Your search keyword '"Weiying Feng"' showing total 99 results

1. Implications of RNA pseudouridylation for cancer biology and therapeutics: a narrative review

Author

Hanyi Ding, Na Liu, Yan Wang, Sofia Abdulkadir Adam, Jie Jin, Weiying Feng, and Jie Sun

Subjects

Pseudouridine, RNA modification, Pseudouridine synthase, Cancer diagnosis, Cancer treatment, Medicine

Abstract

Abstract Background Pseudouridine (Ψ), a C5-glycoside isomer of uridine, stands as one of the most prevalent RNA modifications in all RNA types. Distinguishing from the C-N bond linking uridine to ribose, the link between Ψ and ribose is a C-C bond, endowing Ψ modified RNA distinct properties and functions in various biological processes. The conversion of uridine to Ψ is governed by pseudouridine synthases (PUSs). RNA pseudouridylation is implicated in cancer biology and therapeutics. Objectives In this review, we will summarize the methods for detecting Ψ, the process of Ψ generation, the impact of Ψ modification on RNA metabolism and gene expression, the roles of dysregulated Ψ and pseudouridine synthases in cancers, and the underlying mechanism. Methods We conducted a comprehensive search of PubMed from its inception through February 2024. The search terms included “pseudouridine”; “pseudouridine synthase”; “PUS”; “dyskerin”; “cancer”; “tumor”; “carcinoma”; “malignancy”; “tumorigenesis”; “biomarker”; “prognosis” and “therapy”. We included studies published in peer-reviewed journals that focused on Ψ detection, specific mechanisms involving Ψ and PUSs, and prognosis in cancer patients with high Ψ expression. We excluded studies lacking sufficient methodological details or appropriate controls. Results Ψ has been recognized as a significant biomarker in cancer diagnosis and prognosis. Abnormal Ψ modifications mediated by various PUSs result in dysregulated RNA metabolism and impaired RNA function, promoting the development of various cancers. Overexpression of PUSs is common in cancer cells and predicts poor prognosis. PUSs inhibition arrests cell proliferation and enhances apoptosis in cancer cells, suggesting PUS-targeting cancer therapy may be a potential strategy in cancer treatment. Discussion High Ψ levels in serum, urine, and saliva may suggest cancer, but do not specify the type, requiring additional lab markers and imaging for accurate diagnosis. Standardized detection methods are also crucial for reliable results. PUSs are linked to cancer, but more researches are needed to understand their mechanisms in different cancers. Anticancer treatments targeting PUSs are still under developed.

Published

2024

2. Distribution and risk assessment of nutrients and heavy metals from sediments in the world-class water transfer projects

Author

Weiying Feng, Yingru Tao, Minjie Liu, Yuxin Deng, Fang Yang, Haiqing Liao, Tingting Li, Fanhao Song, and Su Kong Ngien

Subjects

Sediments, Nutrients, Heavy metals, Profiles, Pollution, Environmental sciences, GE1-350, Environmental law, K3581-3598

Abstract

Abstract South-to-North Water Diversion Project, a globally renowned engineering feat, aims to address water supply issues. The sediments within reservoirs play a pivotal role in natural ecosystems, not only as habitats for diverse biota but also as repositories of heavy metals, organic matter, and other contaminants. These sediments serve as a critical interface between sediment and water bodies. This comprehensive analysis focused on the spatial patterns of nutrients, organic matter, and heavy metals in the surface layer and profiles of reservoirs, exploring their interconnectedness. Leveraging the integrated pollution index, organic pollution index, potential ecological risk index, and geo-accumulation index, an ecological risk assessment was performed. The key findings are as follows: (i) Along the Middle Route of the South-to-North Diversion Project, the nutrient and organic matter contents in sediments tends to rise with distance from the Danjiangkou Reservoir, with the TN and TC contents increasing by 2.35- and 3.05-fold, respectively. (ii) As the sediment depth increases, the carbon, nitrogen, phosphorus, and organic matter contents exhibit varying degrees of decline, with average decreases of 62.38%, 67.47%, 17.56%, and 41.83% for TN, TC, TP, and OM, respectively. (iii) Among the eight heavy metals, only manganese (Mn) and zinc (Zn) in the Yahekou Reservoir showed moderate pollution levels, according to the geo-accumulation index. The Mn content within the surface sediments of the six reservoirs ranges from 550 to 1837 mg/kg (average, 1019.5 ± 548.3 mg/kg), whereas the Zn content ranges from 89 to 360 mg/kg (average, 156.5 ± 101.6 mg/kg). (vi) Total phosphorus (TP) and total nitrogen (TN) emerged as the primary pollutants in surface sediments. Comprehensive nitrogen and phosphorus pollution assessment revealed that the surface sediment of Danjiangkou Reservoir is mildly polluted, while Baiguishan and Jiangang Reservoirs are moderately polluted, and the rest are heavily contaminated. For the Yahekou and Chaohe Reservoirs, the average pollutant content indicates moderate pollution, while the remaining reservoirs show mild pollution levels. Graphical Abstract

Published

2024

3. Remote sensing monitoring of irrigated area in the non-growth season and of water consumption analysis in a large-scale irrigation district

Author

He Li, Qingfeng Miao, Haibin Shi, Xianyue Li, Shengwei Zhang, Fengxia Zhang, Huailiang Bu, Pei Wang, Lin Yang, Yali Wang, Heng Du, Tong Wang, and Weiying Feng

Subjects

Hetao Irrigation District, water index, autumn irrigation, water consumption, Agriculture (General), S1-972, Agricultural industries, HD9000-9495

Abstract

Globally, water scarcity threatens food security, especially in arid and semi-arid food-producing regions, such as the Hetao Irrigation District (HID), where the water consumption during the non-growth season (spring irrigation, autumn irrigation) accounts for more than 30 % of the total irrigation volume. Meanwhile, mapping the characteristics of spatial and temporal evolution of the area of cropland irrigated in the spring and autumn and the pattern of water consumption is crucial for strengthening the management of agricultural water use. Evaporation and infiltration of irrigation water are difficult to capture in time due to insufficient timeliness or accuracy of single remote sensing data. This study integrates seven remote sensing datasets (Landsat5, Landsat7, Landsat8, HJ-1A/B, GF-1, Sentinel-2 and MODIS) for the first time to build a high spatial-temporal resolution dataset, and combines the water index NDWI and MNDWI to extract the maximum water range formed after irrigation by manually adjusting the threshold method. In addition to the global land use/cover dataset (GLC FCS30–1985_2020), the cropland layer was superimposed to accurately identify the cropland spring irrigation and autumn irrigation range from 2000 to 2021 in the HID. In the past 20 years, spring-irrigated (SI) areas increased by 1012.60 km2 (+49.96 %), and the autumn-irrigated (AI) areas decreased by 512.63 km2 (-11.02 %). Combined with the quantity of water diversion and displacement, the characteristics of irrigation water consumption in the non-growth season were further analysed. The results showed that the water consumption of spring irrigation increased by 0.67×108 m3 (+22.26 %), and that of autumn irrigation increased by 4.34×108 m3 (+38.82 %). The decrease of autumn- irrigated area and the increase of water consumption were mainly related to the stability of autumn irrigation water, imperfect irrigation and drainage conditions and insufficient field water management. In 2020­2021, the area of non-growth “autumn irrigation - spring irrigation” repeated irrigation is about 1271.52 km2, which can be used as a key control area. This study provides a theoretical basis and direction for rational water use in non-growth seasons of irrigation districts.

Published

2024

4. Eutrophication in cold-arid lakes: molecular characteristics and transformation mechanism of DOM under microbial action at the ice-water interface

Author

Tengke Wang, Weiying Feng, Jing Liu, Wenhong Fan, Tingting Li, Fanhao Song, Fang Yang, Haiqing Liao, and Matti Leppäranta

Subjects

Adapted Kendrick-analogous network visualization, FT-ICR MS, Van Krevelen, microbe, Structure analysis, Production of electric energy or power. Powerplants. Central stations, TK1001-1841, Environmental sciences, GE1-350

Abstract

Abstract During freezing periods, nutrients (carbon and organic matter, etc.) are enriched in the water and sediment of lakes in cold-arid regions, leading to potential algal bloom outbreaks and other health risks to the ecosystem. Particularly, dissolved organic matter (DOM) is a critical component of the nutrients and plays an important role in the global carbon cycle. However, the mechanisms of DOM transfer between ice and water remain unclear. This study analyzed the influence of microbial community on DOM composition using 16 s RNA, 3DEEM, and FT-ICR MS in Daihai Lake and Wuliangsuhai Lake in the Yellow River Basin, China. According to the spectral analysis, the content of endogenous organic matter, such as humus, accounted for 40% of the total DOM in water, while the content of tryptophan and tyrosine accounted for 80% of the total DOM in ice. The results of mass spectrometry showed that lignin was the main component, and the content of organic matter in the ice was less than that in the water. Molecular structures of seven DOM coexisting in the lake ice and water were elucidated with adapted Kendrick-analogous network visualization, which clearly illustrates that long-chain DOM molecules are derived from small molecules, while other heteroatoms are complexed with the side groups. The positive correlations between CHO, CHNO, CHOS, CHOS and Actinomyces indicate that DOM actively interacted with the microbial community. 44% of CHO compounds have the same molecular formula in water, the content of CHOS in the water of the two lakes was closed to 7% higher than that in the ice. Meanwhile, DOM dynamically migrate between ice and water via interstitial water because of the solubility changes under microbial transformation, which has been proved by the decrease in the contents of the humus and tryptophan-like substances in the ice from the bottom to the surface and lower contents of carbohydrate and unsaturated aromatic hydrocarbon in the water than the ice. This study helps to predict the composition and structure of DOM during the migration in lakes and provides a scientific basis for environmental remediation with high concentration of carbon.

