16 results on '"Niazi, Nabeel Khan"'
Search Results
2. The role of various ameliorants on geochemical arsenic distribution and CO2-carbon efflux under paddy soil conditions
- Author
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Hussain, Muhammad Mahroz, primary, Bibi, Irshad, additional, Ali, Fawad, additional, Saqib, Zulfiqar Ahmad, additional, Shahid, Muhammad, additional, Niazi, Nabeel Khan, additional, Hussain, Khalid, additional, Shaheen, Sabry M., additional, Wang, Hailong, additional, Shakil, Qamar, additional, and Rinklebe, Jörg, additional
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- 2022
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3. Sediment quality, elemental bioaccumulation and antimicrobial properties of mangroves of Indian Sundarban
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Bakshi, Madhurima, primary, Ghosh, Somdeep, additional, Ram, S. S., additional, Sudarshan, M., additional, Chakraborty, Anindita, additional, Biswas, Jayanta Kumar, additional, Shaheen, Sabry M., additional, Niazi, Nabeel Khan, additional, Rinklebe, Jörg, additional, and Chaudhuri, Punarbasu, additional
- Published
- 2018
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4. Correction to: Potential toxicity of trace elements and nanomaterials to Chinese cabbage in arsenic- and lead-contaminated soil amended with biochars
- Author
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Awad, Yasser Mahmoud, primary, Vithanage, Meththika, additional, Niazi, Nabeel Khan, additional, Rizwan, Muhammad, additional, Rinklebe, Jörg, additional, Yang, Jae E., additional, Ok, Yong Sik, additional, and Lee, Sang Soo, additional
- Published
- 2017
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5. Potential toxicity of trace elements and nanomaterials to Chinese cabbage in arsenic- and lead-contaminated soil amended with biochars
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Awad, Yasser Mahmoud, primary, Vithanage, Meththika, additional, Niazi, Nabeel Khan, additional, Rizwan, Muhammad, additional, Rinklebe, Jörg, additional, Yang, Jae E., additional, Ok, Yong Sik, additional, and Lee, Sang Soo, additional
- Published
- 2017
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6. Biowaste-based sorbents for arsenic removal from aqueous medium and risk assessment.
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Nagra MA, Natasha N, Bibi I, Tariq TZ, Naz R, Ansar S, Shahid M, Murtaza B, Imran M, Khalid MS, Masood N, Shah GM, Niazi NK, and Dumat C
- Subjects
- Humans, Adsorption, Water, Risk Assessment, Tea, Kinetics, Hydrogen-Ion Concentration, Arsenic analysis, Water Pollutants, Chemical analysis, Water Purification methods
- Abstract
Water contamination by arsenic (As) is widespread and is posing serious health threats globally. Hence, As removal techniques/adsorbents need to be explored to minimize potentials hazards of drinking As-contaminated waters. A column scale sorption experiment was performed to assess the potential of three biosorbents (tea waste, wheat straw and peanut shells) to remove As (50, 100, 200 and 400 µg L
-1 ) from aqueous medium at a pH range of 5-8. The efficiency of agricultural biosorbents to remove As varies greatly regarding their type, initial As concentration in water and solution pH. It was observed that all of the biosorbents efficiently removed As from water samples. The maximum As removal (up to 92%) was observed for 400 µg L-1 initial As concentration. Noticeably, at high initial As concentrations (200 and 400 μg L-1 ), low pH (5 and 6) facilitates As removal. Among the three biosorbents, tea waste biosorbent showed substantial ability to minimize health risks by removing As (up to 92%) compared to peanut shells (89%) and wheat straw (88%). Likewise, the values of evaluated risk parameters (carcinogenic and non-carcinogenic risk) were significantly decreased (7-92%: average 66%) after biosorption experiment. The scanning electron microscopy, Fourier transform infrared spectroscopy, energy-dispersive X-ray and X-ray diffraction analyses confirmed the potential of biosorbents to remediate As via successful loading of As on their surfaces. Hence, it can be concluded that synthesized biosorbents exhibit efficient and ecofriendly potential for As removal from contaminated water to minimize human health risk., (© 2022. The Author(s), under exclusive licence to Springer Nature B.V.)- Published
- 2023
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7. A critical analysis of wastewater use in agriculture and associated health risks in Pakistan.
