ABSTRACT
The basic aim of this study was aimed to determine the ichthyofaunal diversity of River Panjkora in both upper and lower Dir districts in Khyber Pakhtunkhwa province of Pakistan.Fish samples were collected by using fishnets from March to September 2020. A total of 724 specimens were collected and classified into 5 families, 14 genera, and 18 species. The overall results revealed that most fish fauna of river Panjkora contains 8 species of family Cyprinidae (56.49%) followed by 4 species of Nemacheilidae (24.44%), 2 species of Channidae (10.63%), and Sisoridae (7.04%), and 1 species of Mastacembelidae (1.38%), respectively. Among all kinds of fish species, Schizothorax plagiostomus (16.57%) was highly dominated and followed by Carassius auratus (11.87%) and Racoma labiata (9.66%) and were reported as highly abundant, especially during April, May, and June. The least abundant species were Glyptothorax punjabensis, Glyptothorax sufii, and Mastacembelus armatus, that constituting 2.48%, 2.20%, and 1.38% of the total fish samples. The Overall Simpson's diversity (1-D= 0.919) and Simpson's Reciprocal index values (1/D= 12.3876), and Shannon's index (H= 2.68) were indicating that river Panjkora contains a quite rich and diverse group of fish species. The highest microplastics observed in site 7 compared to other study area. Conservation steps should be taken as a top priority to protect and conserve the marine environment and natural heritage from further loss, extinction and stop or minimize losses incurred through irresponsible fishery practices
O objetivo básico deste estudo foi determinar a diversidade ictiofaunística do rio Panjkora nos distritos de Lower e Upper de Dir, na província de Khyber Pakhtunkhwa, no Paquistão. Amostras de peixes foram coletadas com redes de arrasto de março a setembro de 2020. Foram coletados 724 espécimes, classificados em 5 famílias, 14 gêneros e 18 espécies. Os resultados gerais revelaram que a maioria da ictiofauna do rio Panjkora contém 8 espécies da família Cyprinidae (56,49%), seguidas por 4 espécies de Nemacheilidae (24,44%), 2 espécies de Channidae (10,63%) e Sisoridae (7,04%) e 1 espécie de Mastacembelidae (1,38%). Entre todas as espécies de peixes, Schizothorax plagiostomus (16,57%) foi altamente predominante, seguida por Carassius auratus (11,87%) e Racoma labiata (9,66%), e elas foram relatadas como altamente abundantes, especialmente nos meses de abril, maio e junho. As espécies menos abundantes foram Glyptothorax punjabensis, Glyptothorax sufii e Mastacembelus armatus, que constituíram 2,48%, 2,20% e 1,38%, respectivamente, do total de peixes amostrados. O índice de diversidade de Simpson (1-D = 0,919), o índice recíproco de Simpson (1/D = 12,3876) e o índice de Shannon (H = 2,68) indicaram que o rio Panjkora contém um grupo bastante rico e diversificado de espécies de peixes. Os microplásticos mais altos foram observados no local 7 em comparação com outra área de estudo. Medidas de conservação devem ser tomadas como prioridade máxima para proteger e conservar o ambiente marinho e o patrimônio natural de novas perdas e extinção e para parar ou minimizar as perdas ocorridas por práticas de pesca irresponsáveis.
Subject(s)
Animals , Biodiversity , Rivers , Environmental Pollution , Fishes , Microplastics , PakistanABSTRACT
To investigate the formation of polystyrene nanoplastic-plant protein corona and its potential impact on plants, three differently modified polystyrene nanoplastics with an average particle size of 200 nm were taken to interact with the leaf proteins of Impatiens hawkeri for 2 h, 4 h, 8 h, 16 h, 24 h, and 36 h, respectively. The morphological changes were observed by scanning electron microscopy (SEM), the surface roughness was determined by atomic force microscopy (AFM), the hydrated particle size and zeta potential were determined by nanoparticle size and zeta potential analyzer, and the protein composition of the protein corona was identified by liquid chromatography-tandem mass spectrometry (LC-MS/MS). The proteins were classified in terms of biological processes, cellular components, and molecular functions to study the adsorption selection of nanoplastics to proteins, investigate the formation and characteristics of polystyrene nanoplastic-plant protein corona and predict the potential impact of protein corona on plants. The results showed that the morphological changes of the nanoplastics became clearer as the reaction time extends, as evidenced by the increase in size and roughness and the enhancement of stability, thus demonstrating the formation of protein corona. In addition, the transformation rate from soft to hard protein corona was basically the same for the three polystyrene nanoplastics in the formation of protein corona with leaf proteins under the same protein concentration conditions. Moreover, in the reaction with leaf proteins, the selective adsorption of the three nanoplastics to proteins with different isoelectric points and molecular weights differed, and the particle size and stability of the final formed protein corona also differed. Since a large portion of the protein fraction in protein corona is involved in photosynthesis, it is hypothesized that the formation of the protein corona may affect photosynthesis in I. hawkeri.
