Concentrations In Different Parts Research Articles

Soil moisture partitioning strategies in blowouts in the Hulunbeier grassland and response to rainfall

IntroductionSoil moisture and soil water retention capacity are key influencing factors for the normal growth and development of vegetation. Understanding the dynamic change characteristics of soil moisture in blowouts and soil water retention capacity is of great significance for the management of blowouts.MethodsThis study employs drying and in situ monitoring methods to select typical blowouts in different regions (sand pits, fringe zones, sand accumulation zones, and sand-grass transition zones) on the Hulunbuir Grassland. A large area of natural grassland surrounding these regions was chosen as the control (CK). Soil moisture at depths of 20, 40, 60, 100 and 200 cm below the surface was measured along the soil profile using the ECH2O-10HS soil moisture automatic monitoring instrument. The HOBO-RG3-M self-recording rain gauge was used to monitor rainfall. Soil water storage, coefficient of variation, and Pearson’s correlation coefficient were calculated to study the differences in soil moisture and the dynamic change regularity in soil moisture under different rainfall conditions. This research provides important theoretical support for the soil moisture distribution and vegetation restoration in the blowouts of the Hulunbuir Grassland.Results and discussionThe volumetric water content of the soil in the blowouts was 15.95%, the volumetric soil water content in different parts of the soil varied from low to high as follows: sand pit-I < sand-grass transition zone-IV < fringe zone-II < CK < sand accumulation zone-III. The soil volumetric water content of the 0–40 cm soil layer of the blowout was higher than 17.47%, and the soil volumetric water content of the 40–200 cm soil layer ranged from 12.13% to 17.47%. The volumetric water content of soil in various parts of the blowouts under different rainfall amounts had significant differences, with rainstorms and heavy rainfall effectively recharging the blowouts to a depth of 200 cm, and the blowouts responded strongly to heavy rainfall (71.5 mm). A gradual recovery of the pre-rainfall volumetric soil moisture content was seen approximately a week after rainstorms. The water retention and storage capacity of blowout soils was significantly higher than that of CK, the soil water storage capacity of different zones ranked in descending order as the sand accumulation zone (1875.38 mm) > edge zone (1373.22 mm) > CK (1188.36 mm) > sand pit (1000.39 mm) > sand–grass transition zone (803.90 mm). The correlation coefficient of sand pits and sand cover was 0.5612, and that of sand accumulation zones and sand cover was 0.5845, which confirmed that sand cover enhanced the water retention capacity of the localized area of blowouts (sand accumulation zones).

Transcriptome Analysis Reveals Key Genes and Pathways Associated with Cadmium Stress Tolerance in Solanum aculeatissimum C. B. Clarke

As a great economic Solanum with ornamental value and good adaptability, Solanum aculeatissimum is considered an excellent candidate for the phytoremediation of Cadmium-contaminated soils. However, there are no studies on the involvement of S. aculeatissimum in the response and tolerance mechanisms of cadmium (Cd) stress. In the present study, S. aculeatissimum was used for the first time for physiological and transcriptomic systematic analysis under different concentrations of Cd stress. The results showed that S. aculeatissimum was indeed well tolerant to Cd and showed Cd enrichment capabilities. Under the Cd stress treatment of 50 mg/kg (Cd6), S. aculeatissimum could still grow normally. At the 90th day of Cd stress, the amount of Cd content in different parts of the plant at the same concentration was in the order of root > stem > leaf. With the extension of the stress time up to 163 d, the trend of Cd content in each part was not consistent, and the results in the root (77.74 mg/kg), stem (30.01 mg/kg), leaf (29.44 mg/kg), immature fruit (18.36 mg/kg), and mature fruit (21.13 mg/kg) of Cd peaked at Cd4, Cd5, Cd1, Cd4, and Cd4, respectively. The enrichment and transport coefficients of all treatments were greater than 1. The treatment groups with the largest and smallest enrichment coefficients were Cd4 and CK, respectively. The treatment groups with the largest and smallest transport coefficients were CK and Cd4, respectively. Malondialdehyde (MDA), peroxidase (POD), and catalase (CAT) in the antioxidant system after Cd stress treatment were significantly increased compared to the untreated group. Under cadmium stress, by using real-time quantitative PCR, four genes (SaHMA20, SaL-AO, SaPrxs4, and SaPCs) were screened for possible correlations to Cd tolerance and absorption enrichment in S. aculeatissimum. The key DEGs are mainly responsible for the metabolic pathways of heavy metal ATPases, plastocyanin protein phytocyanins (PCs), peroxidases (Prxs), and ascorbate oxidase (AAO); these differential genes are believed to play an important role in Cd tolerance and absorption enrichment in S. aculeatissimum.