Published

2024

5. Shared genetic factors and causal association between chronic hepatitis C infection and diffuse large B cell lymphoma

Author

Leihua Fu, Jieni Yu, Zhe Chen, Feidan Gao, Zhijian Zhang, Jiaping Fu, Weiying Feng, Pan Hong, and Jing Jin

Subjects

Chronic Hepatitis C virus, Diffuse large B cell lymphoma, Mendelian randomization, Colocalization analysis, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282, Infectious and parasitic diseases, RC109-216

Abstract

Abstract Background Epidemiological research and systematic meta-analyses indicate a higher risk of B-cell lymphomas in patients with chronic hepatitis C virus (HCV) compared to non-infected individuals. However, the genetic links between HCV and these lymphomas remain under-researched. Methods Mendelian randomization analysis was employed to explore the association between chronic hepatitis C (CHC) and B-cell lymphomas as well as chronic lymphocytic leukemia (CLL). Approximate Bayes Factor (ABF) localization analysis was conducted to find shared genetic variants that might connect CHC with B-cell lymphomas and chronic lymphocytic leukemia (CLL). Furthermore, The Variant Effect Predictor (VEP) was utilized to annotate the functional effects of the identified genetic variants. Results Mendelian randomization revealed a significant association between CHC and increased diffuse large B cell lymphoma (DLBCL) risk (OR: 1.34; 95% CI: 1.01–1.78; P = 0.0397). Subsequent colocalization analysis pinpointed two noteworthy variants, rs17208853 (chr6:32408583) and rs482759 (chr6:32227240) between these two traits. The annotation of these variants through the VEP revealed their respective associations with the butyrophilin-like protein 2 (BTNL2) and notch receptor 4 (NOTCH4) genes, along with the long non-coding RNA (lncRNA) TSBP1-AS1. Conclusion This research provides a refined genetic understanding of the CHC-DLBCL connection, opening avenues for targeted therapeutic research and intervention.

Published

2024

6. Utilization of cotton byproduct-derived biochar: a review on soil remediation and carbon sequestration

Author

Yingru Tao, Weiying Feng, Zhongqi He, Beibei Wang, Fang Yang, Aainaa Izyan Nafsun, and Yazhai Zhang

Subjects

Cotton, Biochar, Soil remediation, Carbon sequestration, Byproducts, Environmental sciences, GE1-350, Environmental law, K3581-3598

Abstract

Abstract Biochar can improve soil health and fix CO2 by altering soil microenvironment, thus impacting the global carbon cycle and the change of soil ecological environment. Recent studies show that cotton byproduct-derived biochar is a potential effective amendment for soil improvement so that it could play an important role in agricultural and environmental conservation. In this work, research topics on cotton byproduct-derived biochar in soil in last decade and so are systematically reviewed for better understanding of the progresses of cotton byproduct-derived biochar in (i) the morphologic and physicochemical characterization, (ii) latest research hotspots and trends, (iii) the roles in soil reclamation, and (iv) relevant carbon sequestration mechanisms. Finally, the future research directions regarding cotton byproduct-derived biochar mingled to soil environment are discussed. Insight derived from this work would provide scientific basis for promoting more applications of cotton byproduct-derived biochar in soil ecological restoration and carbon fixation. Graphical Abstract

Published

2024

7. QoS Assurance Key Technologies in Space-Ground Heterogeneous Network

Author

Lin LIN, Bin ZHU, Zelin WANG, Guangquan WANG, Haipeng YAO, Tao DONG, and Weiying FENG

Subjects

space-ground heterogeneous network, QoS, LEO, Information technology, T58.5-58.64

Abstract

The high dynamics of the topology structure, the high variability of the links between space and ground, and the highly limited network resource in the space-ground heterogeneous network pose significant challenges.To address these challenges, a space-ground heterogeneous joint QoS assurance scheme was proposed based on deep analysis of space-ground heterogeneous network development situation.The cross-domain network resource orchestration, construction of a space-ground QoS system, dynamic policy control of heterogeneous joint QoS, and on-demand adaptation and deployment of space-ground network resources technologies were discussed.

Published

2024

8. Improved determination of nitrate isotopes in irrigated agricultural areas and Bayesian mixing model quantification of nitrate sources and fate

Author

Weilong Jiang, Fang Yang, Xihuan Wang, Qingfeng Miao, Meicheng Ji, Ting Pan, Qianqian Wang, Zhiming Han, Weiying Feng, and Haiqing Liao

Subjects

Isotopic ratio, δ15N, δ18O-NO3, Chemical conversion, Source analysis, MixSIAR, Agriculture (General), S1-972, Agricultural industries, HD9000-9495

Abstract

Technological advancements in isotope techniques have been widely utilized in environmental pollution research, particularly for the monitoring of nitrate pollution in water. The utilization of pretreatment with an aqueous nitric acid solution offers numerous advantages in analyzing isotopic composition; however, there is still room for improvement regarding conversion efficiency, reduced reaction time, and cost control. In light of this, this study proposes an enhanced chemical conversion method that involves mitigating the interference caused by the nitrogen azide reaction during the pretreatment process, optimizing the purge gas to remove interfering factors, and improving the inlet device for measuring nitrous oxide. The improved method was applied to determine nitrate isotopes in the Ulansuhai Basin, Inner Mongolia and its reliability was verified through analytical results obtained from bacterial denitrification methods. The mean δ15N-NO3- and δ18O-NO3- values determined using the chemical transformation method were 4.85‰ and 23.44‰, respectively. Compared with the previous method, the improved method enhanced the maneuverability of precise control, the pretreatment time was reduced from 2 to 3 hours to 1.5 hours, and the experimental cost was scaled down to half of the original one. In addition, the contribution of each source was calculated by combining nitrate isotopes with a Bayesian stable isotope mixing model. It was found that manure sewage accounted for (50.1±22.6) % while soil nitrogen sources contributed (25.1±20.4) % to nitrate levels in Ulansuhai Lake's water. The chemical conversion methods successfully improved within this study can also be applied to other watersheds or regions. These research findings provide a valuable theoretical foundation for managing nitrogen sources within watersheds.

Published

2024

9. Bioaccessibility-corrected probabilistic health risk assessment of dietary metal(loid) exposure in six major food groups in children from Northwest China

Author

Beibei Wang, Liwen Zhang, Weiying Feng, Han Zhang, Xiaoli Duan, and Ning Qin

Subjects

Bioavailability, Six food groups, Metal(loid)s, Dietary exposure, Probabilistic health risk, Environmental sciences, GE1-350, Environmental law, K3581-3598

Abstract

Abstract Dietary exposure to heavy metals and metalloids [metal(loid)s] deserves increased attention; however, there is a lack of a comprehensive understanding of the risks of dietary exposure from multi-type food intake and multi-metal(loid) exposure using a bioaccessibility-corrected method. Here, we determined the concentration and bioaccessibility of six toxic metal(loid)s in six major food groups in an industrial city with intensive smelting activity. By incorporating children’s dietary patterns, the probability distribution of health risks from dietary metal(loid)s exposure was assessed. Marked differences were observed in the dietary exposure characteristics within metal(loid)s and major food groups. Cereal and vegetables were the major food groups local children intake. Cereals, meat, beans, and aquatic products had the highest concentrations of Cu and Cd, Pb and Cr, Ni, and As, respectively. Generally, meat, eggs, and aquatic products exhibited higher bioaccessibility than cereals, beans, and vegetables. The bioaccessibility of metal(loid)s decreased in the following order: Pb > Cr > Cu > Ni > As > Cd. For non-carcinogenic risks, the average hazard index was 7.3, with 99.6% exceeding acceptable levels. Arsenic was the dominant risk element and aquatic product was the main risk source. The aggregated carcinogenic risk was 3.4 × 10–3, with Cr the major risk contributor and cereals and meat the dominant food sources. The findings demonstrated that (1) the metal(loid) dietary exposure risk of children from areas with intensive smelting activities should be taken seriously, and (2) it is necessary to identify the specific food category and metal(loid) based on a comprehensive analysis of the metal(loid) concentration and bioaccessibility, and dietary habits of the population to effectively reduce risk.

