Search Results (86)

Ozone pollution decreases rice yield and quality in general, but how ozone stress changes grain-filling capacity is unclear. A chamber experiment was conducted to compare the effects of ozone exposure during the rice growth season on the grain-filling capacity and quality of spikelets located on the upper primary rachis (superior spikelets, SS) and the lower secondary rachis (inferior spikelets, IS). Ozone stress significantly decreased filled grain percentage by 41.4% and grain mass by 10.2% in IS, but had little effect on grain-filling capacity in SS. Consistent with the reduction in grain mass, ozone stress decreased grain volume, mainly due to reduced grain thickness, and IS was reduced more than SS. After removing the hull, brown rice obtained from ozone treatment exhibited higher proportions of immature and abnormal kernels, resulting in a substantially lower proportion of perfect kernels. Under ozone stress, the proportion of perfect kernels was only one-third in IS, compared with two-thirds in SS. Ozone stress affected the pasting properties of brown rice for both SS and IS, as shown by the decreased amylose content, and the increased maximum viscosity, minimum viscosity, final viscosity, setback, and peak time of the rapid visco analyzer profile. Out of fourteen traits related to nutritional quality of brown rice, only five showed significant increases under ozone stress, and they were the concentrations of albumin, prolamin, sulfur, copper, and manganese. The differential ozone responses between SS and IS were rather small for rice pasting properties and chemical compositions as shown by very few significant interactions between ozone and grain position. It is concluded that ozone stress during plant growth imposed more adverse effects on IS than SS in terms of grain-filling capacity and appearance quality, suggesting an enlarged asynchronous grain-filling pattern in rice panicles under ozone pollution. Strategies to improve the grain-filling capacity of IS are needed to mitigate ozone-induced damage to rice production. Full article

Municipal wastewater effluent (MWWE) is a common source of nutrient enrichment and provides a route for emerging substances of concern (ESOCs) to enter aquatic systems. Community composition and abundance metrics of benthic macroinvertebrates are commonly utilized to assess ecological impacts associated with nutrient enrichment; however, the responses of these metrics in systems with diverse chemical mixtures from MWWE, are not well understood. This study specifically addresses the effects of cumulative loading of tertiary-treated MWWE through responses in benthic macroinvertebrate communities in experimental control and treatment streams. Treatment streams used source river water previously exposed to upstream wastewater treatment plants but with an additional 5% by volume tertiarily treated MWWE, while control streams used only source river water. Surbers and artificial substrate rock baskets were used to examine impacts on both established and colonizing benthic communities, respectively. No significant differences were observed between the control and treatment streams in any of the community metrics of well-established benthic communities. In contrast, significant decreases in colonizing taxon diversity and evenness were found between treatment and control streams. The dominant taxa (most abundant family, by percentage of sample) in the community, often filter feeders, significantly increased in percentage of the total community in treatment streams. This response was consistent with a nutrient enrichment effect, with no evidence of ESOC related toxicity. This study highlights the need for bioassessment programs to utilize approaches involving varied in-situ sampling methods and controlled exposure systems to gain a better understanding of how various stages of community-level development are impacted by urban pollutants such as MWWE. Full article

Water scarcity is a global crisis and of particular concern in arid regions like Morocco. One creative solution is mining unusual water sources, such as landfill leachate. The presence of nitrogen in the sediment was studied as part of the use of sugar lime sludge in treating landfill leachate for irrigation purposes. A volume of 40 L of landfill leachate was treated with three different concentrations of sugar lime sludge (25%, 35%, and 50%). After homogenization and agitation of the mixture for 24 to 36 h, it was permitted to settle through the concrete decantate and supernatant. Nitrogen was efficiently decanted into the sediment during the composting process with green waste, enhancing the quality of the finished compost. The supernatants underwent physicochemical and microbiological analyses to ascertain their suitability for irrigation. The findings showed that the number of fecal streptococci was decreased by 99.13% at a 25% concentration of sugar lime sludge. The percentage of organic matter in the sediment rose from 10% to 40%, suggesting that the leachate had partially depolluted. The pH and electrical conductivity of the supernatants were within irrigation guidelines. The safety of diluted supernatants for plant germination was verified by phytotoxicity experiments conducted on maize seeds. The compost made from the decantate and green waste showed acceptable physical and chemical properties. Statistical analysis was conducted using JAMOVI software version 2.6.26. One-way ANOVA was used to assess the significance of treatment effects on microbiological and physicochemical parameters. The results confirmed statistically significant differences (p < 0.05) between the sludge concentrations, supporting the effectiveness of the treatment process. This study demonstrates how sugar lime sludge can be used to turn landfill leachate into a sustainable and safe irrigation water source, resolving environmental issues and promoting creative water management techniques. Full article