Long-Term Amendment with Sewage Sludge: Effects on Nutrient Value and Trace-Metal Content in Different Parts of Maize Plants

Agricultural soils play a key role in the achievement of a circular nutrient economy. The use of sewage sludges as fertilizers is important for such an achievement, assisting in the maintenance of soil health and nutritional crop value. This study was established, after 23 years of a fertilization experiment, in calcareous soil under a maize monoculture. The treatments included mineral fertilization as a control (MIN, 225 kg N ha−1) and two sludge treatments, where doses followed a threshold sludge nitrogen criterion (SNC, 170 kg org-N ha−1) or a threshold soil phosphorus criterion (SPC; when the soil Olsen-P value exceeded 40–60 kg P ha−1, the sludge application was stopped). A detailed study was performed on Cd, Cu, F, Mn, Pb, and Zn soil extractable with diethylenetriaminepentaacetic acid (DTPA), as well as the nutrient and heavy metal concentration of different fractions of the maize plant (grain, cob, and the rest of the plant). Extractions were also quantified. No biomass-yield differences were observed in the different parts of the maize plant in the year of sampling. Sludges increased the soil DTPA extraction of Cd, Cu, Fe, and Zn and diminished Mn extraction, without differences in extractable Pb. The SNC, when compared with MIN, showed increased P cob concentrations, and in grain, it showed increased Fe, Cr, and Co concentrations. The SPC figures of the studied parameters were, in general, between both treatments (MIN and SNC), although Cr extractions in grain diminished vs. SNC. Based on the results, the SPC can be recommended as it also avoids excessive available-P build up.

Comparing the Effects of Lime Soil and Yellow Soil on Cadmium Accumulation in Rice during Grain-Filling and Maturation Periods.

The karst area has become a high-risk area for Cadmium (Cd) exposure. Interestingly, the high levels of Cd in soils do not result in an excessive bioaccumulation of Cd in rice. Carbonate rock dissolution ions (CRIs) could limit the accumulation and translocation of Cd in rice. CRIs can become a major bottleneck in the remediation and management of farmlands in karst areas. However, there is limited research on the effects of CRIs in soils on Cd accumulation in rice. The karst area of lime soil (LS) and the non-karst areas of yellow soil (YS) were collected, and an external Cd was added to conduct rice cultivation experiments. Cd and CRIs (Ca2+, Mg2+, CO32-/HCO3-, and OH-) in the rice-soil system were investigated from the grain-filling to maturity periods. The results showed that CRIs of LS were significantly higher than that of YS in different treatments. CRIs of LS were 2.05 mg·kg-1 for Ca2+, 0.90 mg·kg-1 for Mg2+, and 42.29 mg·kg-1 for CO32- in LS. CRIs could influence DTPA Cd, resulting in DTPA Cd of LS being lower than that of YS. DTPA Cd of YS was one to three times larger than that of YS. Cd content in different parts of rice in YS was higher than that of LS. Cd in rice grains of YS was one to six times larger than that of LS. The uptake of Cd from the soil during Filling III was critical in determining rice Cd accumulation. CRIs in the soil could affect Cd accumulation in rice. Ca2+ and Mg2+ had significant negative effects on Cd accumulation of rice at maturity and filling, respectively. CO32-/HCO3- and OH- had significant negative effects on DTPA Cd in soil.

Prediction of geogenic source of groundwater fluoride contamination in Indian states: A comparative study of different supervised machine learning algorithms.

