Substantial discharge of hazardous substances, especially dyes and heavy metal ions to the environment, has become a global concern due to many industries neglecting the environmental protocols in waste management. A massive discharge of contaminantsfrom different anthropogenic activities, can pose alarming threats to living species and adverse effect to the ecosystem stability. In the process of treating the polluted water, various methods and materials are used. Hybrid nanocomposites have attained numerous interest due to the combination of remarkable features of the organic and inorganic elements in a single material. In this regards, carbon and polymer based nanocomposites have gained particular interest because of their tremendous magnetic properties and stability. These nanocomposites can be fabricated using several approaches that include filling, template, hydrothermal, pulsed-laser irradiation, electro-spinning, detonation induced reaction, pyrolysis, ball milling, melt-blending, and many more. Moreover, carbon-based and polymer-based magnetic nanocomposites have been utilized for an extensive number of applications such as removal of heavy metal and dye adsorbents, magnetic resonance imaging, and drug delivery. This review emphasized mainly on the production of magnetic carbon and polymer nanocomposites employing various approaches and their applications in water and wastewater treatment. Furthermore, the future opportunities and challenges in applying magnetic nanocomposites for heavy metal ion and dye removal from water and wastewater treatment plant.

Hydrothermal carbonization (HTC) is an energy-efficient thermochemical process for converting wet waste products into value added materials for water treatment. Understanding how HTC influences the physicochemical properties of the resultant materials is critical in optimizing the process for water treatment, where surface functionality and surface area play a major role. In this study, we have examined the HTC of four wet waste streams, sewage sludge, biosludge, fiber sludge, and horse manure at three different temperatures (180 °C, 220 °C, and 260 °C). The physicochemical properties of these materials were examined via FTIR, SEM and BET with their adsorption capacity were assessed using methylene blue. The yield of solid material after hydrothermal carbonization (hydrochar) decreased with increasing temperature for all samples, with the largest impact on horse manure and fiber sludge. These materials also lost the highest degree of oxygen, while HTC had minimal impact on biosludge and sewage sludge. The differences here were due to the varying compositions of each waste material, FTIR identified resonances related to cellulose in horse manure and fiber sludge, which were not detected in biosludge and sewage sludge. Adsorption capacities varied between 9.0 and 68 mg g⁻¹ with biosludge HTC at 220 °C adsorbing the highest amount. Adsorption also dropped drastically at the highest temperature (260 °C), indicating a correlation between adsorption capacity and HTC conditions. This was attributed to the loss of oxygen functional groups, which can contribute to adsorption. These results suggest that adsorption properties can be tailored both by selection of HTC temperature and feedstock.

Maternal smoking during pregnancy has detrimental effects on fetal development. The current review examined the differences in offspring’s bone mineral density (BMD) between mothers smoked during pregnancy and those who did not. A systematic review and meta-analysis on the studies investigating the influence of maternal smoking during pregnancy on children or neonates’ bone measures published up to October 30, 2018, was performed. BMD results measured at different body sites were pooled and then fixed or random effect models were used based on the presence of heterogeneity. The desired pooled effect size was the offspring’s BMD mean difference with 95% confidence interval between smoker and non-smoker mothers. Sensitivity analysis was performed for birth weight and current weight, two important mediator/confounders causing heterogeneity. Overall, eight studies consisting of 17,931 participants aged from infancy to 18 years were included. According to the fixed effect model, the mean of BMD in offspring whose mothers smoked during pregnancy was 0.01 g/cm² lower than those with non-smoker mothers (95% CI = − 0.02 to − 0.002). However, subgroup meta-analysis adjusted for birth weight and current weight demonstrated no significant mean difference between BMD of children with smoker and non-smoker mothers (d = 0.06, 95% CI = −0.04 to 0.16, p value = 0.25 and d = − 0.005, 95% CI = − 0.01 to 0.004, p value = 0.28, respectively). According to available studies, it is suggested that maternal smoking during pregnancy does not have direct effect on the offspring’s BMD. Instead, this association might be confounded by other factors such as placental weight, birth weight, and current body size of children.