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Natasha, Shahid M, Khalid S, Murtaza B, Anwar H, Shah AH, Sardar A, Shabbir Z, and Niazi NK
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- Humans, Wastewater, Pakistan, Agricultural Irrigation, Agriculture, Soil chemistry, Risk Assessment, Soil Pollutants analysis, Metals, Heavy analysis
- Abstract
Freshwater shortage and its contamination with various types of pollutants are becoming the most alarming issues worldwide due to impacts on socioeconomic values. Considering an increasing freshwater scarcity, it is imperative for the growers, particularly in semiarid and arid areas, to use wastewater for crop production. Wastewaters generally contain numerous essential inorganic and organic nutrients which are considered necessary for plant metabolism. Besides, this practice provokes various hygienic, ecological and health concerns due to the occurrence of toxic substances such as heavy metals. Pakistan nowadays faces a severe freshwater scarcity. Consequently, untreated wastewater is used routinely in the agriculture sector. In this review, we have highlighted the negative and positive affectivity of wastewater on the chemical characteristics of the soil. This review critically delineates toxic metal accumulation in soil and their possible soil-plant-human transfer. We have also estimated and deliberated possible health hazards linked with the utilization of untreated city waste effluents for the cultivation of food/vegetable crops. Moreover, we carried out a multivariate analysis of data (144 studies of wastewater crop irrigation in Pakistan) to trace out common trends in published data. We have also compared the limit values of toxic metals in irrigation water, soil and plants. Furthermore, some viable solutions and future viewpoints are anticipated taking into account the on-ground situation in Pakistan-such as planning and sanitary matters, remedial/management technologies, awareness among local habitants (especially farmers) and the role of the government, NGOs and pertinent stakeholders. The data are supported by 13 tables and 7 figures., (© 2020. Springer Nature B.V.)
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- 2023
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8. Use of agricultural bio-wastes to remove arsenic from contaminated water.
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Shabbir Z, Shahid M, Natasha, Khalid S, Khalid S, Imran M, Qureshi MI, and Niazi NK
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- Cellulose, Risk Assessment methods, Agriculture, Arsenic analysis, Drinking Water analysis, Water Pollutants, Chemical analysis, Saccharum, Groundwater chemistry
- Abstract
Arsenic (As) is a highly toxic metalloid. High As levels have been recorded in groundwater aquifers at a global scale. This study investigated As level in groundwater of District Vehari and assessed the potential of different agricultural by-products (sugarcane bagasse, cottonseed hulls, soybean hulls, corncobs and rice husk) to remove As from water. The study was carried out in two steps. In the first step, a total of 38 groundwater samples were obtained from Vehari. Groundwater samples were analyzed for total As contents and physicochemical parameters. Results indicated that As content ranged from below detection limit to 49 µg/L in the groundwater samples. The values of hazard quotient and cancer risk were up to 1.5 and 0.0004, respectively, which delineated severe risk of As poisoning. During the second step, six As-contaminated groundwater samples (total As contents: 49, 40, 29, 24, 18, 16 µg/L) were selected to remove As using agricultural by-products. Furthermore, four As solutions (200, 100, 50 and 25 µg/L) were prepared in the laboratory. Results revealed that corncobs and soybean hulls removed, respectively, 98% and 71% As from aqueous mediums after 120 min. Moreover, agricultural by-products were less effective in removing As from groundwater samples than synthetic solutions. The adsorption/removal capacity of by-products was lower at low initial As concentration compared to high initial levels, which needs further studies to explore the underlying mechanisms. Overall, the As removal efficiency of agriculture by-products differed significantly with respect to initial As level, contamination category, type of agricultural by-products and interaction duration. Therefore, these aspects need to be optimized before the possible use of an agricultural by-product as a potential biosorbent., (© 2020. Springer Nature B.V.)