India has been dealing with fluoride contamination of groundwater for the past few decades. Long-term exposure of fluoride can cause skeletal and dental fluorosis. Therefore, an in-depth exploration of fluoride concentrations in different parts of India is desirable. This work employs machine learning algorithms to analyze the fluoride concentrations in five major affected Indian states (Andhra Pradesh, Rajasthan, Tamil Nadu, Telangana and West Bengal). A correlation matrix was used to identify appropriate predictor variables for fluoride prediction. The various algorithms used for predictions included K-nearest neighbor (KNN), logistic regression (LR), random forest (RF), support vector classifier (SVC), Gaussian NB, MLP classifier, decision tree classifier, gradient boosting classifier, voting classifier soft and voting classifier hard. The performance of these models is assessed over accuracy, precision, recall and error rate and receiver operating curve. As the dataset was skewed, the performance of models was evaluated before and after resampling. Analysis of results indicates that the RF model is the best model for predicting fluoride contamination in groundwater in Indian states.

Assessment of nutritional contents of different parts of moringa plant from selected districts of Oromia, Ethiopia

Moringa plants are among high-value trees and belong to the Moringaceae family, consisting of 13 species and highly distributed in Africa and southern Asia. It is multi-purpose tree with medicinal, nutritional, industrial and socio-economic values. Preliminary information indicates that the human dietary usage of the edible parts of these species is limited. Assessment of the nutritional quality of different moringa parts was not well documented in Oromia. Hence, the aim of this activity is to assess the nutritional qualities of different parts of moringa collected from different districts of Oromia. Sample collection was done from Bako from West Showa, Bishoftu from East Showa, Dalo Mena and Goro from Bale Zone, of Oromia representing mid and low land agro-ecologies of the region. Three to four sampling PAs were used from each district. Different parts of Moringa, namely, leaf, pod, bark, seed and flower were collected from the four districts at least in triplicate. The collected samples were made to dry at room temperature, milled with coffee miller, and passed through a 1 mm standard sieve. The prepared samples were analyzed for proximate and mineral compositions using standard methodologies. The result obtained indicated that leaf is rich in nutrients Ca, Na, Mn and Zn. Moringa flower is rich in nutrients like Zn and Mn, and second in K composition next to pod. The pod is also rich in K and Zn, while the fat and CP contents are high in the seed part of moringa. Generally, Higher % CP, K and P were found from the Bishoftu collection, while Mg, Ca and K were higher for the collection from DM. Bark is poor in protein content compared to other parts of the plant. However, Ca, Mg and Zn are double the optimum composition of plant material. Finally, it is possible to use different moringa parts for food fortification, where determination for antioxidant and nutritional composition analysis is mandatory, as well as future research directions. Int. J. Agril. Res. Innov. Tech. 14(1): 62-69, June 2024

Effects of Four Amendments on Cadmium Bioavailability and Enzyme Activity in Purple Soil

In this study, the effects of four types of amendments on effective Cd and Cd content in different parts of prickly ash soil and soil enzyme activity were studied, which provided scientific basis for acidification improvement of purple soil and heavy metal pollution control. A field experiment was conducted. Six treatments were set up:no fertilizer (CK), only chemical fertilizer (F), lime + chemical fertilizer (SF), organic fertilizer + chemical fertilizer (OM), biochar + chemical fertilizer (BF), and vinasse biomass ash + chemical fertilizer (JZ). Soil pH; available Cd (DTPA-Cd); Cd content in branches, leaves, shells, and seeds of Zanthoxylum; as well as the activities of catalase (S-CAT), acid phosphatase (S-ACP), and urease (S-UE) in different treatments were studied, and their relationships were clarified. The results showed following:① The two treatments of vinasse biomass ash + chemical fertilizer and lime + chemical fertilizer significantly increased soil pH (P < 0.05) to 3.39 and 2.25 units higher than that in the control, respectively. Compared with that in the control treatment, the content of available Cd in soil under vinasse biomass ash + chemical fertilizer and lime + chemical fertilizer treatment decreased by 28.91 % and 20.90 %, respectively. ② The contents of Cd in leaves, shells, and seeds of Zanthoxylum were decreased by 31.33 %, 30.24 %, and 34.01 %, respectively. The Cd enrichment ability of different parts of Zanthoxylum was different, with the specific performances being leaves > branches > seeds > shells. Compared with that of the control, the enrichment coefficient of each part of Zanthoxylum treated with vinasse biomass ash + chemical fertilizer decreased significantly(P < 0.05)by 27.54 %-40.0 %. ③ The changes in catalase and urease activities in soil treated with amendments were similar. Compared with those in the control group, the above two enzyme activities were significantly increased by 191.26 % and 199.50 %, respectively, whereas the acid phosphatase activities were decreased by 16.45 %. Correlation analysis showed that soil available Cd content was significantly negatively correlated with soil pH value(P < 0.01), S-CAT and S-UE enzyme activities were significantly positively correlated with soil pH(P < 0.01), and the soil available Cd content was significantly negatively correlated (P < 0.01); the S-ACP enzyme showed the complete opposite trends. The application of lime and vinasse biomass ash to acidic purple soil had the most significant effect on neutralizing soil acidity. It was an effective measure to improve acidic purple soil and prevent heavy metal pollution by reducing the effective Cd content in soil and improving the soil environment while inhibiting the absorption and transfer of Cd in various parts of Zanthoxylum.

