Inhibitory effect of thiourea on biological nitrification process and its eliminating method

Organic sulfur-driven denitrification pretreatment for enhancing autotrophic nitrogen removals from thiourea-containing wastewater: performance and microbial mechanisms

Thiourea (CH4N2S) is a widely used industrial reagent and is frequently detected in both sewage and industrial wastewater. However, treating thiourea-containing wastewater remains challenging due to its toxicity, high ammonium concentration, and low C/N ratio. In this study, a novel integrated autotrophic-heterotrophic denitrification (IAHD)- completely autotrophic nitrogen removal over nitrite (CANON) process was developed. The degradation pathway of toxic compounds, nitrogen, and sulfur release and transformation, as well as variations in functional genes were comprehensively examined. The results show that by incorporating an IAHD unit, prior to CANON, toxic thiourea was effectively degraded by the recycled nitrate from CANON. The released sulfur and organic carbon served as electron donors facilitating efficient NO3--N reduction. The optimal thiourea/NO3--N ratio for IAHD operation was determined to be 4:1 (m:m), achieving NO3- and thiourea removal efficiencies of 90 % and 99 %, respectively. Additionally, NH4+-N and SO42--S concentrations increased by 199.9 mg/L and 201.9 mg/L, respectively. Approximately 53.3 % of thiourea was converted into high-molecular-weight biological metabolites in the IAHD unit, which were subsequently and completely degraded in the CANON unit, where a robust nitrite-shunt and anammox process occurred. 16S rRNA amplicon sequencing revealed that Thiobacillus (with a relative abundance of 39.9 %) was the dominant genera in the IAHD unit, followed by Arenimonas (10.8 %) and norank_o_1013-28-CG33 (12.4 %), indicating that sulfur autotrophic denitrification was the primary pathway for thiourea degradation. Metagenomic analysis further confirmed that thiourea, acting as an electron donor, stimulated the expression of key functional genes involved in denitrification, sulfur oxidation, dissimilatory nitrate reduction, hydrolytic oxidation, and amino acid synthesis and transport pathways. These processes contributed to the active biological transformation of carbon, nitrogen and sulfur in the IAHD unit. This study demonstrates that implementing a prior autotrophic-heterotrophic denitrification unit effectively degrades toxic thiourea, thereby ensuring the subsequent nitrogen removal performance of CANON. This approach offers a new paradigm for the treatment of thiourea-containing wastewater, promoting a more efficient and low-carbon process.

Highly efficient metal-free electrochemical membrane enables zero-valent sulfur recovery from thiourea wastewater

Electrochemical recovery of zero-valent sulfur (S0) from thiourea (TU) wastewater offers a promising waste-to-value strategy that expects to promote the sulfur resource cycle in water treatment but still suffer from electrode poisoning and sulfur over-oxidation. Herein, we designed a metal-free CNT electrochemical membrane for selective oxidation of thiourea and recovery of S0. We found that defect sites on the carbon nanotube surface enable direct electron transfer for thiourea oxidation and may form carbon-sulfur bridge bonds, thereby facilitating the generation of S0 and urea. When treating real industrial wastewater with a concentration of 83.1 mg L-1 thiourea, the CNT membrane system could achieve a thiourea removal efficiency of 95.4% and a S0 recovery rate of 83.8% at 150 L m-2 h-1. The corresponding treatment energy consumption and S0 recovery energy consumption are 3.3 ± 0.2 kWh kg-TU-1 and 9.9 ± 1.0 kWh kg-S-1, respectively, lower than that of existing commercial electrodes such as Ti/SnO₂-Sb, PbO₂, Ru/IrO₂, and BDD. More importantly, the membrane system exhibits a desirable durability and stability during a 48-h continuous flow operation. Our findings advance the electrochemical membrane design for efficient S0 recovery from thiourea wastewater, contributing to the realization of economical and sustainable waste management and reclaiming resource.

Bacterial consortium (Priestia endophytica NDAS01F, Bacillus licheniformis NDSA24R, and Priestia flexa NDAS28R) and thiourea mediated amelioration of arsenic stress and growth improvement of Oryza sativa L

The present study analyzed the effects of individual microbes and their consortium (Priestia endophytica NDAS01F, Bacillus licheniformis NDSA24R, and P. flexa NDAS28R) either alone or in interaction with thiourea (TU) on growth and responses of rice plants subjected to As stress (50 mg kg^-1 in soil) in a pot experiment. The bacteria used in the experiment were isolated from As contaminated fields of Nadia, West Bengal and showed significant As removal potential in in vitro experiment. The results revealed significant growth improvement, biomass accumulation, and decline in malondialdehyde levels in rice plants in bacterial and TU treatments as compared to control As treatment. The best results were observed in a bacterial consortium (B1-2-3), which induced a profound increase of 65%, 43%, 127% and 83% in root length, shoot length, leaf width and fresh weight, respectively. Sulfur metabolism and cell wall synthesis were stimulated upon bacterial and TU amendment in plants. The maximum reduction in As concentration was observed in B2 in roots (-55%) and in B1-2-3 in shoot (-83%). The combined treatment of B1-2-3 + TU proved to be less effective as compared to that of B1-2-3 in terms of As reduction and growth improvement. Hence, the usage of bacterial consortium obtained in the present work is a sustainable approach, which might find relevance in field conditions to achieve As reduction in rice grains and to attain higher growth of plants without the need for additional TU supplementation.