Fipronil is an insecticide commonly used in agriculture. We report here on the sublethal and sub-chronic effects of fipronil on non-target topmouth gudgeon (Pseudorasbora parva) at environmentally relevant levels. The results showed that fipronil did not cause significant changes in brain acetylcholinesterase activities, glutathione S-transferase (GST) activities in the intestine, and GST, glutamic pyruvic transaminase (GPT), and glutamic oxaloacetic transaminase (GOT) activities in the liver tissues at environmentally relevant levels for 96-h exposure. In the further test for a 12-day exposure, dose-dependent responses of the serum GPT and GOT activities were observed in all treated groups with sublethal concentrations of fipronil. Furthermore, fipronil could reduce the liver mitochondrial membrane fluidity of P. parva, especially with high concentration of fipronil at high temperature. The results suggest that serum GPT and GOT in P. parva might be useful biomarkers for effects of fipronil exposure at environmentally relevant level, and reducing fluidity of liver mitochondrial membrane may be one toxic mechanism of fipronil.

Secondary pollution resulting from shoot death is a difficult problem that complicated the application of wetland plants for water purification in northern wetlands. Phalaris arundinacea, a perennial herb with an obviously declining stage, or senescence, is a species that is often selected for water purification in Northern China; however, whether it reduces the secondary pollution risk via nitrogen (N) and phosphorus (P) accumulation during senescence or not remains unclear. To investigate this question, an experiment was conducted with containerized plants during the winter of 2016, after roughly half the leaves on the plants had withered. The experimental observations and analyses were conducted within 0, 2, 4, 6, and 8 weeks of the initiation of senescence. Results revealed that leaves continued to wither and shoot death occurred during weeks 4 to 6 and 8 to 10, respectively. However, no significant differences occurred in fresh biomass or in N and P accumulations of a single plant during senescence. The root biomass, root weight per volume, and total N content increased significantly, while total P content remained stable when leaves withered, respectively. H⁺-ATPase, a key enzyme for ion transportation, decreased after the leaves withered. However, root activity, evaluated by absorption surface per root volume, remained stable, and percentage of fine root length (diameter < 1 mm) increased significantly during senescence. In conclusion, the root activity and morphology enables P. arundinacea to accumulate N and P during senescence, which makes it a good choice for water purification in northern wetlands.

The nitrogen removal efficiency in constructed wetlands (CWs) was largely affected by the dissolved oxygen (DO). In this study, micro-aeration with different numbers of hollow fiber membrane modules (HFMEs) was adopted to increase the oxygen availability and improve the nitrogen removal efficiency in CWs under different air temperatures and different hydraulic retention time (HRT). Compared to the plant oxygen release (ROL) of wetland plants and traditional mechanical aeration, HFME increased the oxygen availability and enhanced the nitrogen removal efficiency in CWs. The COD and NH₄⁺–N removal efficiencies increased with the increase of the HMFE. TN removal efficiency was increased by 8~16% after the application of HFME in CWs in the high-temperature stage. However, less HFME in CW-M1 realized the highest TN removal efficiency in low- and medium-temperature stages. At low temperature after 4-day HRT, the DO concentration respectively reached 6.25 mg L⁻¹ and 3.25 mg L⁻¹ in the upper zone and the bottom of CW-M1. The TN removal efficiencies in the upper zone of CW-M1 (60.69%) and the bottom of CW-M1 (64.98%) were all significantly higher than those in the upper zone of CK (35.98%) and the bottom of CK (39.9%). In addition, the microbial biomass and community analyses revealed that CW-M1 showed the most nitrifying bacteria and the best metabolic activity of bacteria. HEMF in CW-M1 also increased the nitrifying capacity from 0.12 to 0.46 mg kg⁻¹ h⁻¹. The application of HFME in CWs accelerated the nitrification process by enhancing nitrifying bacteria and less HFME realized the highest TN removal efficiency through nitrification-denitrification processes. Graphical abstract The application of hollow fiber membrane modules in CWs enhanced the pollutants (TN and COD) removal efficiency in the process of biological nitrification-denitrification and increased the number of nitrifying bacteria.