Zinc fertilization effect on macro and micro-nutrients concentrations and uptake in wheat (Triticum aestivum) varieties

A field experiment was conducted during the winter (rabi) seasons of 2013–14 and 2014–15 at New Delhi, to find out the effect of zinc (Zn) fertilization on concentration and uptake of macro and micro-nutrients in high-yield ing wheat (Triticum aestivum L.) varieties. Treatments comprised 6 high-yielding varieties of wheat in the main plots and 5 Zn management treatments as sub-plots. Results indicated that nitrogen (N), phosphorus (P) and po tassium (K) content in different parts of wheat varieties was found in the order of grain > straw > spike straw, grain > spike straw > straw and straw > spike straw > grain, respectively. However the concentration of iron (Fe) and manganese (Mn) was found in order of straw > spike straw > grain and straw > grain > spike straw respectively. With respect to nutrients, the highest N (2.28%), P (3,711.6 mg/kg), K (0.48%), Zn (40.6 mg/kg), Fe (124.8 mg/kg) and Mn (33.7 mg/kg) contents were registered in grain of ‘HD 2967’, ‘HD 2967’, ‘HD 2687’, ‘HD 2851’, ‘HD 2687’ and ‘HD 2894’, respectively. The concentration of macro and micro-nutrients were recorded statistically identical in different treatments of Zn fertilization. However, significant increase in macro and micro-nutrients uptake was registered due to Zn fertilization and the highest uptake of nutrients was recorded with application of 1.25 kg Zn/ha through Zn-EDTA + 0.5% foliar spray of Zn-EDTA at maximum tillering and booting stages. Thus, soil (1.25 kg Zn/ ha) + foliar (0.5%) application of Zn-EDTA was found superior with respect to macro and micro-nutrients uptake.

Total phenolic content, phytochemical profile and cytotoxic effects of endemic Alyssum floribundum (Brassicaceae) from Turkey

Alyssum genus has many ethnobotanical uses due to the bioactive compounds it contains (glucosinolates, hydrocarbons, fatty acids and phenolic compounds, etc.). The objective of this study was to assess the total phenolic content, potential bioactive components and cytotoxic effects of ethanol extracts obtained from different parts (root, stem and leaf) of Alyssum floribundum. The Folin-Ciocalteu colorimetric method was utilized to measure the total phenolic content of all extracts. The total phenolic content of different parts A. floribundum were 12.6 ± 02, 8.2 ± 1.2 and 4.9 ± 0.8 mg GAE/g, respectively. The bioactive compounds of different parts A. floribundum were shown by employing gas chromatography coupled to mass spectrometry (GC/MS) and were identified to contain 30 different chemical components in all parts of the plant. The cytotoxic effect was evaluated using the xCELLigence method on the DU-145 prostate cancer cell line. The root, stem and leaf extracts of A. floribundum displayed the strongest cytotoxicity against the DU-145 prostate cancer cell act in a dose-dependent manner after 24 and 48 h with IC50 values of various concentrations after 24 and 48 h were calculated and determined as 192.1–157.4 µg/mL, 29.12–26.93 µg/mL and 226.4–80.23 µg/mL, respectively.

Antioxidant potential and polyphenol content in different parts of Graptophyllum pictum extracts.