Subject(s)
Polystyrenes/chemistry , Protein Corona/chemistry , Microplastics , Plant Proteins , Chromatography, Liquid , Tandem Mass Spectrometry , Nanoparticles/chemistryABSTRACT
As a widespread pollutant in the environment, research on microplastics have attracted much attention. This review systematically analyzed the interaction between microplastics and soil microorganisms based on existing literatures. Microplastics can change the structure and diversity of soil microbial communities directly or indirectly. The magnitude of these effects depends on the type, dose and shape of microplastics. Meanwhile, soil microorganisms can adapt to the changes caused by microplastics through forming surface biofilm and selecting population. This review also summarized the biodegradation mechanism of microplastics, and explored the factors affecting this process. Microorganisms will firstly colonize the surface of microplastics, and then secrete a variety of extracellular enzymes to function at specific sites, converting polymers into lower polymers or monomers. Finally, the depolymerized small molecules enter the cell for further catabolism. The factors affecting this degradation process are not only the physical and chemical properties of the microplastics, such as molecular weight, density and crystallinity, but also some biological and abiotic factors that affect the growth and metabolism of related microorganisms and the enzymatic activities. Future studies should focus on the connection with the actual environment, and develop new technologies of microplastics biodegradation to solve the problem of microplastic pollution.
Subject(s)
Microplastics , Plastics , Soil , Polymers , Biodegradation, EnvironmentalABSTRACT
Microplastics pollution has attracted worldwide attention. Compared with the status quo of microplastics pollution in marine environment and other major rivers and lakes, the relevant data of the Yellow River basin is relatively inadequate. The abundance, types, and spatial distribution characteristics of microplastic pollution in the sediments and surface water of the Yellow River basin were reviewed. Meanwhile, the status of microplastic pollution in the national central city and Yellow River Delta wetland was discussed, and the corresponding prevention and control measures were put forward. The results showed that the spatial distribution of microplastics pollution in sediments and surface water of the Yellow River basin increased from upstream to downstream, especially in the Yellow River Delta wetland. There are obvious differences between the types of microplastics in sediment and surface water in the Yellow River basin, which is mainly related to the materials of microplastics. Compared with similar regions in China, the microplastics pollution levels in national key cities and national wetland parks in the Yellow River basin are in the medium to high degree, which should be taken seriously. Plastics exposure through various ways will cause serious impact on aquaculture and human health in the Yellow River beach area. To control microplastic pollution in the Yellow River basin, it is necessary to improve the relevant production standards, laws and regulations, and improve the capacity of biodegradable microplastics and the degradation capacity of plastic wastes.