Published

2024

10. Analysis of Nitrogen and Phosphorus Pollution in Shenzhen Bay over the Past 40 Years

Author

Yudong Wang, Weiying Feng, Xuxia Li, Huaming Luo, Wang Xu, Xu Xu, Haipeng Wang, and Yimeng Chen

Subjects

nitrogen and phosphorus pollution, Shenzhen Bay, coastal waters, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

Based on 40 years of routine water quality monitoring data from Shenzhen Bay and special intensive monitoring since 2021, we analysed the spatiotemporal variations in nitrogen and phosphorus pollution. The results indicate serious levels of nitrogen and phosphorus pollution in Shenzhen Bay. Although recent trends show a decline in concentrations of inorganic nitrogen and reactive phosphate—with the annual average concentration of inorganic nitrogen dropping below 1.0 mg/L since 2020 and reactive phosphate levels near the bay mouth decreasing to approximately 0.020 mg/L—the overall water quality still does not meet China’s Class IV seawater quality standards. Additionally, water quality is poorer during the rainy season, with the average summer concentration of inorganic nitrogen being over 25% higher than in spring and autumn. The water quality is primarily influenced by land-sourced pollutants and tidal effects, generally, with the concentration of DIN and DIP decreased from the estuary of the Shenzhen River, the main seagoing river, to the bay mouth. Near the river’s mouth, concentrations of inorganic nitrogen and reactive phosphate are approximately six and four times higher, respectively, than those near the bay mouth. Due to current emission standards and sewage disposal methods, the proportion of nitrate nitrogen in DIN has significantly increased, exceeding 80% since 2020. To improve the water quality of Shenzhen Bay and to reduce pollution inputs, coordinated land and marine development activities are recommended.

Published

2024

11. Influence and Mechanism of Fertilization and Irrigation of Heavy Metal Accumulation in Salinized Soils

Author

Dandan Yu, Qingfeng Miao, Haibin Shi, Zhuangzhuang Feng, Weiying Feng, Zhen Li, and José Manuel Gonçalves

Subjects

saline–alkali soil, fertilizer, irrigation volume amount, heavy metal, microorganism, Agriculture (General), S1-972

Abstract

The impact of fertilization and irrigation on heavy metal accumulation in saline–alkali soil and its underlying mechanisms are critical issues given the constraints that soil salinization places on agricultural development and crop quality. This study addressed these issues by investigating the effects of adjusting organic fertilizer types, proportions, and irrigation volumes on the physicochemical properties of lightly to moderately saline–alkali soils and analyzing the interaction mechanisms between microorganisms and heavy metals. The results indicate that the rational application of organic fertilizers combined with supplemental irrigation can mitigate soil salinity accumulation and water deficits, and reduce the soil pH, thereby enhancing soil oxidation, promoting nitrogen transformation and increasing nitrate–nitrogen levels. As the proportion of organic fertilizers increased, heavy metal residues, enrichment, and risk indices in the crop grains also increased. Compared to no irrigation, supplemental irrigation of 22 mm during the grain-filling stage increased soil surface Cd content, Zn content, and the potential ecological risk index (HRI) by 10.2%, 3.1%, and 8%, respectively, while simultaneously reducing the heavy metal content in grains by 12–13.5% and decreasing heavy metal enrichment. Principal component analysis revealed the primary factors influencing Cu and Zn residues and Cd accumulation in the crop grains. Soil salinity was significantly negatively correlated with soil pH, organic matter, total nitrogen, and ammonium nitrogen, whereas soil organic matter, total nitrogen, ammonium nitrogen, soil pH, oxidation–reduction potential, soluble nitrogen, and microbial biomass nitrogen were positively correlated. The accumulation and residues of Zn and Cu in the soil were more closely correlated with the soil properties compared to those of Cd. Specifically, Zn accumulation on the soil surface was primarily related to aliphatic organic functional groups, followed by soil salinity. Residual Zn in the crop grains was primarily associated with soil oxidation–reduction properties, followed by soil moisture content. The accumulation of Cu on the soil surface was mainly correlated with the microbial biomass carbon (MBC), whereas the residual Cu in the crop grains was primarily linked to the soil moisture content. These findings provide theoretical insights for improving saline–alkali soils and managing heavy metal contamination, with implications for sustainable agriculture and environmental protection.

Published

2024

12. Effects of Combined Application of Organic and Inorganic Fertilizers on Physical and Chemical Properties in Saline–Alkali Soil

Author

Dandan Yu, Qingfeng Miao, Haibin Shi, Zhuangzhuang Feng, and Weiying Feng

Subjects

saline–alkali land, organic–inorganic fertilizer blending, soil, physical and chemical properties, Agriculture

Abstract

To mitigate the issues of severe farmland soil salinization, the environmental degradation stemming from the overuse of chemical fertilizers, and suboptimal soil composition, a study was conducted to investigate the influence of different types and ratios of organic fertilizers on the physical and chemical attributes of saline–alkali soil. This study aimed to investigate the relationship between different types and proportions of organic fertilizers, soil moisture, organic fertilizer application rates, organic carbon molecular structure, and the soil environment in saline–alkali soils. Reducing the application of chemical fertilizers and substituting them with organic fertilizers can improve the soil quality of saline–alkali lands. The results indicated that replacing a part of the urea with organic fertilizer in saline–alkali farmland reduced the soil salinity by 11.1 to 22.8% in the 0–60 cm soil layer, decreased the soil pH by 0.11 to 1.52%, and increased the soil redox potential (Eh) values by 2.5 to 4.3% in the 0–20 cm layer of the mild and moderate saline–alkali soils. It also decreased the accumulation of the soil organic matter (OM) during the growing season. Compared to commercial organic fertilizers, natural organic fertilizers increased the accumulation of the soil soluble carbon (DOC) and nitrogen (DON), resulting in less soil salinity accumulation. When commercial organic fertilizer was applied in a 1:1 ratio with inorganic fertilizer, the salt accumulation was minimized. Compared to conventional fertilization, organic fertilizer reduced the accumulation of the NH4+-N (ammonium nitrogen) and NO3−-N (nitrate nitrogen) in the soil by 3.1 to 22.6%. In comparison to conventional chemical fertilizers, the application of organic fertilizer in the mild and moderate saline–alkali soils increased the accumulation of the DOC, DON, microbial biomass carbon (MBC), microbial biomass nitrogen (MBN), and microbial quotient during the grain-filling stage. Specifically, it increased the DOC, DON, and DOC/DON by 12.7 to 26.7%, 12 to 59.3%, and 15.2 to 35.5%, respectively. The application of commercial organic fertilizer in the mild saline–alkali soils increased the MBC, MBN, MBC/SOC, and MBN/TN by 37.1, 65.6, 36.7, and 4.7%, respectively. Through analyzing the relative proportions of soil surface organic carbon functional groups during the grain filling period, we observed that, after the application of organic fertilizer, the OM in the mildly salinized soils primarily originated from terrestrial plant litter, whereas, in moderately salinized soils, the OM was mainly derived from microbial sources.

Published

2024

13. Seasonal Variations of Ice-Covered Lake Ecosystems in the Context of Climate Warming: A Review

Author

Qianqian Wang, Fang Yang, Haiqing Liao, Weiying Feng, Meichen Ji, Zhiming Han, Ting Pan, and Dongxia Feng

Subjects

ice-covered lakes, seasonal variability, climate change, bibliometrics, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

The period of freezing is an important phenological characteristic of lakes in the Northern Hemisphere, exhibiting higher sensitivity to regional climate changes and aiding in the detection of Earth’s response to climate change. This review systematically examines 1141 articles on seasonal frozen lakes from 1991 to 2021, aiming to understand the seasonal variations and control conditions of ice-covered lakes. For the former, we discussed the physical structure and growth characteristics of seasonal ice cover, changes in water environmental conditions and primary production, accumulation and transformation of CO2 beneath the ice, and the role of winter lakes as carbon sources or sinks. We also proposed a concept of structural stratification based on the differences in physical properties of ice and solute content. The latter provided an overview of the ice-covered period (−1.2 d decade−1), lake evaporation (+16% by the end of the 21st century), the response of planktonic organisms (earlier spring blooming: 2.17 d year−1) to global climate change, the impact of greenhouse gas emissions on ice-free events, and the influence of individual characteristics such as depth, latitude, and elevation on the seasonal frozen lakes. Finally, future research directions for seasonally ice-covered lakes are discussed. Considering the limited and less systematic research conducted so far, this study aims to use bibliometric methods to synthesize and describe the trends and main research points of seasonal ice-covered lakes so as to lay an important foundation for scholars in this field to better understand the existing research progress and explore future research directions.