The antioxidant potential of Graptophyllum pictum (wungu leaves), an indigenous shrub plant extensively used in traditional medicine in Indonesia, was investigated in this study. The research focused on a comprehensive evaluation of total phenolic content (TPC), total flavonoid content (TFC), 2,2-diphenyl-1-picrylhydrazyl (DPPH), and ferric-reducing antioxidant power (FRAP) across various plant parts, including roots, stems, and flowers, which had been underexplored in prior studies. The ethanol extract derived from wungu flowers and leaves demonstrated notable antioxidant potential, characterized by elevated TPC (12.22 ± 0.31 mg GAE/g DW) and FRAP (37.73 ± 1.08 μmol TEAC/g DW) in the ethanol extract of wungu flowers. Similarly, the ethanol extract of wungu leaves showcased a substantial TFC (2.31 ± 0.18 mg QE/g DW) and DPPH (1.12 ± 0.05 μmol TEAC/g DW), surpassing other parts of the wungu plant in the same or different extracts. These findings suggested that ethanol extracts were a promising foundation for herbal medicines with antioxidant properties, highlighting their potential applications in plant breeding programs. Furthermore, the correlation data underscored the significance of the ethyl acetate and ethanol extracts, revealing a robust correlation between TPC, TFC, and FRAP compared to the n-hexane extract.

Phenolics and flavonoids from Polygonum posumbu and comparision of flavonoid compounds content in different tissues (leaves, stems and roots)

The growing global need for antioxidative phenolics and flavonoids for maintenance of human health resulted into search of new sustainable unexplored medicinal plants used by the traditional healers for various ailments. Many synthetic based products of phenolics and flavonoids have been used, however the demand of eco-friendly, natural herbal based products are increasing. As a result, the current study aims to explore traditional potential of Polygonum posumbu related to its phenolics and flavonoids. Optimization of extraction parameters were employed which includes: solvent selection (water, ethanol, methanol, acetone and ethyl acetate), ethanol composition (40–100%), solvent to sample ratio (30–70 ml/g), temperature (50–80 °C) and time (1–5 h). Under optimal conditions, total phenolics (TPC), total flavonoids (TFC), the extract yield (EY) and antioxidant activities of leaves extract were 162.79 ± 2.28 mg GAE/g, 56.57 ± 6.22 mg QE/g 27.96 ± 0.91%, and 27.34 ± 0.98 μg/ml respectively. Seven flavonoids were quantified in different tissues with significant (p ≤ 0.05) differences found in flavonoids contents in different parts of the plant. Highest concentration of flavonoids was observed in stems: (−)-epicatechin-53.19 ± 1.13 mg/g, myricetin-15.90 ± 0.13 mg/g, quercetin-50.66 ± 0.08 mg/g, luteolin-43.10 ± 0.47 mg/g, apigenin-16.73 ± 0.43 mg/g. Leaves and roots had the highest amount of genistein (05.06 ± 0.01 mg/g) and kaempferol (11.13 ± 0.06 mg/g) respectively. From the study it had been found that Polygonum posumbu possess a very good amount of phenolics and flavonoids and this study details first ever investigation on this plant in terms of phenolics and flavonoids. Therefore, this study enhanced the importance of this bioresource in functional food or nutraceutical industries.

Content and distribution of cyanogenic compounds in cassava roots and leaves in association with physiological age.

Cassava roots are widely consumed in tropical regions of Asia, Africa, and Latin America. Although the protein, vitamin, carotenoid, and mineral content in the leaves makes them a nutritionally attractive option, their consumption is limited due to their high levels of cyanogenic compounds (CCs). In this study, the CC content in different parts of the plant (leaves, storage root cortex, and parenchyma) was assessed at harvest for 50 landrace genotypes representative of cassava diversity in Latin America. The changes in CC in leaves at different physiological ages (3, 6, 9, and 11 months after planting) were also investigated. The average CC was higher in the cortex (804 ppm) and leaves (655 ppm) than in root parenchyma (305 ppm). Genotypes from different regions of Latin America, as identified by seven genetic diversity groups, differed significantly in CC levels. The Andean and Amazon groups had, respectively, the lowest (P = 0.0008) and highest (P < 0.0001) CC levels in all three parts of the plants. Cyanogenic compound concentrations were higher in leaves from young plants (P < 0.0001) and decreased with increasing physiological age. The results help to guide the selection of parental lines with low CC levels for breeding and to contribute to the expanded use of cassava and its by-products for food and feed. Cassava for fresh consumption, especially, requires varieties with low total CC content, especially in the root cortex and parenchyma. COL1108 (204, 213, and 174 ppm, respectively, in the parenchyma, cortex, and leaves) and PER297 (83, 238, and 299 ppm, respectively, in the parenchyma, cortex, and leaves) can fulfill this requirement. © 2023 The Authors. Journal of The Science of Food and Agriculture published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.