Subject(s)
Humans , Microplastics , Plastics , Water Pollutants, Chemical/analysis , Environmental Monitoring/methods , Water , ChinaABSTRACT
Environmental concerns are increasing in and around us due to improper discharge of personal protective gear or equipment (PPEs) during the current pandemic with SARS-CoV-2.The residents of Salalah, under the Dhofar governorate of Oman,were hastening to take every possible measure to safeguard their health against the COVID-19 pandemic. In this scenario, improper discard of facemasks in the environment entails a significant problem forpublic health and aquatic environments. Objective:This study aimsto assess how the SARS-CoV-2 virus disrupted the household waste management chainin the Sultanate of Oman. In addition, descriptivesurvey has also identified people's perception about the existing household waste management system. Methods:Total 200 respondents were personally selected under the purposive sampling category. Data were analyzed using SPSS version 26. The mean, standard deviation, and distribution shapewere calculated based on the retrieved data. The variables and frequencies were tabulated for categorical variables. Results show negative impacts on the environment, wildlife, and public health. It was also observed that there was a significant difference when grouped according to residence location since the obtainedalso observed a significant difference when grouped according to residence location since thep-value of 0.007 was less than 0.05 alpha level. This means that the responses differ significantly. It shows from the test conducted that participantsfrom the village experienced and observed a negative impact on the discarded face masks comparedto those in the city.Conclusion and recommendation: This study illustrates the real impact of the COVID-19 facemasks on the environment, wildlife, and public health. In addition, the new management of the user's facemasks for eliminating or reducing the risks to human health and the environmenthas been suggested. [Ethiop. J. Health Dev. 2022; 36(2):000-000]
Subject(s)
Environmental Health , Data Interpretation, Statistical , Microplastics , COVID-19 , Health Care Surveys , N95 Respirators , SARS-CoV-2ABSTRACT
Background:Environmental concerns are increasing in and around us due to improper discharge of personal protective gear or equipment (PPEs) during the current pandemic with SARS-CoV-2.The residents of Salalah, under the Dhofar governorate of Oman,were hastening to take every possible measure to safeguard their health against the COVID-19 pandemic. In this scenario, improper discard of facemasks in the environment entails a significant problem forpublic health and aquatic environments. Objective:This study aimsto assess how the SARS-CoV-2 virus disrupted the household waste management chainin the Sultanate of Oman. In addition, descriptivesurvey has also identified people's perception about the existing household waste management system. Methods:Total 200 respondents were personally selected under the purposive sampling category. Data were analyzed using SPSS version 26. The mean, standard deviation, and distribution shapewere calculated based on the retrieved data. The variables and frequencies were tabulated for categorical variables. Results show negative impacts on the environment, wildlife, and public health. It was also observed that there was a significant difference when grouped according to residence location since the obtainedalso observed a significant difference when grouped according to residence location since thep-value of 0.007 was less than 0.05 alpha level. This means that the responses differ significantly. It shows from the test conducted that participantsfrom the village experienced and observed a negative impact on the discarded face masks comparedto those in the city.Conclusion and recommendation: This study illustrates the real impact of the COVID-19 facemasks on the environment, wildlife, and public health. In addition, the new management of the user's facemasks for eliminating or reducing the risks to human health and the environmenthas been suggested. [Ethiop. J. Health Dev. 2022; 36(2):000-000
Subject(s)
Humans , Male , Female , Environmental Health , SARS-CoV-2 , Surveys and Questionnaires , Directories as Topic , Microplastics , N95 RespiratorsABSTRACT
Resumen Introducción: La presencia de microplásticos (MPs, partículas menores a 5 mm) y el incremento de la temperatura en los océanos, vienen generando perturbaciones en la vida marina, que se pueden relacionar con alteraciones en el metabolismo de organismos filtradores, como los mitílidos. Objetivo: Se evalúa el efecto de diferentes temperaturas y concentraciones de MPs sobre la tasa de filtración (TF) de Semimytilus algosus. Métodos: Una muestra de organismos (N = 72) fue expuesta a cuatro temperaturas (17, 20, 23 y 26 °C), y un testigo sin microplásticos (MPs0) y dos concentraciones de MPs (< 125 µm) de 0.125 mg/l (MPs1) y 0.250 mg/l (MPs2), todos en combinación con la microalga Isochrysis galbana (1x106 cel/ml/día) por 21 días. Resultados: A medida que aumentó la concentración de MPs, se redujo la TF de S. algosus. Respecto a la temperatura, durante el día 7 se observó una mayor TF a 23 °C en todos los tratamientos, y para los días 14 y 21 se obtuvieron los menores valores de TF a 23 y 26 °C. La acción conjunta del incremento de temperatura y MPs, afectó negativamente la TF de S. algosus, donde ambos factores ocasionaron el descenso de la TF para todos los tiempos de evaluación. No se registró mortalidad a 17 °C para ningún tratamiento, y en el caso de mitílidos expuestos a MPs1 y temperaturas de 20 y 26 °C se presentó la mayor mortalidad (67 %). Conclusiones: El estudio demuestra el efecto adverso del incremento de temperatura y MPs sobre la TF de S. algosus.