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- 2023
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9. The role of various ameliorants on geochemical arsenic distribution and CO 2 -carbon efflux under paddy soil conditions.
- Author
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Hussain MM, Bibi I, Ali F, Saqib ZA, Shahid M, Niazi NK, Hussain K, Shaheen SM, Wang H, Shakil Q, and Rinklebe J
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- Humans, Soil chemistry, Carbon, Clay chemistry, Cellulose, Carbon Dioxide, Manure, Ecosystem, Biofuels, Charcoal chemistry, Sand, Arsenic, Saccharum
- Abstract
Climate change is a global challenge that is accelerated by contamination with hazardous substances like arsenic (As), posing threat to the agriculture, ecosystem and human health. Here, we explored the impact of various ameliorants on geochemical distribution of As in two soils with contrasting textures (sandy clay loam (Khudpur Village) and clay loam (Mattital Village)) under paddy soil conditions and their influence on the CO
2 -carbon efflux. The exchangeable As pool in clay loam soil increased as: lignite (0.4%) < biogas slurry (6%) < cow dung (9%), and < biochar (20%). However, in the sandy clay loam soil exchangeable soil As pool was found to be maximum with farmyard manure followed by biogas slurry, biochar and cow dung (17%, 14%, 13% and 7%, respectively). Interestingly, in the sandy clay loam soil the percentage As distribution in organic fraction was: biochar (38%) > cow dung (33%) > biogas slurry (23%) > sugarcane bagasse (22%) > farmyard manure (21%) that was higher compared to the clay loam soil (< 6% for all the amendments). In addition to the highest As immobilization by biochar in sandy clay loam soil, it also led to the lowest CO2 -carbon efflux (1470 CO2 -C mg kg-1 ) among all the organic/inorganic amendments. Overall, the current study advances our understanding on the pivotal role of organic amendments, notably biochar, in immobilizing As under paddy soil conditions with low (CO2 ) carbon loss, albeit it is dependent on soil and ameliorant types., (© 2022. The Author(s), under exclusive licence to Springer Nature B.V.)- Published
- 2023
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10. Arsenic-induced oxidative stress in Brassica oleracea: Multivariate and literature data analyses of physiological parameters, applied levels and plant organ type.
- Author
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Natasha, Shahid M, Khalid S, Bibi I, Khalid S, Masood N, Qaisrani SA, Niazi NK, and Dumat C
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- Antioxidants metabolism, Data Analysis, Hydrogen Peroxide, Oxidative Stress, Plant Leaves chemistry, Plant Roots metabolism, Plants metabolism, Arsenic analysis, Arsenic toxicity, Brassica metabolism, Soil Pollutants analysis, Soil Pollutants toxicity, Trace Elements analysis
- Abstract
Plant redox homeostasis governs the uptake, toxicity and tolerance mechanism of toxic trace elements and thereby elucidates the remediation potential of a plant. Moreover, plant toxicity/tolerance mechanisms control the trace element compartmentation in edible and non-edible plant organs as well as the associated health hazards. Therefore, it is imperative to unravel the cellular mechanism involved in trace element toxicity and tolerance. The present study investigated the toxicity and tolerance/detoxification mechanisms of four levels of arsenic (As(III): 0, 5, 25 and 125 µM) in Brassica oleracea under hydroponic cultivation. Increasing As levels significantly decreased the pigment contents (up to 68%) of B. oleracea. Plants under As stress showed an increase in H
2 O2 contents (up to 32%) in roots while a decrease (up to 72%) in leaves because As is mostly retained in plant roots, while less is translocated toward the shoot, as evident from the literature. Arsenic treatments caused lipid peroxidation both in the root and leaf cells. Against As-induced oxidative stress, B. oleracea plants mediated an increase in the activities of peroxidase and catalase. Contradictory, the ascorbate peroxidase and superoxide dismutase activities slightly decreased in the As-stressed plants. In conclusion and as evident from the literature data analysis, As exposure (especially high level, 125 µM) caused pigment toxicity and oxidative burst in B. oleracea. The ability of B. oleracea to tolerate As-induced toxicity greatly varied with applied treatment levels (As-125 being more toxic than lower levels), plant organ type (more toxicity in leaves than roots) and physiological response parameter (pigment contents more sensitive than other response variables). Moreover, the multivariate statistical analysis appeared to be a useful method to estimate plant response under stress and trace significant trends in the data set., (© 2021. The Author(s), under exclusive licence to Springer Nature B.V.)- Published
- 2022
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11. Hydrogeochemical and health risk investigation of potentially toxic elements in groundwater along River Sutlej floodplain in Punjab, Pakistan.