The Relationship Between Total Phenol, Total Flavonoid, and IC50 Contents of Different Parts of Satureja thymbra and Nutrient Elements

The goal of this study is to investigate the variations in certain quality parameters, including total antioxidant activity, total phenol and total flavonoid contents, of various organs, including inflorescences, leaves and stems, of the Satureja thymbra plant, which grows naturally in the Kaş district of Antalya. Also, the relationship between these quality parameters and the nutrient content of the plant was revealed. The free radical (DPPH) was used to determine the antiradical scavenging activities of extracts prepared from various parts of the plant. The concentration of the antioxidant compound that can cause a 50 % loss in DPPH free radical activity is expressed by the IC50 value. S. thymbra leaf extracts have higher antiradical scavenging activity (IC50 = 0.11 mg dw/mg-DPPH), total phenol (38.79 mg GAE/g), and total flavonoid (29.0 mg/g) content than extracts of other plant components.

Ecological restoration reduces mercury in corn kernel and the distinction of mercury in corn plants in rural China – A case in Wuchuan mercury mining area

Corn is a crucial crop in China and is widely cultivated in the mercury (Hg) mining region of Guizhou. This study analyzed the Hg content in soil and corn plant samples from the Wuchuan Hg mining area (WCMA) and the surrounding non-Hg mining regions (SNMR). The findings suggest that ongoing ecological rehabilitation and environmental conservation measures in the WCMA have significantly decreased the Hg content in corn kernels. The Hg concentration in different parts of the corn plant varied, being higher in the roots, tassels, and leaves and lower in kernels and stalks. Hg stored in corn plant growing in the WCMA primarily originates from the soil (55.4%), while in the SNMR, it mainly comes from the atmosphere (74.9%). Despite counted only about 7% of the total plant mass, corn roots play a crucial role in soil Hg pollution remediation when corn is used for remediation. Household corn residues burning release about 58.5% and 66.9% of the stored Hg in corn plants growing in the WCMA and the SNMR, respectively, into the atmosphere. Our findings indicate that corn cultivation acts as a reservoir for both soil and atmospheric Hg in the SNMR, while in the WCMA, it serves as a source of atmospheric Hg.

Combined application of biochar and metal-tolerant bacteria alleviates cadmium toxicity by modulating the antioxidant defense mechanism and physicochemical attributes in rice (Oryza sativa L.) grown in cadmium-contaminated soil

Agricultural soil contamination by heavy metal (cadmium) is a widespread issue and causes deleterious effects on crops. One of the most effective and ecofriendly methods for cadmium detoxification is microbe-assisted phytoremediation and soil amendment with biochar. The current study investigated the combined effect of biochar (Parthenium hysterophorus L.) and microbes (Bacillus cereus strain B2) in alleviating cadmium toxicity in rice grown in cadmium-contaminated soil (0, 10, 15, and 20 mg/kg). Results revealed that cadmium caused damage to plant health. Maximum reduction in plant biomass, gas exchange parameters, and chlorophyll content was observed on cadmium 20 mg/kg. As compared with the sole application of biochar (2 %) and microbes, the greatest plant height (33.68%), photosynthetic rate (23.52 %), stomatal conductance (48.93 %), water use efficiency (21.41 %), transpiration rate (58.87 %), chlorophyll a (74.81 %), chlorophyll b (31.28 %), total chlorophyll (60.53 %), and carotenoids (26.97 %) were recorded with combined application of biochar and microbes. Similarly, superoxidase (SOD), catalase (CAT), peroxidase (POD), and absorbate peroxidase (APX) activity was significantly boosted by combined application of microbes and biochar (2 %), which were 33.90 %, 24.18 %, 51.70 %, and 19.06 %, respectively, while significant reduction was found in the ROS (16.60 %), (20.06 %) and MDA (26.08 %) content in rice plants. However, cadmium concentrations in different parts of plant were decreased at higher concentrations of biochar (2 %) with microbes. These findings indicate that combined application of Bacillus cereus strain B2 and biochar could be a promising strategy for reducing rice crop cadmium toxicity and boosting its growth, physiology, and defense system efficiently as compared with sole application.