Vegetation concrete is one of the most widely used substrates in ecological slope protection, but its practical application often limits the growth and nutrient uptake of plant roots due to consolidation problems, which affects the effectiveness of slope protection. This paper proposed the use of a plant protein foaming agent as a porous modifier to create a porous, lightweight treatment for vegetation concrete. Physical performance tests, direct shear tests, plant growth tests, and scanning electron microscopy experiments were conducted to compare and analyze the physical, mechanical, microscopic characteristics, and phyto-capabilities of differently treated vegetation concrete. The results showed that the higher the foam content, the more significant the porous and lightweight properties of the vegetation concrete. When the foam volume was 50%, the porosity increased by 106.05% compared to the untreated sample, while the volume weight decreased by 20.53%. The shear strength, cohesion, and internal friction angle of vegetation concrete all showed a decreasing trend with increasing foaming agent content. Festuca arundinacea grew best under the 30% foaming agent treatment, with germinative energy, germinative percentage, plant height, root length, and underground biomass increasing by 6.31%, 13.22%, 8.57%, 18.71%, and 34.62%, respectively, compared to the untreated sample. The scanning electron microscope observation showed that the pore structure of vegetation concrete was optimized after foam incorporation. Adding plant protein foaming agents to modify the pore structure of vegetation concrete is appropriate, with an optimal foam volume ratio of 20–30%. This study provides new insights and references for slope ecological restoration engineering. Full article

Diarrheal irritable bowel syndrome (IBS-D) is a chronic bowel condition that leads to intestinal dysfunction and is typically accompanied by diarrhea, stomach pain, and abdominal distension. Ribes nigrum L. polyphenols (RNPs), which are natural plant polyphenols, are the subject of this study, which aims to assess their potential in improving IBS-D and to explore the underlying mechanisms through a network pharmacology analysis and 16S rRNA sequencing. Next, mice models of diarrhea-predominant irritable bowel were established, and the mice with IBS-D were treated with RNPs. The effect of RNPs was then evaluated in terms of body weight, abdominal withdrawal reflex (AWR), Bristol score, fecal water percentage, diluted fecal volume, total intestinal transit time, immune index, histopathological observation, and changes in inflammatory factors. Finally, 16S rRNA sequencing and reverse q-RTPCR were utilized to evaluate the components that mediate the impact of RNPs on IBS-D. It was found that when RNP treatment was administered to mice with IBS-D, they decreased the water content in their stools, raised their immunological scores, and decreased the amount of inflammatory substances in their bodies. Moreover, through 16S rRNA sequencing, it was shown that the RNP treatment increased the relative abundances of Bacteroides, Alloprevotella, and Alistipes, which led to the remodeling of gut microbiota. In summary, RNPs significantly improved the conditions of mice with IBS-D by inhibiting the FoxO pathway and enhancing gut microbiota. This study concludes that RNPs could significantly improve the symptoms of mice with IBS-D through these means. Full article

This study aimed to assess the efficacy of anaerobic digestion (AD) in the co-digestion of the organic fraction of municipal solid waste (OFMSW) and municipal dehydrated sewage sludge (DSS). The experiments were conducted in batch and continuous mode under mesophilic conditions (T = 37 ± 2 °C). The results of batch tests indicated that the use of DSS in co-digestion with OFMSW led to a biomethane production of 422 NmL_CH4/g_VS with a production yield of 450 NmL_CH4/g_VSremoved. Nevertheless, the findings of the tests conducted with OFMSW alone demonstrated superior performance. A pilot plant reactor with a volume of approximately 2 m³ was employed in the continuous tests. The results corroborated the trends observed in the batch tests. In particular, the specific methane production yields decreased from 0.47 Nm³/kg_VS when OFMSW was the sole substrate to 0.44 Nm³/kg_VS when DSS was introduced, with a DSS/OFMSW ratio (R_DO) of 0.1. Despite the reduction in methane production yield observed in both batch and continuous tests, a techno-economic assessment of the process indicated the potential profitability of DSS in co-digestion with OFMSW. Notably, the estimated profit from utilizing DSS in a percentage of 10% (R_DO = 0.1) is 108 EUR/ton, compared to 102 EUR/ton when only OFMSW is employed. Full article