Shiga toxin-producing Escherichia coli (STEC) is one of the most commonly heard sources of foodborne outbreaks but presently lacks studies of in the Kathmandu Valley. This study explored the presence of STEC in river water (n = 17), groundwater (n = 83), feces (n = 50), and manure (n = 20) in the Kathmandu Valley, Nepal. Samples that were confirmed to be E. coli–positive using the Colilert assay in previous studies were selected to examine the presence of the sfmD, stx1, and stx2 genes using quantitative polymerase chain reaction. Based on Colilert/sfmD gene ratios, the percentage of viable cells of E. coli in the fecal (2.0% ± 2.5%), manure (0.1% ± 0.1%), river water (3.4% ± 3.1%), and groundwater samples (3.9% ± 5.8%) were determined. The presence of the stx1 gene was observed in the fecal (6%), river water (53%), and groundwater (2%) samples, whereas the stx2 gene was detected in the fecal (8%), manure (5%), and river water (71%) samples. Interestingly, the stx/sfmD gene ratios in the groundwater samples were greater than 100%, suggesting the presence of other stx1/stx2-harboring microorganisms. These findings indicated the importance of continuing investigation into waterborne sources of STEC contamination within the Kathmandu Valley.

In the present work, the interaction between temperature, relative humidity, wind speed, and wind direction was studied in the atmosphere of Patras port, and the following were found: The interaction between temperature and air particle concentration was synergistic in the absence of wind direction, this result being however false. The actual effect of temperature in the presence of wind direction was antagonistic in line with most of the authors of the international bibliography; i.e., increase of the temperature level resulted in a decrease of particle concentration per unit volume (cm³). On the other hand, increase of the relative humidity increased the particle concentration per cm³, while the interaction between temperature and relative humidity was also antagonistic; i.e., increase of temperature decreased accordingly the relative humidity, and vice versa. Similarly, the interaction between wind speed and relative humidity was also antagonistic and statistically significant. It is emphasized that the wind direction played an important role in determining the antagonistic or synergistic nature of the interactions between the meteorological factors, and especially, in controlling quantitatively the results (or outcomes), of the above interactions.

Environmental degradation has become an important global issue due to the extraordinary increase in greenhouse gas emissions in recent years. Therefore, identifying the main determinants of environmental degradation is one of the primary agenda items of researchers and policymakers. In the literature, many social, economic, and sectorial factors related to the main determinants of CO₂ emissions have been studied. Although these studies provide very important information about the causes of CO₂ emissions and environmental degradation, some deficiencies remain in the related literature. The agricultural sector activities, which are an important sector at a global level and have significant potential impacts on CO₂ emissions, have not been adequately studied. In order to fill this gap, the effects of agriculture and renewable energy on CO₂ emissions were examined for lucky-seven countries during the period 1995–2014. The results of panel cointegration reveal the presence of long-run nexus among the variables. While the findings indicate that agriculture increases CO₂ emissions, renewable energy is a very important catalyst in reducing CO₂ emissions in lucky-seven countries. We also found that economic growth and energy consumption enhance CO₂ emissions and trade openness decreases. Panel VECM results indicate that variables are the causes of CO₂ emission in the long run. Also, we find that economic growth is the cause of CO₂ emissions in the short run.

In this paper, a phthalic acid ester (PAE) three-dimensional quantitative structure-activity relationship (3D-QSAR) model with a double activity (toxicity and estrogenic activities) combination was established using a comprehensive evaluation method, in which the database of the combined activities consisted of 17 and 13 employed in the training sets and test sets, respectively. Ditridecyl phthalate (DTDP) derivatives with low-toxicity and estrogen combined activities were designed with DTDP as the target molecule. Four environmentally friendly DTDP derivatives were screened out by evaluating their environmental friendliness (expressed by persistence, bioaccumulation and migration) and practicability (expressed by insulation). Through the toxicity and estrogen single-activity model validation and contour map analyses, the results showed that the 3D-QSAR model for PAE toxicity and estrogen combined activities was feasible and the weight setting was reasonable. In addition, the mechanism analysis showed that the toxicity and estrogen combined activities of the four DTDP derivatives (2-CH₃-DTDP, 2-OCHO-DTDP, 2-CH₂COOH-DTDP, 2-CH₂OH-DTDP) decreased in turn and were consistent with the single-activity model prediction. Meanwhile, it was speculated that the binding effect of the DTDP derivative molecules and estrogen-related proteins might be related to their hydrophobic interaction.