituted organophosphorus pesticides (OPs) into β-oxoadipate and the genes encoding Vitreoscilla hemoglobin (VHb) and green fluorescent protein (GFP) were integrated into the genome of a salt-tolerant chassis Halomonas cupida J9, to generate a genetically engineered halotolerant degrader J9U-MP. RT-PCR assays demonstrated that the nine exogenous genes are successfully transcribed to mRNA in J9U-MP. Gas chromatography analysis of methyl parathion (MP) and its intermediates demonstrated that the expressed MP hydrolase and PNP-degrading enzymes PnpABCD show obvious degradation activity toward the specific substrates in J9U-MP. Stable isotope analysis showed that J9U-MP is able to efficiently convert 13C6-PNP into 13CO2, demonstrating the complete mineralization of MP in high-salt media. J9U-MP is genetically stable during passage culture, and genomic integration of exogenous genes does not negatively influence the growth of J9U-MP. Under oxygen-limited conditions, VHb-expressing J9U-MP does not show obvious growth inhibition and a significant reduction in the MP degradation rate. A real-time monitoring system with enhanced GFP is used to track the motion and activity of J9U-MP during bioremediation. Moreover, 50 mg/L MP and its intermediates (i.e., PNP and HQ) were completely degraded by J9U-MP within 12 h in wastewater supplemented with 60 g/L NaCl. After 3 days of incubation, 25 mg/L 13C6-PNP was converted into 13CO2 by J9U-MP in wastewater supplemented with 60 g/L NaCl. Our results highlight the power of synthetic biology for creating new halotolerant pollutant-mineralizing strains. The strong competitive advantages of J9U-MP in high-salinity and low-oxygen environments make this degrader suitable for in situ bioaugmentation of OP wastewater.

Hypersaline organic wastewater treatment: Biotechnological advances and engineering challenges

The sustainable treatment of hypersaline organic wastewater (HSOW) remains a significant challenge in industrial wastewater management, as conventional approaches often fail to meet stringent discharge standards and low-carbon sustainability targets. Halotolerant and halophilic microbial strains offer promising solutions, yet their application is hindered by limited stress resistance, thus hindering effective treatment and achieving near-zero liquid discharge. In this review, we systematically examine endogenous strategies, such as microbial mutualism and genetic engineering, alongside exogenous approaches, including functional materials, electrical and magnetic stimulation, and 3D bioprinting, to improve microbial resilience in hypersaline environments. Furthermore, we propose an integrated treatment framework that combines physicochemical and biochemical processes, leveraging biological detoxification and biological desalination to enhance the treatment of HSOW while minimizing environmental impact and carbon emissions. By advancing the understanding of microbial stress adaptation and optimization strategies, this review provides critical insights into the development of sustainable, low-carbon wastewater treatment solutions.

Properties and kinetic behavior of free and immobilized laccase from Oudemansiella canarii: Emphasis on the effects of NaCl and Na2SO4 on catalytic activities

Studies have highlighted the great potential of Oudemansiella canarii laccase in degrading synthetic dyes for reducing their toxicity. Immobilization of enzymes improves usability in degradation processes and the present work succeeded in immobilizing this laccase onto MANAE-agarose. Immobilization improved pH, thermal, and storage stabilities. Both, free and immobilized enzymes presented Michaelis-Menten kinetics with the substrate 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid) (ABTS) with Km values of 0.056 ± 0.003 and 0.195 ± 0.022 mM, respectively. Immobilization increased Vmax 1.27-fold. NaCl caused incomplete (hyperbolic) inhibition, which was satisfactorily described by the one-substrate one-modifier mechanism. Immobilization reduced the maximal inhibition by NaCl from 80.2 to 55.7 %. The effect of Na2SO4 was predominantly stimulation, but inhibition of the free enzyme occurred at high substrate concentrations. Stimulation of the immobilized enzyme by Na2SO4 was much more pronounced. It strongly depended on the substrate concentration and was much stronger (up to 300 %) at low substrate concentrations. The combined effects of substrate and sulfate on the immobilized laccase could be satisfactorily described by the one-substrate one-modifier mechanism. The modified response of the immobilized O. canarii laccase to NaCl and Na2SO4 considerably favors its use as a tool in bioremediation processes because environmental contamination by salts frequently represents a strong operational challenge.

Enrichment performance and salt tolerance of polyhydroxyalkanoates (PHAs) producing mixed cultures under different saline environments

The key to the resource recycling of saline wastes in form of polyhydroxyalkanoates (PHA) is to enrich mixed cultures with salt tolerance and PHA synthesis ability. However, the comparison of saline sludge from different sources and the salt tolerance mechanisms of salt-tolerant PHA producers need to be clarified. In this study, three kinds of activated sludge from different salinity environments were selected as the inoculum to enrich salt-tolerant PHA producers under aerobic dynamic feeding (ADF) mode with butyric acid dominated mixed volatile fatty acid as the substrate. The maximum PHA content (PHAm) reached 0.62 ± 0.01, 0.62 ± 0.02, and 0.55 ± 0.03 g PHA/g VSS at salinity of 0.5%, 0.8%, and 1.8%, respectively. Microbial community analysis indicated that Thauera, Paracoccus, and Prosthecobacter were dominant salt-tolerant PHA producers at low salinity, Thauera, NS9_marine, and SM1A02 were dominant salt-tolerant PHA producers at high salinity. High salinity and ADF mode had synergistic effects on selection and enrichment of salt-tolerant PHA producers. Combined correlation network with redundancy analysis indicated that trehalose synthesis genes and betaine related genes had positive correlation with PHAm, while extracellular polymeric substances (EPS) content had negative correlation with PHAm. The compatible solutes accumulation and EPS secretion were the main salt tolerance mechanisms of the PHA producers. Therefore, adding compatible solutes is an effective strategy to improve PHA synthesis in saline environment.