Effect of partially hydrolyzed polyacrylamide (HPAM) on the bacterial communities of wetland rhizosphere soils and their efficiency in HPAM and alkane degradation

The effect of partially hydrolyzed polyacrylamide (HPAM) on structure and function of rhizosphere soil bacterial communities in constructed wetlands has been largely underinvestigated. In this study, we compare the effect of 250, 500, and 1000 mg/L of HPAM on bacterial community composition of Phragmites australis associated rhizosphere soils in an experimental wetland using MiSeq amplicon sequencing. Rhizosphere soils from the HPAM-free and the 500-mg/L-exposed treatments were used for laboratory experiments to further investigate the effect of HPAM on the soil's degradation and respiration activities. Soils treated with HPAM showed differences in bacterial communities with the dominance of Proteobacteria and the enrichment of potential hydrocarbon and HPAM-degrading bacteria. CO₂ generation was higher in the HPAM-free soils than in the HPAM pre-exposed soil, with a noticeable increase in both soils when oil was added. The addition of HPAM at different concentrations had a more pronounced effect on CO₂ evolution in the HPAM-pre-exposed soil. Soils were able to degrade between 37 ± 18.0 and 66 ± 6.7% of C₁₀ to C₃₀ alkanes after 28 days, except in the case of HPAM-pre-exposed soil treated with 500 mg/L where degradation reached 92 ± 4.3%. Both soils reduced HPAM concentration by 60 ± 15% of the initial amount in the 500 mg/L treatment, but by only ≤ 21 ± 7% in the 250-mg/L and 1000-mg/L treatments. In conclusion, the rhizosphere soils demonstrated the ability to adapt and retain their ability to degrade hydrocarbon in the presence of HPAM.

Wild Heterotrophic Nitrifying Strain Pseudomonas BT1 Isolated from Kitchen Waste Sludge Restores Ammonia Nitrogen Removal in a Sewage Treatment Plant Shocked by Thiourea

Thiourea is used in agriculture and industry as a metal scavenger, synthetic intermediate, and nitrification inhibitor. However, in wastewater, it can inhibit the nitrification process and induce the collapse of the nitrification system. In such a case, ammonia-oxidizing bacteria (AOB) lose their ability to remove ammonia. We investigated the nitrification system of a 60,000-t/d municipal sewage treatment plant in Nanjing, which collapsed after receiving 5–15 ppm (5–15 mg/L) thiourea. Ammonia nitrogen removal quickly recovered to more than 95% after inoculation with 10 t high-efficiency nitrification sludge, which was collected from a kitchen waste treatment plant. A heterotrophic nitrification strain was isolated from the inoculated sludge and identified as wild Pseudomonas by 16S rDNA sequencing and named “BT1.” Based on thiourea tolerance tests, BT1 can tolerate a thiourea content of more than 500 ppm. For comparison, the in situ process was imitated by the simulation system, and the wastewater shocked by 10 ppm thiourea could still meet the emission standard after adding 1% (V/V) BT1. High-throughput sequencing analysis was applied to study microbial succession during thiourea shock loading. The results showed that Hydrogenophaga and Thiobacillus grew with the growth of BT1. Pseudomonas BT1 was used for a 6,000-t/d printed circuit board (PCB) wastewater treatment system, the nitrification system returned to normal in 15 days, and the degradation rate stabilized at more than 95%.

New insights into morphological, stereological and functional studies of the adrenal gland under exposure to the potent goitrogen thiourea

Thiourea (thiophen-3-yl-acetic acid) is a well established antithyroid drug used for treating hyperactivity of the thyroid gland as it blocks the conversion of thyroxine (T4) to triiodothyronine (T3) in peripheral tissues. Human exposures to thiourea include contaminated drinking water and vegetables for its extensive use in fertilizers. Chronic thiourea exposure can cause thyroid dysfunction leading to redox imbalance. However, such effects on morphological, quantitative, functional and hypothalamo-pituitary-adrenocortical axis (HPA) analysis of the adrenal gland are yet to be explored. The aim was to explore the effect of thiourea on structural and functional status of the adrenocortical region with special reference to the HPA axis. Control rats were fed a normal laboratory standardized diet whereas to experimental rats, thiourea at a dose of 0.3 mg/day/Kg body weight was administered orally, once every day for consecutive 28 days. Histology and histometry, including morphometry of the adrenal, adrenal Δ5 3β HSD and 17β HSD activity, LPO level and serum corticosterone profile were assessed. Statistical significance was studied by ‘Mann-Whitney U’ test at p<0.05. Hypertrophy and hyperplasia of the adrenocortical cells was found especially in the layer zona fasciculata (p=0.0027) and enhanced adrenal Δ5 3β HSD activity (p=0.0067) in comparison to that of the control. Increased lipid peroxidation (p=0.0054) and up-regulated corticosterone release (p=0.0064) through adrenocortical stress signalling pathway were also noted. Stereological analysis of the left adrenal gland showed significant increase in volume (p=0.0025) and mass of cells (p=0.0031) in adrenocortical region in comparison to that of control animals. This study concludes that thiourea, in addition to its antithyroidal activity, develops stress in the adrenal as evident by enhanced lipid peroxidation in the gland that in turn through the HPA axis causes hypertrophy and hyperplasia of adrenocortical cells to enhance synthesis and release of corticosterone secretion to counteract the stress developed under the influence of this potent chemical agent.