Published

2024

14. Forms and Migration Mechanisms of Phosphorus in the Ice, Water, and Sediments of Cold and Arid Lakes

Author

Weiying Feng, Yingru Tao, Tengke Wang, Fang Yang, Meng Zhao, Yuxin Li, Qingfeng Miao, Tingting Li, and Haiqing Liao

Subjects

ice, lake, aquatic ecosystem, 31P-NMR, freeze–thaw cycle, Chemical technology, TP1-1185

Abstract

Phosphorus (P) is a crucial nutrient in lake ecosystems and organic phosphorus (Po) is a significant component. However, the distribution characteristics and migration behaviour of Po in ice–water–sediment systems under freezing and thawing conditions in cold and arid regions remain unclear. This study aims to investigate the forms of Po and its contribution to endogenous P pollution. We selected three lakes (Dai, Hu, and Wu Lake) and employed phosphorus nuclear magnetic resonance (31P-NMR) techniques to analyse the following: (1) The total phosphorus (TP) content, which was the highest in the water from Dai Lake (0.16 mg/L), with substantial seasonal variation observed in Wu Lake, where P content was four times higher in summer than in winter because of farmland drainage. (2) Eutrophication analysis, which indicated that Dai Lake had significantly higher eutrophication levels than Wu Lake, with P being the controlling factor in Dai Lake and both N and P in Wu Lake. The proportion of Po in the TP content was 90%, 70%, and 55% for Wu, Dai, and Hu Lake, respectively, indicating that Po was the main component of eutrophic lakes. (3) 31P-NMR, which revealed that orthophosphate (Ortho-P) and monoester phosphate (Mon-P) were the main P components in the winter, with a higher P content in Dai Lake. Ortho-P has a higher content in ice, indicating that inorganic phosphorus (Pi) migration is the main factor in ice–water media. Mon-P showed multiple peaks in Dai Lake, indicating a complex composition of adenosine monophosphate and glucose-1-phosphate. (4) The ice–water phase change simulation experiments, which showed that phosphate was the least repelled in ice, while pyrophosphate (Pyro-P) and macromolecular P were more repelled. Adding sediment enhanced the migration of P but did not change the repulsion of macromolecular P, suggesting the molecular structure as the main influencing factor. These results provide important scientific evidence for the quantitative analysis of Po pollution in lake water environments, aiding in P load reduction and risk prevention and control.

Published

2024

15. Progress and Prospects of Microplastic Biodegradation Processes and Mechanisms: A Bibliometric Analysis

Author

Yingnan Cao, Jing Bian, Yunping Han, Jianguo Liu, Yuping Ma, Weiying Feng, Yuxin Deng, and Yaojiang Yu

Subjects

microplastic, biodegradation, bibliometric, mechanism research, Chemical technology, TP1-1185

Abstract

In order to visualize the content and development patterns of microplastic biodegradation research, the American Chemical Society (ACS), Elsevier, Springer Link, and American Society for Microbiology (ASM) were searched for the years 2012–2022 using Citespace and VOSvivewer for bibliometrics and visual analysis. The biodegradation processes and mechanisms of microplastics were reviewed on this basis. The results showed a sharp increase in the number of publications between 2012 and 2022, peaking in 2020–2021, with 62 more publications than the previous decade. The University of Chinese Academy of Sciences (UCAS), Northwest A&F University (NWAFU), and Chinese Academy of Agricultural Sciences (CAAS) are the top three research institutions in this field. Researchers are mainly located in China, The United States of America (USA), and India. Furthermore, the research in this field is primarily concerned with the screening of functional microorganisms, the determination of functional enzymes, and the analysis of microplastic biodegradation processes and mechanisms. These studies have revealed that the existing functional microorganisms for microplastic biodegradation are bacteria, predominantly Proteobacteria and Firmicutes; fungi, mainly Ascomycota; and some intestinal microorganisms. The main enzymes secreted in the process are hydrolase, oxidative, and depolymerization enzymes. Microorganisms degrade microplastics through the processes of colonization, biofilm retention, and bioenzymatic degradation. These studies have elucidated the current status of and problems in the microbial degradation of microplastics, and provide a direction for further research on the degradation process and molecular mechanism of functional microorganisms.

Published

2024

16. Effects of biochar on soil evaporation and moisture content and the associated mechanisms

Author

Weiying Feng, Tengke Wang, Fang Yang, Rui Cen, Haiqing Liao, and Zhongyi Qu

Subjects

Simulation, Field experiment, Crop, Growth period, Environmental sciences, GE1-350, Environmental law, K3581-3598

Abstract

Abstract High soil evaporation levels are a major contributor to loss of soil moisture in arid and semiarid regions globally. Therefore, it is important to use effective measures to slow the evaporation from farmland soils. We applied various amounts of straw biochar (BC) in a soil column experiment and a field experiment to study the influence of BC on soil evaporation and moisture content, respectively, to improve the water use efficiency of cultivated soil in arid areas. The addition of BC reduced soil evaporation and delayed water loss from the soil by evaporation. In the field experiment, cumulative evaporation in the treatments declined by 9.58% (Bo-10), 10.95% (Bo-30), and 4.2% (Bo-50) compared with that in the control group, demonstrating that 30 t/hm2 BC is the most effective at suppressing soil evaporation. BC also delayed the time required for the soil moisture content to drop to field capacity and increased the upward transport of water from the deeper soil layers at night. Data from continuous monitoring of moisture content for 3 days during each growth period revealed that the increases in moisture replenishment were 18.52–79.62% at the seedling stage, 55.81–202.38% at the jointing stage, 270.83–587.5% at the tassel stage, and 6.66–61.64% at the maturation stage; hence, BC was shown to work best at the tassel stage.

Published

2023

17. Molecular mechanisms of ferroptosis and its roles in leukemia

Author

Zhe Chen, Suying Zheng, Jiongping Han, Leihua Fu, Jiaping Fu, Zhijian Zhang, Pan Hong, and Weiying Feng

Subjects

programmed cell death, ferroptosis, leukemia, reactive oxygen species, immunotherapy, iron metabolism, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Cell death is a complex process required to maintain homeostasis and occurs when cells are damage or reach end of life. As research progresses, it is apparent that necrosis and apoptosis do not fully explain the whole phenomenon of cell death. Therefore, new death modalities such as autophagic cell death, and ferroptosis have been proposed. In recent years, ferroptosis, a new type of non-apoptotic cell death characterized by iron-dependent lipid peroxidation and reactive oxygen species (ROS) accumulation, has been receiving increasing attention. Ferroptosis can be involved in the pathological processes of many disorders, such as ischemia-reperfusion injury, nervous system diseases, and blood diseases. However, the specific mechanisms by which ferroptosis participates in the occurrence and development of leukemia still need to be more fully and deeply studied. In this review, we present the research progress on the mechanism of ferroptosis and its role in leukemia, to provide new theoretical basis and strategies for the diagnosis and treatment of clinical hematological diseases.

Published

2023

18. Distribution and Variation of Soil Water and Salt before and after Autumn Irrigation

Author

Yin Zhang, Qingfeng Miao, Ruiping Li, Minghai Sun, Xinmin Yang, Wei Wang, Yongping Huang, and Weiying Feng

Subjects

Hetao Irrigation District, autumn irrigation, dry drainage, water and salt movement, Agriculture

Abstract

Autumn irrigation is a key measure for alleviating soil salinity and promoting sustainable agricultural development in the Hetao Irrigation district; however, only a part of farmland is irrigated in autumn during the non-growth period of crops, which leads to the redistribution of soil water and salt between autumn-irrigated land (AIL) and adjacent non-autumn-irrigated land (NAIL) after autumn irrigation. To explore the distribution and variation of soil water and salt in different positions of AIL and NAIL after local autumn irrigation and reveal the interaction range between AIL and NAIL, field experiments were carried out for two years in typical test areas. The results showed that compared with non-autumn irrigation, autumn irrigation improved the distribution uniformity of soil water and salt profiles in both horizontal and vertical directions; after autumn irrigation, the water content of the soil at the nearest sampling point to the boundary in the AIL increased the least, but the desalination rate was the greatest, while the water and salt contents of the soil within 45 m from the sampling points to the boundary in the NAIL both increased significantly. NAIL received the drainage of AIL and made the groundwater level after the rise in AIL fell quickly back, but unreasonable autumn irrigation caused the groundwater level of AIL to remain at a high level before freezing, exacerbating the risk of groundwater carrying salts to the surface soil during the freezing and thawing period, detrimental to the growth of crops in the next spring. The research results are of great significance to the rational use of farmland water resources and the improvement of soil salinization in cold and dry areas.

Published

2024

19. Sources, Risks, and Remediation Technologies of Pollutants in Aquatic Environments

Author

Jing Liu, Weiying Feng, and Fang Yang

Subjects

n/a, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

Water, the lifeblood of our planet, is encountering unprecedented challenges stemming from a diverse array of pollution sources, including industrial wastewater, agricultural runoff, and urban domestic sewage [...]