- Author
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Ahmad S, Imran M, Murtaza B, Natasha, Arshad M, Nawaz R, Waheed A, Hammad HM, Naeem MA, Shahid M, and Niazi NK
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- Environmental Monitoring, Humans, Pakistan, Rivers, Arsenic analysis, Arsenic toxicity, Groundwater, Water Pollutants, Chemical analysis, Water Pollutants, Chemical toxicity
- Abstract
Understanding groundwater quality and hydrogeochemical behavior is important because consumption of the potentially toxic elements (PTEs)-contaminated drinking water may induce several health problems for humans and animals. In the current study, we examined the potential groundwater contamination with various PTEs (arsenic, As; cadmium, Cd; copper, Cu; manganese; Mn) and the PTEs-induced health risk. Groundwater (n = 111) was characterized for total As, Cd, Cu, and Mn concentrations and other water quality attributes along the River Sutlej floodplain of Punjab, Pakistan. Results revealed that groundwater, which is used for drinking purpose, contained high concentrations of As and Cd (mean As: 33 µg/L, mean Cd: 3 µg/L), exceeding 100% and 32% than the World Health Organization's safe limits (10 and 3 µg/L, respectively) in drinking water. The other water quality attributes (i.e., EC, HCO
3 , Cl and SO4 ) were also found above their safe limits in most of the wells. Hydrogeochemical data showed that groundwater was dominated with Na-SO4, Na-Cl, Ca/Mg-CO3 type saline water. The hazard quotient and cancer risk indices values calculated for As and Cd indicated potential threat (carcinogenic risk > 0.0001 and non-carcinogenic risk > 1.0) of drinking groundwater in the study area. This study shows that the groundwater along River Sutlej floodplain poses a health threat to the communities relying on it for drinking and irrigation due to high concentrations of As and Cd in water. Moreover, it is important to monitor groundwater quality in the adjacent areas along River Sutlej floodplain and initiate suitable mitigation and remediation programs for the safety of people's health in Punjab, Pakistan., (© 2021. The Author(s), under exclusive licence to Springer Nature B.V.)- Published
- 2021
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12. The potential of microbes and sulfate in reducing arsenic phytoaccumulation by maize (Zea mays L.) plants.
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Natasha, Bibi I, Hussain K, Amen R, Hasan IMU, Shahid M, Bashir S, Niazi NK, Mehmood T, Asghar HN, Nawaz MF, Hussain MM, and Ali W
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- Plant Roots chemistry, Soil, Sulfates, Zea mays, Arsenic, Soil Pollutants analysis
- Abstract
Arsenic (As) contamination in soil-plant system is an important environmental, agricultural and health issue globally. The microbe- and sulfate-mediated As cycling in soil-plant system may depend on soil sulfate levels, and it can be used as a potential strategy to reduce plant As uptake and improve plant growth. Here, we investigated the role of soil microbes (SMs) to examine As phytoaccumulation using maize as a test plant, under varying sulfate levels (S-0, S-5, S-25 mmol kg
-1 ) and As stress. The addition of sulfate and SMs promoted maize plant growth and reduced As concentration in shoots compared to sulfate-treated plants without SMs. Results revealed that the SMs-S-5 treatment proved to be the most promising in reducing As uptake by 27% and 48% in root and shoot of the maize plants, respectively. The SMs-S treatments, primarily with S-5, enhanced plant growth, shoot dry biomass, Chl a, b and total Chl (a + b) contents, and gas exchange attributes of maize plants. Similarly, the antioxidant defense in maize plants was increased significantly in SMs-S-treated plants, notably with SMs-S-5 treatment. Overall, the SMs-S-5-treated plants possessed improved plant growth, dry biomass, physiology and antioxidant defense system and decrease in plant shoot As concentration. The outcomes of this study suggest that sulfate supplementation in soil along with SMs could assist in reducing As accumulation by maize plants, thus providing a sustainable and eco-friendly bioremediation strategy in limiting As exposure., (© 2021. The Author(s), under exclusive licence to Springer Nature B.V.)- Published
- 2021
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13. Assessment of arsenic exposure by drinking well water and associated carcinogenic risk in peri-urban areas of Vehari, Pakistan.