Food reformulation has become a critical concern for the food industry due to society’s growing interest in improving nutritional profiles. In this context, Moringa oleifera, a plant native to India with high nutritional value, offers an alternative for enriching food products. Its abundant antioxidants, proteins and fibers make it an attractive choice. This study aimed to assess the impact of substituting wheat flour with dried moringa leaf powder in snack crackers. These were prepared using 53% (w/w) wheat flour and substituting part of it with different replacement percentages (1, 2.5, 5, 7.5 and 10% (w/w)) of dried moringa leaf powder. The baked snacks were characterized in terms of moisture, aw, optical properties, mechanical properties, antioxidant capacity, total phenol content, protein content and energy value. In addition, a sensory analysis was carried out to evaluate the acceptability of the crackers. The results indicated that cracker thickness and volume remained constant across all formulations. As moringa incorporation increased, weight loss decreased. The high water-holding capacity of moringa leaf powder and its protein content contributed to keep the same moisture content and reduce water activity in the crackers, resulting in decreased firmness. The snacks exhibited a greener color with brownish tones as moringa replacement levels rose. Antioxidant capacity (up to 251 ± 13 mg Trolox E/100 g snack) and total phenol content (up to 1172 ± 288 mg Galic acid/100 g snack) were higher with greater moringa inclusion, remaining stable after baking. The protein content increased, allowing all crackers to be labeled as a “protein source” since the energy value due to protein was higher than 12%. However, judges found the color, aroma and flavor attributes of the highest moringa content (10%) crackers too intense. In conclusion, replacing up to 5% of wheat flour with dried moringa leaf powder in snack crackers could enhance their nutritional profile while maintaining consumer acceptance. Full article

Natural water resources often contain fluorides and chlorides due to wastewater discharge; however, excessive exposure to fluorides can pose health risks to humans. Elevated chloride levels can negatively affect aquatic fauna and disrupt the reproductive rates of plants. This study assessed constructed wetlands (CWs) featuring monocultures (including Canna hybrid, Alpinia purpurata, and Hedychium coronarium) and polycultures (combinations of species from the monoculture systems) of ornamental plants (OPs) to evaluate their efficiency in removing fluorides and chlorides. The results revealed that the ornamental plants flourished in the CW conditions without sustaining any physical damage. C. hybrid demonstrated the longest roots and the highest volume, as well as greater height compared to other species. However, this did not affect the ion removal efficiency. In polyculture systems, 42.2 ± 8.8% of fluoride was removed, a result that was not significantly different (p > 0.05) from the removal rates observed in monocultures of C. hybrid (42.5 ± 7.5%), H. coronarium (36.8 ± 7.0%), or A. purpurata (30.7 ± 7.9%). For chloride, a similar pattern emerged, with 32.4 ± 4.8% removed in constructed wetlands (CWs) using a polyculture of ornamental plants, a figure that was also not significantly different (p > 0.05) from the removal percentages in monocultures of C. hybrid (29.1 ± 5.3%), H. coronarium (28.1 ± 5.0%), or A. purpurata (32.0 ± 5.7%). Our results indicate that CWs with polyculture species contribute to pollutant removal at levels comparable to those found in monoculture systems. However, polyculture systems offer enhanced aesthetic appeal and biodiversity, incorporating various ornamental flowering plants. The use of this eco-technology for removing fluoride and chloride pollutants helps prevent river contamination and associated health issues. Full article

Aquaponics offers a simple conclusive solution to the food and environmental crisis around the world. This paper presents a comparative analysis of standard aquaponics with vermiponics (aquaponics with earthworms) before and after applying an optimal freshwater replenishment. Fish and plants were grown on a standard aquaponics testbed and a vermiponics testbed for 3 months each, initially without water replenishment, and then with 19% replenishment based on the fishtank volume. Water quality and environmental data were monitored, collected and processed using sensors and internet of things (IoT) devices. Daily growth analysis, the mean productivity of both testbeds before and after replenishment, the percentage of productivity difference and the general productivity comparison between standard and vermiponics testbeds were determined. Results showed an enhanced productivity of 2.83% and 5.54% for the standard testbed and the vermiponics testbed, respectively, when replenishment was applied. The yield improvement after replenishment was proven to be statistically significant, with p < 0.05 reassuring the impact of water replenishment. This research contributes to the understanding of the impact of water replenishment in aquaponics and vermiponics systems. Moreover, it provides insights into the effect of earthworms on both systems’ yield productivity. Full article