Published

2024

20. Spatiotemporal Absorption Features of Yellow Willow Water Usage on the Southern Edge of the Semi-Arid Hunshandak Sandland in China

Author

Mingyu Ji, Debin Jia, Qingfeng Miao, Yusheng Hao, Shuling Chen, Ting Liu, Lina Yang, Xiaoyan Li, and Weiying Feng

Subjects

Hunshandak Sandland, isotope, leveraging strategy, yellow willow, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

The improvement of water usage efficiency and productivity, as well as the development of effective water management plans, necessitates a comprehensive understanding of how water utilization patterns in different soil layers within arid and semi-arid climates impact the capacity of plant roots to absorb water. However, there is currently no knowledge regarding the water use strategies employed by artificial yellow willow. So, we conducted a study on the hydrogen and oxygen isotopic composition of rainfall in yellow willow (Salix gordejevii) from the semi-arid region located at the southern edge of the Hunshandak Sandland in China. This study utilized measured data on xylem water, groundwater, soil moisture, and rainfall. By employing a combination of the direct comparison method and the MixSIAR model, we investigated the water uptake strategies employed by yellow willow throughout its growing season. The findings revealed that the mean δ D was highest in precipitation and lowest in groundwater, whereas the mean δ18O was highest in stem water and lowest in groundwater. The δ D and δ18O fluctuated significantly in precipitation but were steady in groundwater. Because precipitation was significantly less than evaporation, the slope and intercept were lower for the local than global atmospheric precipitation line. Water availability steadily declined with increasing depth. Lower δ18O values were caused by precipitation diluting the soil water. The MixSIAR results indicated that the primary source in May, September, and October was utilized at 19%, 18%, and 18%, respectively. In contrast, the utilization rate of each source varied considerably in June, July, and August (the primary source was utilized at 19%, 18%, and 18%, respectively). Comparatively high rates of water absorption and utilization were observed in June (19% of the total water source), July (18%), and August (23%). Therefore, the vertical distribution of the root system and variations in the soil water content regulate water usage for the yellow willow. To prevent excessive water usage and promote ecosystem restoration with artificial yellow willow plantations in water-limited desert settings, policy makers should consider the patterns of plant water use and soil water availability. By selecting drought-adapted plant species and optimizing irrigation management, it is possible to reduce water wastage and ensure that water is used efficiently for revegetation and ecosystem restoration, avoiding overuse of water and maintaining the sustainability of revegetation in water-stressed desert areas.

Published

2024

21. P664: REAL-WORLD ANALYSIS OF MUTATION CHARACTERISTICS AND CLINICAL OUTCOMES IN 343 CHRONIC MYELOID LEUKEMIA PATIENTS WITH BCR::ABL KINASE DOMAIN MUTATIONS

Author

Shiwei Hu, Dijiong Wu, Weiying Feng, Lili Chen, Lihong Cao, Xiaoqiong Zhu, Xiudi Yang, Jingjing Zhu, Huafeng Wang, Dan Chen, Hongyan Tong, Ying Lu, Honglan Qian, Yi Wang, Jie Jin, and Jian Huang

Subjects

Diseases of the blood and blood-forming organs, RC633-647.5

Published

2023

22. P684: A MULTICENTER RETROSPECTIVE STUDY IN CHINA: CLINICAL CHARACTERISTICS AND PROGNOSIS OF PATIENTS WITH CML-CP TREATED WITH DIFFERENT TYROSINE KINASE INHIBITORS

Author

Jian Huang, Xinlu Zhang, Weiying Feng, Honglan Qian, Chen Yu, Lirong Liu, Dan Chen, Xiaoqiong Zhu, Huafeng Wang, Xiudi Yang, Jingjing Zhu, Dijiong Wu, Mei Zhou, Ying Lu, Yi Wang, Hongyan Tong, and Jie Jin

Subjects

Diseases of the blood and blood-forming organs, RC633-647.5

Published

2023

23. Effect of Water Conservation and Nitrogen Reduction on Root Growth and Yield in Spring Maize in Typical Sand Interlayered Soil

Author

Wei Sun, Haibin Shi, Xianyue Li, Qingfeng Miao, Jianwen Yan, Zhuangzhuang Feng, Yinglong Qi, and Weiying Feng

Subjects

sand interlayered soil, water saving and nitrogen reduction, root growth, root length density, WUE, correlation analysis, Agriculture (General), S1-972

Abstract

Given the low water and fertiliser use efficiency and the extensive distribution of sand interlayered soil in the Hetao irrigation district (HID), this study aimed to investigate the effects of different irrigation and fertilisation regimes on root parameters and yield in spring maize grown in sand interlayered soil. A two-year field plot experiment was conducted using the spring maize “Ximeng 3358” under three irrigation and nitrogen levels. Root length (RL), surface area (RS), diameter (RD), volume (RV), and length density (RLD), grain yield, and water use efficiency (WUE) were examined. Root growth was inhibited at the sand layer, with approximately 72.46–87.37% of the roots concentrated in the 0–40 cm soil layer. Notably, the proportion of roots in the bottom layer was 24.61–87.37% higher than that in the sub-bottom layer. Moreover, RL, RS, RD, and RV peaked in the medium irrigation and nitrogen fertilisation (I2F2) treatment. Furthermore, correlation analysis showed that the root parameters were significantly positively correlated with yield and WUE, with RS being most correlated to yield and WUE. Roots at a narrow row spacing of 20 cm (NR20) and at a depth of 10–20 cm were strongly correlated with yield and WUE. Conclusively, the I2F2 treatment can be used as the optimal combination of water and nitrogen for sand interlayered soil farmlands.

Published

2024

24. Characteristics and Migration Dynamics of Microplastics in Agricultural Soils

Author

Yuxin Deng, Zijie Zeng, Weiying Feng, Jing Liu, and Fang Yang

Subjects

agriculture, microplastics, microorganisms, transformation, degradation, Agriculture (General), S1-972

Abstract

The risks brought by microplastics (MPs) to agricultural soil structure and crop growth in the agricultural system are the focus of global debate. MPs enter the soil through various routes, such as through the use of agricultural mulch and atmospheric deposition. Here, we review the research on MP pollution in the soil during the last 30 years. This review focuses on (i) the sources, types, and distribution characteristics of MPs in agricultural soils; (ii) the migration and transformation of MPs and their interactions with microorganisms, organic matter, and contaminants in agricultural soils; and (iii) the effects of environmental factors on the composition and structure of MPs in agricultural soils. This review also proposes key directions for the future research and management of MPs in the agricultural soil. We aim to provide a theoretical basis for the fine management of agricultural farmland.

Published

2024

25. Simulating Water and Salt Migration through Soils with a Clay Layer and Subsurface Pipe Drainage System at Different Depths Using the DRAINMOD-S Model

Author

Feng Tian, Qingfeng Miao, Haibin Shi, Ruiping Li, Xu Dou, Jie Duan, and Weiying Feng

Subjects

DRAINMOD-S, Hetao Irrigation District, saline–alkali soil, subsurface drainage system, clay layer, Agriculture

Abstract

Soil salinization affects more than 25% of land globally. Subsurface pipe drainage is known for its effectiveness in improving saline–alkali land. The red clay layer (RCL) hinders soil improvement in the Hetao Irrigation District of Inner Mongolia, China. The soil water and salt migration rules at different buried depths and RCL were studied based on the field subsurface pipe drainage test and simulation using the DRAINMOD-S model (Version 6.1). The following implications can be drawn from the results: (1) Although the RCL affected the accuracy of the model, the calibrated statistical results met the application requirements, and the DRAINMOD-S model can be used to analyze subsurface pipe drainage under different distribution conditions of the RCL. (2) The RCL can reduce the drainage efficiency of the subsurface pipe, specifically when the distribution is shallow. (3) The soil desalting rate increased with an increase in the buried depth of the subsurface pipe. The desalination effect of shallow soil was better than that of deep soil. The RCL reduced the drainage and salt removal efficiency of the subsurface pipe. Burying the subsurface pipe as far above the RCL as possible should be considered. Thus, it is feasible to apply the DRAINMOD-S model to relevant studies.

Published

2023

26. Soil Water and Salt Transport in Severe Saline–Alkali Soil after Ditching under Subsurface Pipe Drainage Conditions

Author

Feng Tian, Haibin Shi, Qingfeng Miao, Ruiping Li, Jie Duan, Xu Dou, and Weiying Feng

Subjects

Hetao Irrigation District, saline–alkali soil, subsurface drainage system, ditching, DRAINMOD-S, Agriculture (General), S1-972

Abstract

The subsurface pipe drainage project is essential in farmland drainage operations and is globally recognized as an effective saline–alkali land improvement measure owing to its efficient drainage capacity and low land occupation rate. This study aimed to establish enhanced methods for improving saline–alkali land by combining ditching with subsurface pipe drainage. The ditching was conducted at a depth of 60 cm based on the existing subsurface pipe arrangement. The calibrated DRAINMOD-S model was employed to simulate the test area with different ditching depths and subsurface pipe arrangement parameters. Furthermore, the law of soil water and salt transport in the subsurface pipe drainage system at different ditching depths was investigated. After ditching, the total unit drainage volume of leaching increased by an average of 14.65% over two years and the water storage of different soil layers in the different plots decreased by 1.37–1.48 mm on average. Ditching demonstrated a superior salt-leaching effect in areas with subsurface pipe layouts. The soil desalination rate of different soil layers increased by 6.40–13.40% on average, with a more significant impact on the surface soil desalination rate. The effect of the increased desalination rate was more apparent as the ditching depth increased. However, as the buried depth of the subsurface pipe increased, the relationship between the ditching depth and soil desalination rate became insignificant. Ditching improved the salt-leaching effect of subsurface pipe drainage projects, which can effectively reduce the cost of subsurface pipe burial, consequently promoting subsurface pipe use.