- Author
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Shah AH, Shahid M, Khalid S, Natasha, Shabbir Z, Bakhat HF, Murtaza B, Farooq A, Akram M, Shah GM, Nasim W, and Niazi NK
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- Arsenic toxicity, Carcinogens analysis, Carcinogens toxicity, Dietary Exposure adverse effects, Drinking Water analysis, Environmental Monitoring, Groundwater chemistry, Humans, Hydrogen-Ion Concentration, Pakistan, Risk Assessment, Temperature, Water Pollutants, Chemical toxicity, Water Wells, Arsenic analysis, Dietary Exposure analysis, Groundwater analysis, Water Pollutants, Chemical analysis
- Abstract
Arsenic (As) is a highly toxic and carcinogenic element. It has received considerable consideration worldwide in recent years due to its highest toxicity to human, and currently, high concentrations observed in the groundwater. Some recent media and research reports also highlighted possible As contamination of groundwater systems in Pakistan. However, there is a scarcity of data about As contents in groundwater in different areas/regions of the country. Consequently, the current study estimated the As concentration in the groundwater used for drinking purpose in 15 peri-urban sites of district Vehari, Pakistan. In total, 127 groundwater samples were collected and examined for As contents in addition to physicochemical characteristics such as temperature, electrical conductivity, pH, total soluble salts, chloride, carbonates, bicarbonates, sodium, potassium, lithium, calcium and barium. Results indicated that the groundwater samples were not fully fit for drinking purposes with several parameters, especially the alarming levels of As (mean As: 46.9 µg/L). It was found that 83% groundwater samples of peri-urban sites in district Vehari have As concentration greater than WHO lower permissible limit (10 µg/L). The risk assessment parameters (mean hazard quotient: 3.9 and mean cancer risk: 0.0018) also showed possible carcinogenic and non-carcinogenic risks associated with ingestion of As-contaminated groundwater at peri-urban sites. Based on the findings, it is anticipated that special monitoring and management of groundwater is necessary in the studied area in order to curtail the health risks associated with the use of As-contaminated drinking water. Moreover, appropriate remediation and removal of As from groundwater is also imperative for the study area before being used for drinking purpose to avoid As exposure and related risks to the local community.
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- 2020
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14. Correction to: Potential toxicity of trace elements and nanomaterials to Chinese cabbage in arsenic- and lead-contaminated soil amended with biochars.
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Awad YM, Vithanage M, Niazi NK, Rizwan M, Rinklebe J, Yang JE, Ok YS, and Lee SS
- Abstract
Unfortunately, in the original publication of the article, Prof. Yong Sik Ok's affiliation was incorrectly published. The author's affiliation is as follows.
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- 2019
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15. Potential toxicity of trace elements and nanomaterials to Chinese cabbage in arsenic- and lead-contaminated soil amended with biochars.