Improving the productivity of medicinal and aromatic species via eco-friendly approaches is imperative worldwide because of their therapeutic impacts. Biostimulants have been recognized among the best cultural practices in the last few decades. Among them, bee honey (BH) and ginger extract (GE) are new sources of multifunctional biostimulants that positively influence plant growth and development. However, there are currently no detailed reports on the impacts of BH or GE as promising growth and yield enhancers for medicinal and aromatic species. Also, the mechanism involved in stimulating growth and essential oil content with BH or GE is still unidentified. This work was, therefore, undertaken to analyze the impact of BH and GE on the growth, productivity, and essential oil content of sage plants (Salvia officinalis L.). Sage plants were sprayed monthly for three months with the same volume of BH (0, 5, 10, and 15 g L⁻¹), GE (0, 5, 10, and 15 mg L⁻¹), or tap water, which was used as a control. BH or GE application improved the plant height, branch number, herb yield, total chlorophyll content, total phenolics, and antioxidant capacity relative to the controls, more so with GE. Intriguingly, the essential oil percentage, oil yield, and oil constituents were enhanced by BH and GE. In this respect, the highest levels of biostimulants, particularly GE, were more effective. On a percentage basis, the essential oil yield per hectare was largely increased by 127.91 and 138.89% with GE (10 g L⁻¹) in both seasons relative to the controls. The contents of IAA, GA₃, and CK in THE sage leaves were substantially increased by BH and GE, and higher levels of both biostimulants and GE were more effective. The nutrient levels of N, P, K, Fe, Zn, and Mg were also elevated by BH and GE compared with the untreated plants. These results suggest that BH or GE application could be a promising biostimulant for improving the productivity of sage and provide a new understanding of their mechanisms in this aspect. Full article

Saccharum is relatively new to 33° N latitude. S. spontaneum readily hybridizes with commercial sugarcane (Saccharum spp.) and lends cold tolerance and greater yield to the hybrid progeny, called energycane. Since 2007, there have been numerous new hybrid and backcross energycane genotypes developed but there is a paucity of information about them. Twenty energycane genotypes were tested in the first season of growth from cane propagules (plant cane; PC) against Ho 02-113 (a control) for two site-years in northcentral Mississippi. Grand (exponential) growth continued into October. The prevailing paradigm is that tonnage is what matters. Except for percentage cellulose, all factors tested (dry matter yield, extractable juice volume, °Brix, theoretical ethanol from fermentation, theoretical ethanol from cellulose, and total theoretical ethanol) were greater from the second site-location compared to the first. Dry matter yield (DMY) and total theoretical ethanol yield (TTEY) were moderately correlated. Over the two years of this test only Ho 14-9213 exceeded in mean DMY of Ho 02-113. Sixteen of the 19 test genotypes in this test equaled or exceeded the mean TTEY of Ho 02-113. Full article

A member of the Phyllanthaceae family, Flueggea leucopyrus is a well-known plant in the tribal areas of Sri Lanka, India’s Shaurastra region, Australia, and Malaysia. This study provides information about Flueggea leucopyrus, a plant with a wide range of therapeutic uses in India. Different extracts from the leaves and roots of Flueggea leucopyrus were evaluated for their physical and chemical properties, preliminary phytochemical parameters, and pharmacological activities in the current study, followed by their fourier transform infrared spectroscopy (FTIR), gas chromatography-mass spectrometry (GC–MS), antioxidant, and anti-inflammatory properties. The aqueous extract of Flueggea leucopyrus leaves and roots have more different phytochemical elements than other solvent extracts, according to physico-chemical tests and phytochemical screening. As a result, the FT-IR, GC–MS, antioxidant, and anti-inflammatory activities of an aqueous extract were tested. Studies on hind paw edemas caused by carrageenan in albino rats examined the mean increase in paw volume and the percentage inhibition in paw volume at various time points following the injection of carrageenan (1% w/v). In comparison to the norm, these inhibitions were statistically significant (p < 0.001). The aqueous extract of Flueggea leucopyrus leaves and roots have both antioxidative and anti-inflammatory activities, indicating that it has the potential to be used in the formulation of antioxidant and anti-inflammatory medications in the future. Full article

Given the problems such as insufficient control on pests and diseases or pesticide damage on plants caused by uneven distribution of pesticide droplets during the current application process by UAVs, this paper designed novel uniform application equipment with nozzles swinging horizontally based on a UAV platform in order to improve the distribution uniformity of droplets volume. Nozzles swinging periodically are able to increase the overlap probability of spray fans generated from nozzles. It is helpful to further the spray deposition uniformity improvement. Through droplet motion analysis, CFD simulation, and spray tests, it was determined that the key factors affecting uniformity were the oscillating rod length, spray height, and nozzle angle. The best parameter combination was explored as the length of 175 mm, the height of 1.5 m, and the angle of 15°. Based on this combination, the prototype was produced and installed on the UAV platform. A field test was carried out to verify its performance. The results showed that the CV of the improved UAV was 26.41%, which was 6.43 percentage points lower than the traditional UAV, and the decrease was 19.58%, meaning that it is feasible to use this equipment to improve uniformity. Full article