Published

2023

27. Water and Salinity Variation along the Soil Profile and Groundwater Dynamics of a Fallow Cropland System in the Hetao Irrigation District, China

Author

Cong Hou, Qingfeng Miao, Haibin Shi, Zhiyuan Hu, Yi Zhao, Cuicui Yu, Yan Yan, and Weiying Feng

Subjects

soil moisture, salinity, groundwater, principal component analysis, soil ions, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

Managing soil salinity has always been a difficult problem for agriculture. Balancing water and salt while maintaining crop quality and yield is a key issue for agricultural sustainability. The Hetao lrrigation District in China has a complex mix of cultivated and uncultivated land which plays a crucial role in soil salinization processes. To investigate the dynamic properties of soil moisture and salinity, soil ions and groundwater, cultivated and fallow soils in the Hetao lrrigation District were analyzed, side by side, using a combination of field and laboratory tests, with data processed using univariate and multivariate statistical approaches. The results showed that soil moisture increased with increasing soil depth in both cultivated and fallow soils. Salinity showed an increasing trend in 2022 and 2023 from April to September. The soil ions were mainly sulfate in the cultivated soils and chloride in the fallow soils. The characteristic factors affecting salt accumulation in cultivated soils are Na++K+, Cl−, SSC, SO42−, HCO3−, and pH, and the characteristic factors affecting salt accumulation in fallow soils are Na++K+, Cl−, SSC, HCO3−, and pH. Water table depth varied with irrigation and precipitation and was strongly influenced by external environmental factors. Groundwater salinity remained stable throughout the study period. This study provides a theoretical basis for the prevention and control of soil salinization in arid and semiarid areas through the “dry drainage salt” measure.

Published

2023

28. Systematic Review of Contaminants of Emerging Concern (CECs): Distribution, Risks, and Implications for Water Quality and Health

Author

Weiying Feng, Yuxin Deng, Fang Yang, Qingfeng Miao, and Su Kong Ngien

Subjects

contaminants of emerging concern, POPs, microplastics, endocrine disruptor, antibiotic, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

The introduction of contaminants of emerging concern (CECs) into the environment has raised concerns due to the significant risks they pose to both ecosystems and human health. In this sys-tematic review, we investigate research trends on CECs worldwide over the past 10 years, focus-ing on four critical aspects: (i) the identification and distribution of typical CECs across various media, (ii) the sources and environmental behavior of CECs, (iii) the implications of CECs expo-sure on human health, and (iv) risk assessment and control measures for CECs. The review re-veals a comprehensive understanding of the typical types and distribution of CECs in different environmental media, shedding light on their prevalence and potential impact on ecosystems. Furthermore, insights into the sources and behavior of CECs provide crucial information for de-vising effective strategies to mitigate their release into the environment. By examining the health effects of EC exposure, we highlight the importance of considering potential risks to human well-being. This aspect of the review emphasizes the significance of monitoring and managing CECs to safeguard public health. The review also synthesizes the advancements in risk assessment methodologies and control measures for CECs, which are essential for developing comprehensive regulations and guidelines to manage these contaminants effectively. Drawing from the findings, we identify future research directions for CECs in aquatic environments.

Published

2023

29. Spatial Variations and Distribution Patterns of Soil Salinity at the Canal Scale in the Hetao Irrigation District

Author

Zhiyuan Hu, Qingfeng Miao, Haibin Shi, Weiying Feng, Cong Hou, Cuicui Yu, and Yunfang Mu

Subjects

salinization, soil particle diameter, spatial variations, groundwater depth, ordinary Kriging, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

Soil salinization is a major factor impacting global crop yields. To explore the spatial distribution and influencing factors of soil water and salt in typical canals of the Hetao irrigation district, regional soil information was monitored at fixed locations. In this study, classical statistics, geostatistics, and spatial autocorrelation methods were used to conduct quantitative analyses of soil salt content, water content, soil particle size distribution, and groundwater depth. The variation coefficient of the soil salt content in the 20–40 and 40–60 cm soil layers was between 10% and 100%, which corresponds to a medium degree of variation; the other soil layers had strong degrees of variation. The soil moisture content in each layer varied moderately. The gold coefficients of soil salt content and water content were less than 0.25, and the Z value was greater than 0, showing a strong spatial correlation and certain spatial agglomeration characteristics, which were mainly affected by structural factors in the study area. The distribution patterns of soil water and salt were affected by soil particle size. Sand content decreased with increasing depth, soil salt was negatively correlated with sand content, and soil water was positively correlated with sand content. Soil salinity was significantly affected by groundwater depth and increased with decreasing groundwater depth, following an exponential relationship. When the groundwater depth exceeded 1.7 m, the soil salt content exhibited small changes with groundwater depth. The results of this study could play a guiding role in terms of understanding the degree of soil salinization surrounding canals in the Hetao irrigation area and adjusting land management strategies over time.

Published

2023

30. Immune Status and Chemokine C Receptor 7 Expression in Primary in Patients with Immune Thrombocytopenia

Author

Lin Zhang, Guo-zhong Zhou, Weiying Feng, and Dan Li

Subjects

primary immune thrombocytopenia, immune state, chemokine c receptor 7, t-cells, Diseases of the blood and blood-forming organs, RC633-647.5

Abstract

Objective: The present study investigated immune disorders and chemokine C receptor 7 (CCR7) expression in primary immune thrombocytopenia (ITP) patients and analyzed their changes and clinical significance before and after treatments. Materials and Methods: Flow cytometry was used to detect the proportion of different immune cell subsets in the peripheral blood of 42 patients with ITP and 20 healthy controls at different time points. Treatments included first-line drugs, such as glucocorticoids and intravenous immunoglobulin, and second-line therapy, such as interleukin-11 and thrombopoietin receptor agonists. Results: An elevated CD4/CD8 ratio and decreased natural killer (NK) cells and CD4+CD25+CD127low regulatory T-cells (Tregs) were found in pretreatment ITP patients compared to healthy controls. The newly diagnosed group had a higher CD4/CD8 ratio and more NK cells than the relapsed group. Treg levels of the remission group were higher than those of the recurrence group. The CD4+CCR7+, CD8+CCR7+, and CCR7+ subsets of B cells and NK cells showed higher increases in the newly diagnosed and relapsed group compared to controls and the remission group. The values for the CD4+CCR7+ and CD8+CCR7+ subsets in the relapsed group were slightly higher than those in the newly diagnosed group. The CCR7+ subsets of CD4+ T-cells, CD8+ T-cells, NK cells, and B cells had lower values in the remission group compared to the relapsed group. Higher levels of the CD8+CCR7+ subset and lower levels of NK cells were found in the remission group compared to the controls. The ratio between the CD4+CCR7+ subset and CD8+CCR7+ subset was lower in ITP patients than in healthy controls. There was a negative correlation between the CD8+CCR7+ subset and platelet count in the ITP patients. Conclusion: ITP patients with CCR7 had immune disorders and high heterogeneity, and CCR7 was found to be involved in the pathogenesis of ITP. Further studies are needed to investigate effective treatments for ITP by targeted regulation of CCR7.

Published

2022

31. Community characteristics and functional gene response analysis of phosphorus-metabolizing bacteria in plateau saline lake sediments

Author

Wenhuan Yang, Jie Ma, Yu Zhen, Weiping Li, Zhi Yao, and Weiying Feng

Subjects

plateau, lake sediment, salinity, phosphorus metabolism, microorganisms, community composition, Environmental sciences, GE1-350

Abstract

Microbial phosphorus metabolism in sediments and the biogeochemical cycling of phosphorus have been central issues in lake ecosystems, but the analysis of microbial community characteristics and influential factors of phosphorus metabolic processes in sediments from highland saline lakes have not been well documented. In this study, metagenome sequencing technology was used to analyze the diversity of community characteristics and the relationship between nitrogen and phosphorus functional genes of microorganisms involved in phosphorus metabolic processes in Daihai sediments under high saline conditions, as well as the response of microorganisms involved in phosphorus metabolic processes to changes in environmental factors, including salinity, pH, and the N/P ratio. The results showed that 1) salinity had positive correlations with Bacteroidetes involved in the major metabolic pathways (ko00030, ko00562, and ko00190) and positively correlated with the specific dominant bacteria involved in the minor pathways (ko00564 and ko00440); 2) norB and nirS denitrification genes were involved in a major component of phosphorus metabolism, and these functional genes of nitrogen metabolism had significant (p < 0.05) effects on phytate hydrolysis, phosphate hydrolysis, and polyphosphate synthesis and decomposition; and 3) environmental factors influenced the diversity of the bacterial community characteristics in the order of salinity > N/P ratio > pH. This study provides new insights into the analysis of the causes of eutrophication and the current state of imbalance in the hydroecological structure of saline lakes on plateaus, as well as an indication of the interactions between the global lake nitrogen and phosphorus cycles.