Characteristics and evaluation of heavy metal pollution in a soil–wheat system of an arid oasis city in northwest China

In this paper, the Cu and Ni accumulation and contamination levels in agricultural soils and wheat around a smelter in Jinchang City in northwest China were investigated with a combination of field investigations and indoor analytical tests, using a soil–wheat system as the study area. The average Cu and Ni contents in the soil were 119.50 mg kg–1 and 123.40 mg kg–1, respectively, both of which exceeded the local soil background values. The Cu and Ni contents in 46.15% o and 26.92% of sampling sites, respectively, exceeded the screening values for soil contamination risk in agricultural land in China. The average Cu content in different parts of wheat was in the order of roots (24.22 mg kg–1) > leaves (20.11 mg kg–1) > husks (5.51 mg kg–1) > grains (4.05 mg kg–1) > stalks (3.74 mg kg–1). Furthermore, the average Ni content ranked as leaves (24.64 mg kg–1) > roots (21.12 mg kg–1) > husks (6.95 mg kg–1) > stalks (1.75 mg kg–1) > grains (0.38 mg kg–1). The health risk evaluation showed that with average hazard index values of 0.88 for adults and 1.04 for children for Cu and Ni in wheat grain, wheat in this region is unlikely to pose a health risk to adults but may pose a lesser health risk to children. The Ni bio–concentration and translocation factors in the husk and leaves of wheat were greater than those of Cu and smaller than those of Cu in the other parts of wheat. The results of this study provide basic data for the remediation of heavy metal contamination in local agricultural soils.

Содержание плутония в растениях на территории Обнинска, прилегающей к хранилищу радиоактивных отходов

Plutonium is long-lived radioactive element of high radiotoxicity. The presence of anthropogenic plutonium in the environment is mainly caused by nuclear tests, nuclear power plants accidents, leaks from nuclear fuel cycle facilities and radioactive waste storages. The radioactive waste storage facility located in Obninsk is one of the first radioactive waste storage facilities built in Russia. Radionuclides leak in the storage from 1998 over 1999 was registered. A set of specific protective engineering measures was carried out in 1999. In subsequent studies, the presence of local radioactive spots, mainly contaminated with 90Sr, was found in the territory of the radioactive waste storage facility and adjacent area. The article presents the results of the 239+240Pu content accumulated by the vegetation growing in the area near the Obninsk radioactive waste storage facility. The analysis of 239+240Pu content in samples was carried out by alpha spectrometry following radiochemical separation. It was found that the plutonium content in the roots of herbaceous plants ranges from (7.92.0)∙10-2 Bq/kg to (1.70.1)∙100 Bq/kg, in the above-ground part from (3.41.0)∙10-2 Bq/kg to (1.20.4)∙10-1 Bq/kg. The distribution of 239+240Pu content in different parts of herbaceous plants are consistent with published data, it means that plutonium is accumulated by the plants root system mainly. The range of 239+240Pu content in parts of shrubs is estimated from (4.0+/-1.4)∙10-2 Bq/kg in branches to (9.0+/-2.7)∙10-1 Bq/kg in white currant berries, and from (4.0+/-1.4)∙10-2 Bq/kg in branches to (3.0+/-0.9)∙10-1 Bq/kg in hazel leaves. The content of 239+240Pu in organs and tissues of woody vegetation varied from (3.4+/-1.0)∙10-3 Bq/kg to (4.2+/-1.3)∙100 Bq/kg. The highest content of plutonium was found in tree bark.