The agricultural industry produces a substantial quantity of organic waste, and finding a suitable method for disposing of this highly biodegradable solid waste is a difficult task. The utilisation of anaerobic digestion for agricultural waste is a viable technological solution for both renewable energy production (biogas) and waste treatment. The primary objective of the study was to assess the composition of biogas, namely the percentages of methane, carbon dioxide, ammonia, and hydrogen sulphide. Additionally, the study aimed to quantify the amount of biogas produced and determine the methane yield (measured in NmL/g VS) from different agricultural substrates. The biochemical methane potential (BMP) measurements were conducted in triplicate using the BPC Instruments AMPTS II instrument. The substrates utilised in the investigation were chosen based on their accessibility. The substrates used in this study comprise cattle manure, chicken manure, pig manure, tomato plants, tomatoes, cabbage, mixed fruits, mixed vegetables, dog food, and a co-digestion of mixed vegetables, fruits, and dog food (MVMFDF). Prior to the cleaning process, the makeup of the biogas was assessed using the BIOGAS 5000, a Geotech Analyser. The AMPTS II flow cell automatically monitored and recorded the volume of bio-methane produced after the cleaning stage. The data were examined using the Minitab-17 software. The co-digestion of mixed vegetables, mixed fruits, and dog food (MVMFDF) resulted in the highest methane level of 77.4%, followed by mixed fruits at 76.6%, pig manure at 72.57%, and mixed vegetables at 70.1%. The chicken manure exhibited the greatest levels of ammonia (98.0 ppm) and hydrogen sulphide (589 ppm). Chicken manure had the highest hydrogen sulphide level, followed by pig manure (540 ppm), tomato plants (485 ppm), mixed fruits (250 ppm), and MVMFDF (208 ppm). Ultimately, the makeup of biogas is greatly affected by the unique qualities of each substrate. Substrates containing elevated quantities of hydrogen sulphide, such as chicken manure, require the process of biogas scrubbing. This is because they contain substantial amounts of ammonia and hydrogen sulphide, which can cause corrosion to the equipment in biogas plants. This emphasises the crucial need to meticulously choose substrates, with a specific focus on their organic composition and their capacity to generate elevated methane levels while minimising contaminants. Substrates with a high organic content, such as agricultural waste, are optimal for maximising the production of methane. Furthermore, the implementation of biogas scrubbing procedures is essential for efficiently decreasing carbon dioxide and hydrogen sulphide levels in biogas. By considering and tackling these problems, the effectiveness of biogas generation can be enhanced and its ecological consequences alleviated. This strategy facilitates the advancement of biogas as a sustainable energy source, hence contributing to the attainment of sustainable development goals (SDGs). Full article

The improved wear and corrosion resistance of gray cast iron (GCI) with enhanced mechanical properties is a proven stepping stone towards the longevity of its versatile industrial applications. In this article, we have tailored the microstructural properties of GCI by alloying it with titanium (Ti) and tungsten (W) additives, which resulted in improved mechanical, wear, and corrosion resistance. The results also show the nucleation of the B-, D-, and E-type graphite flakes with the A-type graphite flake in the alloyed GCI microstructure. Additionally, the alloyed microstructure demonstrated that the ratio of the pearlite volume percentage to the ferrite volume percentage was improved from 67/33 to 87/13, whereas a reduction in the maximum graphite length and average grain size from 356 ± 31 µm to 297 ± 16 µm and 378 ± 18 µm to 349 ± 19 µm was detected. Consequently, it improved the mechanical properties and wear and corrosion resistance of alloyed GCI. A significant improvement in Brinell hardness, yield strength, and tensile strength of the modified microstructure from 213 ± 7 BHN to 272 ± 8 BHN, 260 ± 3 MPa to 310 ± 2 MPa, and 346 ± 12 MPa to 375 ± 7 MPa was achieved, respectively. The substantial reduction in the wear rate of alloyed GCI from 8.49 × 10⁻³ mm³/N.m to 1.59 × 10⁻³ mm³/N.m resulted in the upgradation of the surface roughness quality from 297.625 nm to 192.553 nm. Due to the increase in the corrosion potential from −0.5832 V to −0.4813 V, the impedance of the alloyed GCI was increased from 1545 Ohm·cm² to 2290 Ohm·cm². On the basis of the achieved experimental results, it is suggested that the reliability of alloyed GCI based on experimentally validated microstructural compositions can be ensured during the operation of plants and components in a severe wear and corrosive environment. It can be predicted that the proposed alloyed GCI components are capable of preventing the premature failure of high-tech components susceptible to a wear and corrosion environment. Full article