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Awad YM, Vithanage M, Niazi NK, Rizwan M, Rinklebe J, Yang JE, Ok YS, and Lee SS
- Subjects
- Arsenic analysis, Arsenic toxicity, Biological Availability, Brassica growth & development, Environmental Restoration and Remediation methods, Germination drug effects, Hydrogen-Ion Concentration, Lead analysis, Lead toxicity, Metals, Heavy analysis, Nanostructures analysis, Nanotubes, Carbon analysis, Oryza chemistry, Plant Roots drug effects, Plant Roots growth & development, Sewage, Soil chemistry, Soil Pollutants analysis, Soil Pollutants toxicity, Trace Elements analysis, Arsenic pharmacokinetics, Brassica drug effects, Charcoal chemistry, Lead pharmacokinetics, Nanostructures toxicity, Soil Pollutants pharmacokinetics
- Abstract
To our knowledge, this is the first report on exploring the interactive effects of various biochars (BCs) and nanomaterials (NMs) on plant growth and bioavailability of trace elements in soil. This study evaluated the bioavailability and toxicity of arsenic (As), lead (Pb), and NMs to cabbage plants. The BCs were produced from rice husk (RB), sewage sludge, and bamboo wood (WB). The BCs at 2.5 and 5% (w w
-1 ), NMs for removing As (NMs-As) and heavy metals (NMs-HM) at 3000 mg kg-1 , and multi-walled carbon nanotubes (CNT) at 1000 mg kg-1 were applied in bioassay and incubation experiments (40 days), along with the unamended soil as the control. Results showed that the NMs-As and NMs-HM decreased seed germination at 3 days after sowing; however, their toxicity was eliminated by BCs. Growth parameters of cabbage revealed that the CNT was the most toxic NMs, as it was translocated in root and leaf cells, which was confirmed by transmission electron microscopic images. Bioavailable Pb was reduced by 1.2-3.8-folds in all amended rhizosphere and bulk soils. Amendments of 2.5% WB + NMs-As and 2.5% RB + NMs-As significantly decreased both bioavailable As and Pb.- Published
- 2019
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16. Sediment quality, elemental bioaccumulation and antimicrobial properties of mangroves of Indian Sundarban.
- Author
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Bakshi M, Ghosh S, Ram SS, Sudarshan M, Chakraborty A, Biswas JK, Shaheen SM, Niazi NK, Rinklebe J, and Chaudhuri P
- Subjects
- Acanthaceae metabolism, Ecosystem, India, Metals, Heavy metabolism, Plant Leaves chemistry, Plant Leaves metabolism, Risk Assessment, Water Pollutants, Chemical metabolism, Acanthaceae chemistry, Anti-Infective Agents analysis, Environmental Monitoring, Geologic Sediments chemistry, Metals, Heavy analysis, Water Pollutants, Chemical analysis
- Abstract
Mangroves have wide applications in traditional medicines due to their several therapeutic properties. Potentially toxic elements (PTEs), in mangrove habitats, need serious concern because of their toxicity, bioaccumulation capacity and ecotoxicological risks. In the current study, we aimed to examine sediment quality and bioaccumulation of PTEs in a mangrove-dominated habitat of Sundarban, India, and their relation with antimicrobial property of ten mangrove species of the region. Antimicrobial activity of different solvent fractions of mangrove leaves was assessed against seven microorganisms. The highest antimicrobial activity was detected in ethyl acetate and acetone-extracted fractions of Avicennia alba. Various sediment quality indices revealed progressively deteriorating nature of surface sediment having moderate contamination, however, low ecotoxicological risk. The accumulation factors (AF) for different PTEs indicate a gradual metal bioaccumulation in leaf tissue. Antimicrobial activities indicated both positive and negative correlations with manganese (Mn), copper (Cu), iron (Fe) and zinc (Zn) concentrations of mangrove species. Concentration of Mn showed a significant correlation with almost all the fractions, whereas Cu had correlation with ethyl acetate, acetone and methanol fractions (P < 0.05). The AF of Mn and Cu exhibited correlation with antimicrobial activities of acetone and methanol fractions, whereas Fe and Zn had correlation with hexane and ethyl acetate fractions. Overall, Mn, Fe, Cu and Zn concentrations of Acanthus ilicifolius and Avicennia alba leaves and in the surface sediments demonstrated the strongest association (P < 0.05) with their antimicrobial activity as also depicted in correlation and cluster analysis studies. Thus, this study will help to establish a link between the PTEs in mangrove ecosystem with their bioactivity.
- Published
- 2019
- Full Text
- View/download PDF
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