Published

2022

32. Water Environment Pollution and Control in the Dual-Carbon Background

Author

Weiying Feng, Fang Yang, and Jing Liu

Subjects

n/a, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

Water pollution and control are becoming increasingly important in the global context of carbon peaking and carbon neutrality [...]

Published

2023

33. Study on Water and Salt Transport under Different Subsurface Pipe Arrangement Conditions in Severe Saline–Alkali Land in Hetao Irrigation District with DRAINMOD Model

Author

Feng Tian, Qingfeng Miao, Haibin Shi, Ruiping Li, Xu Dou, Jie Duan, Jing Liu, and Weiying Feng

Subjects

Hetao Irrigation District, saline–alkali soil, subsurface drainage system, DRAINMOD, water and salt transport, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

As an effective method to improve saline–alkali land, the drainage from subsurface pipes has been extensively studied in typical arid and semi-arid agricultural areas (Hetao Irrigation District). However, there are few studies on the improvement of subsurface pipe layout and the long-term soil salinization control in the process of leaching and soil amendment with subsurface pipes in this area. This study investigated the water and salt migration in the process of amending the heavy saline soil. Field experiments growing sunflowers and numerical model calculation were combined in this research. It was found in the field experiment that the salt concentration in the surface pipe drainage was positively correlated with the salt content in the soil and the depth of the pipe, while it was negatively correlated with the amount of irrigation water and the spacing of crops. Thus, the soil desalting rate (N) and salt control rate (SCR) were positively correlated with the depth of the pipe, and they were negatively correlated with the spacing. The leaching effect of irrigation would decrease when the soil salt content decreased. On the basis of field experiments, the DRAINMOD model and drainmod equation were used to calculate the water and salt migration in 38 different field plots during 2019 and 2020. When N was the same, the soil salinity in several plots with large burial depth could be controlled below the salt tolerance threshold of sunflowers during the growth period in the second year. The quantitative relationship between N and SCR, soil salt content before leaching, water amount of leaching, pipe spacing and buried depth was already established. These results can help develop strategies for desalination and salt control in the soil in the arid and semi-arid areas with the optimal layout of subsurface pipes.

Published

2023

34. Stress Corrosion Cracking in Amorphous Phase Separated Oxide Glasses: A Holistic Review of Their Structures, Physical, Mechanical and Fracture Properties

Author

Weiying Feng, Daniel Bonamy, Fabrice Célarié, Paul C. M. Fossati, Stéphane Gossé, Patrick Houizot, and Cindy L. Rountree

Subjects

sodium borosilicate glasses, amorphous phase separation, miscibility gap, physical properties, mechanical properties, dynamic fracture, Chemical technology, TP1-1185

Abstract

Stress corrosion cracking is a well-known phenomenon in oxide glasses. However, how amorphous phase separation (APS) alters stress corrosion cracking, and the overall mechanical response of an oxide glass is less known in literature. APS is a dominant feature concerning many multicomponent systems, particularly the ternary sodium borosilicate (SBN) glass systems. Its three constituent oxides have significant industrial relevance, as they are the principal components of many industrial oxide glasses. Simulations and experimental studies demonstrate the existence of a two-phase metastable miscibility gap. Furthermore, theory suggests the possibility of three-phase APS in these oxide glasses. Literature already details the mechanisms of phase separation and characterizes SBN microstructures. Realizing that glasses are structurally sensitive materials opens a number of other questions concerning how the mesoscopic APS affects the continuum behavior of glasses, including dynamic fracture and stress corrosion cracking. This paper reviews current literature and provides a synthetic viewpoint on how APS structures of oxide glasses alter physical, mechanical, dynamic fracture, and stress corrosion cracking properties.

Published

2021

35. Distribution, Sources, and Risk of Polychlorinated Biphenyls in the Largest Irrigation Area in the Yellow River Basin

Author

Qi Zhang, Yafang Li, Qingfeng Miao, Guoxia Pei, Yanxia Nan, Shuyu Yu, Xiaole Mei, and Weiying Feng

Subjects

Yellow River irrigation area, polychlorinated biphenyl, distribution characteristics, source apportionment, health risks, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

To investigate the contamination of PCBs in agricultural soils irrigated chronically with polluted water and the distribution and migration of PCBs under long-term irrigation, 100 farmland soil profile samples were collected in the Yellow River irrigation area in Inner Mongolia, China, to determine PCB content. Cluster analysis was used to identify possible sources of PCBs products, and the USEPA Health Risk Evaluation Model assessed the health risks posed by PCBs to humans. The results showed that the detection rates of eight monomers in the different soil layers of each sample site ranged from 5% to 90%, and the concentration ranged from not detected to 87.71 ng·g−1. The PCBs content showed a vertical distribution rule of accumulation in the shallow layer, sudden decrease in the middle layer. Low-chlorinated PCBs were dominant in each soil profile. Source identification indicated that PCB pollution in the study area originated mainly from the Aroclor1242, Aroclor1248, Aroclor1016, Aroclor1232, and Aroclor1221 industrial products and domestic transformer oil. Finally, a health risk assessment demonstrated that child and adult groups in study area were exposed to negligible carcinogenic and noncarcinogenic risks.

Published

2022

36. Treatment of Wastewater Effluent with Heavy Metal Pollution Using a Nano Ecological Recycled Concrete

Author

Jing Liu, Jiayi Su, Zhenyu Zhao, Weiying Feng, and Shuai Song

Subjects

adsorption, heavy metal pollution, nano ecological, recycled aggregates, water stress, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

Water pollution exacerbates water stress and poses a great threat to the ecosystem and human health. Construction and demolition waste (CDW) due to rapid urbanization also causes heavy environmental burdens. A major proportion of CDW can be effectively converted into recycled aggregates, which can be reused in many fields, including environment remediation. In this study, a nano ecological recycled concrete (nano-ERC) was produced with recycled aggregates and copper oxide nanoparticles (nCuO) to remove heavy metals (HMs) from a simulated wastewater effluent (SWE) for further treatment. Recycled aggregates were obtained from CDW, thereby simultaneously reducing the treatment cost of the SWE and the environmental burden of solid waste. The adsorption capacity of nano-ERC was presumed to be significantly enhanced by the addition of nCuO due to the unique large surface-to-volume ratio and other properties of nanoparticles. The SWE containing five common HMs, arsenic (As), chromium (Cr), cadmium (Cd), manganese (Mn) and lead (Pb), was filtered through a control ERC and nano-ERCs, and the concentrations of these HMs were determined with ICP-MS in the SWE and the filtrates. Results showed the nano-ERCs could significantly remove these HMs from the SWE compared to the control ERC, due to the enhanced adsorption capacity by nCuO. The relative weighted average removal percentage (RWAR%) was in the range of 53.05–71.83% for nano-ERCs and 39.27–61.65% for control ERC. Except for Cr, concentrations of these HMs in the treated wastewater effluent met the requirements for crop irrigation or scenic water supplementation; the Cr may be removed by multiple filtrations. In conclusion, nano-ERC can serve as a cost-effective approach for the further treatment of wastewater effluent and may be applied more widely in wastewater treatment to help relieve water stress.

Published

2022

37. Effects of Polyacrylamide-Based Super Absorbent Polymer and Corn Straw Biochar on the Arid and Semi-Arid Salinized Soil

Author

Weiying Feng, Jiayue Gao, Rui Cen, Fang Yang, Zhongqi He, Jin Wu, Qingfeng Miao, and Haiqing Liao

Subjects

electrical conductivity, field trials, ion concentration, irrigation district, Agriculture (General), S1-972

Abstract

Green approaches are much more appreciable during the present scenario. Soil amendments are frequently applied for improving water use efficiency, reducing soil salinity in arid and semi-arid areas, controlling the secondary salinization of cultivated soils, and increasing the carbon sequestration capacity of soils. Thus, lab soil column simulation experiments and field experiments were carried out to evaluate these functions of two separate amendments, polyacrylamide-based super absorbent polymer (SAP) and corn straw biochar at different application rates. The simulation experiments showed that both SAP and biochar inhibited the accumulation of soil salinity, with a reduced rate of 9.7–26.3% and 13.5–37.2%, respectively, dependent on the amendment application rates. The field experiments found different salt inhibition effects of the two amendments with growth stages of maize. Soil salinization was inhibited in the pre-germination and early jointing stages by SAP, but throughout the whole growth period by biochar. Both soil amendments reduced soil electrical conductivity, and biochar increased the soil contents of Ca2+, Mg2+, and K+. Our observations demonstrated that application of biochar and SAP played important roles in increasing soil fertility and inhibiting soil salt accumulation. It provided an effective method to potentially mitigate the environmental crisis and promote sustainable development in agriculture.