Multi-agent simulation of doughnut deep fat frying considering two domain heating media and sample flipping

Two domain heating media and sample flipping during processing were considered when developing an agent-based model to explain coupled heat and mass transfer phenomena during deep fat frying of doughnuts. The model was validated by comparing the moisture content, oil content and temperature profiles obtained from the experimental results with those obtained from the model. Results of this study showed that the water content of crumb raised to 60% (based on dry weight) whereas, it decreased to less than 10% in the case of doughnut crust during deep fat frying. Simulated profile of oil penetration illustrated that the oil content of different parts of crust were not equal and were affected by frying temperature and crust structure. In general, as the surface of doughnut (a porous material) was heated from the surface, evaporation zones were formed in the thinner parts of the crust and gradually formed oil penetrating areas. Moreover, experimental and simulated data indicated that flipping of samples in the middle of processing time had an important effect on heat and mass transfer during frying. Variation of thermophysical properties in each part of doughnut had a unique behavior. The changes in the density, specific heat capacity and thermal conductivity of crumb followed a sigmoid pattern; whereas, a dominant falling rate period with some variations was observed in crust. Moreover, any changes in moisture content and temperature of crust occurred faster than the crumb. The output of simulation was in a good agreement with the experimental data. With the power of simulation now available for design, the results of this study greatly improve the design of fried foods and frying processes.

Ratiometric luminescent sensor based on BSA-coated gold/silver nanoclusters for the selective determination and spatiotemporal imaging of gallic acid in plants.

Anewfluorescence sensing strategyhas been developed. Four bimetallic nanoclusters, gold/silver, gold/copper, gold/molybdenum and gold/cobalt, were prepared using bovine serum albumin (BSA) as a reducing and stabilizing agent. The fluorescence properties of four nanoclusters were explored by solid-state UV and XPS. The gold/silver nanoclusters (BSA-Au/Ag NCs) with the best ratiometric fluorescence properties for gallic acid (GA) in plants were selected to realize the sensitive detection of GA. GA affected the conformation of BSA, thereby disrupting the luminescent environment of the nanoclusters, resulting in a pronounced fluorescence quenching at 566nm. The ratiometric fluorescence signal (I566/I453) was used for trace detection of GAin plants. It has a wide response range of 1.25-40.0μM and a low detection limit of 45.27nM. GA was detected at 19.49μM in the plant extract, and the spiked recoveries ranged from 96.09 to 104.6%. In addition, due to the non-toxic and biocompatible properties of BSA, BSA-Au/Ag NCs have also been validated for fluorescence imaging of plant tissues. It realized the comparison of GA content in different parts of plants and the difference of GA content in plants after abiotic stress. Therefore, the developed strategy offers potential application for the analytical study of active substances in plants.

Influence of Nitrogen Supply on Growth, Antioxidant Capacity and Cadmium Absorption of Kenaf (Hibiscus cannabinus L.) Seedlings

Kenaf (Hibiscus cannabinus L.) is considered suitable for the remediation of cadmium (Cd)-contaminated farmlands, because of its large biomass and resistance to Cd stress. The addition of nitrogen (N) fertilizer is an important measure used to increase crop yields, and it may also affect Cd accumulation in plants. To clarify the effects of different forms and concentrations of N on plant growth and Cd absorption in kenaf, a hydroponic experiment was conducted using three N forms (NH4+–N, NO3−–N and urea–N) at four concentrations (0, 2, 4 and 8 mM, 0 mM as control) under Cd stress (30 μM). The plant growth, the antioxidant enzyme activity and the Cd contents of various parts of the kenaf seedlings were measured. The results showed that the N form had the greatest impact on the growth of the kenaf and the absorption and transport of the Cd, followed by the interaction effect between the N type and the concentration. Compared to the control, the addition of N fertilizer promoted the growth of kenaf to varying degrees. Among all the treatments, the use of 2 mM of NO3−–N enhanced the biomass and Cd accumulation to the greatest extent compared to CK from 2.02 g to 4.35 g and 341.30 μg to 809.22 μg per plant, respectively. The NH4+–N significantly reduced the Cd contents of different parts but enhanced the translocation factors of Cd stem to root (TF S/R) and leaf to stem (TF L/S) by 34.29~78.57% and 45.10~72.55%, respectively. The peroxidase (POD), superoxide dismutase (SOD) and catalase (CAT) enzyme activities of the kenaf increased with the N treatments, especially with NH4+–N. Overall, applying low concentrations of NO3−–N can better promote the extraction of Cd by kenaf.