Published

2020

38. Iterative signal detection based soft interference cancellation for satellite-terrestrial downlink NOMA systems

Author

Meng, Sun, primary, Qi, Zhang, additional, Haipeng, Yao, additional, Ran, Gao, additional, Xiangjun, Xin, additional, Feng, Tian, additional, Weiying, Feng, additional, and Dong, Chen, additional

Published

2024

39. Analysis of genetic test results in 378 patients suspected of thalassaemia

Author

Jing Jin, Weiying Feng, Zehao Fang, Jiaping Fu, Hongqiang Luo, Pan Hong, Li Hong, and Lin Zhang

Subjects

Bioengineering, Molecular Biology, Biotechnology

Published

2023

40. Gene Mutations and Targeted Therapies of Myeloid Sarcoma

Author

Leihua Fu, Zhijian Zhang, Zhe Chen, Jiaping Fu, Pan Hong, and Weiying Feng

Subjects

Oncology, Pharmacology (medical)

Published

2023

41. First reported case of splenic diffuse red pulp small B-cell lymphoma with novel mutations in CXCR4 and TRAF3 genes

Author

Suying Zheng, Ling Lin, Jing Jin, Fang Liu, Jianguo Wei, Yi Feng, Yaping Zhang, Hongqiang Luo, Jiayue Qin, and Weiying Feng

Subjects

Hematology

Published

2023

42. Chemical composition, sources, and ecological effect of organic phosphorus in water ecosystems: a review

Author

Weiying Feng, Tengke Wang, Yuanrong Zhu, Fuhong Sun, John P. Giesy, and Fengchang Wu

Abstract

Phosphorus (P) affects the water–air CO2 flux through primary productivity, and affects the changes of carbon cycle and ecological environment in the global world. Organic phosphorus (Po) is an important P component in water environments. Various processes control the formation and transformation of Po and outbreaks of algal blooms. Here, research topics on Po in global water over the past 50 years are systematically reviewed to understand the progress in the (i) Po pretreatment techniques in various media, (ii) technical methods and qualitative and quantitative research on chemical composition of Po and bioavailability, (iii) source analysis of and factors affecting Po in different media of water environments and biogeochemical processes, (iv) interactions among Po, organic matter, and minerals, and their environmental behaviors, and (v) quantification of material exchanges at the sediment–water interface, interfacial processes, and ecological effects. Finally, the future research directives regarding Po in water environments are discussed. The findings provided an important scientific basis to formulate and revise global standards for water nutrients and a better understanding of water eutrophication and its control. Graphical Abstract

Published

2023

43. MALAT-1 regulates the AML progression by promoting the m6A modification of ZEB1

Author

Jing Jin, Leihua Fu, Pan Hong, and Weiying Feng

Subjects

General Biochemistry, Genetics and Molecular Biology

Abstract

Metastasis-associated lung adenocarcinoma transcript 1 (MALAT-1) is abnormally upregulated in various human cancers. However, the role of MALAT-1 in acute myeloid leukemia (AML) remains unclear. This study investigated the expression and function of MALAT-1 in AML. MTT assay was used to determine cell viability, qRT-PCR was applied to determine the RNA levels. Western blot was performed to detect the protein expression. Flow cytometry was conducted to measure cell apoptosis. RNA pull-down assay was carried out to detect the interaction between MALAT-1 and METTL14. RNA FISH assay was performed to determine the localization of MALAT-1 and METTL14 in AML cells. Our results have revealed the key role of MEEL14 and m6A modification in AML. Besides, MALAT-1 was significantly up-regulated in AML patients. MALAT-1 knockdown inhibited the proliferation, migration and invasion of AML cells, and induced cell apoptosis; additionally, MALAT-1 binding to METTL14 promoted the m6A modification of ZEB1. Besides, ZEB1 overexpression partially reversed the effect of MALAT-1 knockdown on the cellular functions of AML cells. Taken together, MALAT-1 promoted the aggressiveness of AML through regulating m6A modification of ZEB1.

Published

2023

44. Effect of straw biochar on soil evaporation and its mechanism

Author

weiying feng, tengke wang, Fang Yang, Rui Cen, and Haiqing Liao

Abstract

High soil evaporation levels are a major contributor to loss of soil moisture in arid and semiarid regions globally. Therefore, it is important to use effective measures to slow down the evaporation from farmland soils. We applied various rates of straw biochar (BC) in a soil column experiment and a to study the influence of BC on soil evaporation and moisture content, respectively, so as to improve the water use efficiency of cultivated soil in arid areas. In the field experiment, cumulative evaporation in the treatments declined by 9.58% (Bo-10), 10.95% (Bo-30) and 4.2% (Bo-50) compared with that in the control group, 30 t/hm2 BC was the most effective at suppressing soil evaporation. Data from continuous monitoring of moisture content for 3 days during each growth period revealed that the increases in moisture replenishment were 18.5–79.6% at the seedling stage, 55.8–202.4% at the jointing stage, 270.8–587.5% at the tassel stage and 6.7–61.6% at the maturation stage, BC was shown to work best at the tassel stage. The addition of BC reduced soil evaporation and delayed water loss from the soil by evaporation. BC also delayed the time required for the soil moisture content to drop to field capacity and increased the upward transport of water from the deeper soil layers at night. The effective evidence of soil column experiment and field experiment showed that straw biochar could effectively reduce soil evaporation and increase soil moisture content.

Published

2023

45. Synthesis of Cu2+ Doped Biochar and its Inactivation Performance of Microcystis Aeruginosa: Significance of Synergetic Effect

Author

Xing Gao, Weiying Feng, Jingtian Zhang, Hanxiao Zhang, and Shouliang Huo

Published

2023

46. Routing and Wavelength Assignment Algorithm Based on Link Distance and Hop Count Balancing in Double Layer Satellite Optical Network

Author

Chendi Feng, Yuanfeng Li, Qi Zhang, Weiying Feng, Dong Chen, Jinxi Qian, Ying Tao, Feng Tian, and Qinghua Tian

Published

2022

47. Load balancing routing algorithm based on geographical location code

Author

Hui Li, Furong Chai, Dong Chen, Qi Zhang, Weiying Feng, Jinxi Qian, Ying Tao, Feng Tian, and Qinghua Tian

Published

2022

48. Pattern changes of microbial communities in urban river affected by anthropogenic activities and their environmental driving mechanisms

Author

Weiying Feng, Jiayue Gao, Yimei Wei, Danni Liu, Fang Yang, Qiuying Zhang, and Yangwei Bai

Subjects

Pollution

Abstract

The microbial community structure of sediments in the Bahe River Basin, China was studied using a high-throughput sequencing platform and PCR amplification to investigate the pattern changes in microbial communities in urban rivers affected by anthropogenic activities and their environmental driving mechanisms. The results demonstrated that the average total nitrogen and total phosphorus in the sediments were 524 and 734 mg/kg, respectively. The T, COD and $${\text{NH}}_{4}^{ + }$$ NH 4 + -N of the water and the moisture content of the sediments has significantly impacted on the microbial community structure. Twenty microbial species with a relative abundance > 1% in the sediments of the river were observed, accounting for 95–99% of the total microbial community. The primary species were Proteobacteria (13.86–69.14%), Firmicutes (1.45–58.33%), Chloroflexi (3.68–26.18%), Actinobacteria (2.7–21.51%), Acidobacteria (0.73–16.36%), Bacteroides (1.53–14.11%), and Thermodesulfobacteria (0.1–8.9%), accounting for over 90% of the total microbial community. At the class level, the primary species were γ-proteobacteria, Alphaproteobacteria, Anaerolineae, Bacillus, Bacteroidota, Actinobacteriota, and Clostridia, accounting for over 70% of the total microbial community. Our results provide direct evidence for a link between microbial community structure and environment factors. This evidence demonstrates that sediment microorganisms can be applied to evaluate urban rivers pollution levels, which can provide a scientific basis for pollution control and management in the urban river affected by human activities.

Published

2022

49. Removal of EDTA-Cu(II) from Water Using Synergistic Fenton Reaction-Assisted Adsorption by Nanomanganese Oxide-Modified Biochar: Performance and Mechanistic Analysis

Author

Weiying Feng, Ying Wang, Zhaomin Dong, Shu Liu, Wenhong Fan, Xiaomin Li, and Ying Zhu

Subjects

Fenton reaction, Chemistry, Natural water, Oxide, Metal, chemistry.chemical_compound, Adsorption, Chemical engineering, Chemistry (miscellaneous), visual_art, Biochar, visual_art.visual_art_medium, Environmental Chemistry, Chemical Engineering (miscellaneous), Water Science and Technology

Abstract

Metal complexes exhibit higher stability in water, making metal removal more challenging. In this study, a low-cost, high-efficiency, and multifunctional nanomanganese oxide-modified biochar (BC-Mn...

Published

2021

50. Simulation of water balance and irrigation strategy of typical sand-layered farmland in the Hetao Irrigation District, China

Author

Zhuangzhuang Feng, Qingfeng Miao, Haibin Shi, Weiying Feng, Xianyue Li, Jianwen Yan, Meihan Liu, Wei Sun, Liping Dai, and Jing Liu

Subjects

Soil Science, Agronomy and Crop Science, Earth-Surface Processes, Water Science and Technology

Published

2023