Abstract Introduction: The presence of microplastics (MPs, particles smaller than 5 mm) and the increase in temperature in the oceans, have been generating disturbances in marine life, which can be related to alterations in the metabolism of filter-feeders, such as Mythilids. Objective: The effect of different temperatures and concentrations of MPs on the filtration rate (TF) of Semimytilus algosus is evaluated. Methods: A sample of organisms (N = 72) was exposed to four temperatures (17, 20, 23 and 26 °C), and a control without microplastics (MPs0) and two concentrations of MPs (< 125 µm) of 0.125 mg/l (MPs1) and 0.250 mg/l (MPs2), all in combination with Isochrysis galbana microalgae (1x106 cells/ml/day) for 21 days. Results: As the concentration of MPs increased, the TF of S. algosus decreased. Regarding temperature, during day 7 a higher TF was observed at 23 °C in all treatments, and during days 14 and 21 the lowest TF values were obtained at 23 and 26 °C. The joint action of the increase in temperature and MPs, negatively affected the TF of S. algosus, where both factors caused the decrease in TF for all evaluation times. No mortality was recorded at 17 °C for any treatment, and in the case of mytylids exposed to MPs1 at 20 °C and 26 °C, the highest mortality (67 %) occurred. Conclusions: The study demonstrates the adverse effect of the increase in temperature and MPs on the TF of S. algosus.
Subject(s)
Animals , Bivalvia , Microplastics , Global Warming , Filtration/methodsABSTRACT
El uso de mascarillas por parte de la población general como elemento de protección personal frente al COVID-19 se mantuvo en ascenso durante la primera mitad del 2020, en medio de constantes actualizaciones de la OMS acerca del público objetivo, su correcto uso y posibles beneficios, pero donde no se definieron protocolos para el manejo del desecho resultante. Durante el segundo semestre del 2020 la población mundial usaba diariamente 4.300 millones de mascarillas, de las cuales el 78,5% se descartaban de forma incorrecta, llegando a generar un volumen de 2,61 (2,26-2,94; IC=95%) millones de toneladas de desecho diseminadas en el medio ambiente. Los componentes plásticos incorporados en la fabricación de mascarillas como PP, PE y PET pueden tardar 400 años en degradarse en condiciones ambientales, fragmentándose paulatinamente en microplásticos, que afectan a la flora, fauna, agua y suelos de su entorno. Adicionalmente, algunos aditivos sintéticos antioxidantes (AO) usados en la fabricación de plásticos pueden retardar aún más las reacciones de degradación de las mascarillas descartadas hacia el ambiente, aumentando su daño potencial. Se calculó que 216,9 (188,5-245,3; IC=95%) toneladas de AO168, 190 (165,2-214,9; IC=96%) toneladas de AO168O y 442,7 (384,8-500,6; IC=95%) toneladas de AO1010 fueron expuestas al medio ambiente debido a la disposición incorrecta de mascarillas en la segunda mitad de 2020. Aunque la masa conjunta de estos componentes sintéticos sólo representa el 0,017% de las mascarillas desechadas en el mismo lapso, su concentración resulta suficiente para acrecentar el riesgo de daño al ambiente(AU)
The use of masks by the general population as an element of personal protection against COVID-19 continued to rise during the first half of 2020, amid constant updates from the WHO about the target audience, their correct use and possible benefits, but where no protocols were defined for the management of the resulting waste. During the second half of 2020, the world population used 4.3 billion masks daily, of which 78.5% were discarded incorrectly, generating a volume of 2.61 (2.26-2.94; IC = 95%) million tons of waste disseminated in the environment. The plastic components incorporated in the manufacture of masks such as PP, PE and PET can take 400 years to degrade under environmental conditions, gradually fragmenting into microplastics, which affect the flora, fauna, water and soils of their environment. Additionally, some synthetic antioxidant additives (OA) used in the manufacture of plastics can further delay the degradation reactions of discarded masks into the environment, increasing their potential damage. It was calculated that 216.9 (188.5-245.3; IC = 95%) tons of AO168, 190 (165.2-214.9; IC = 96%) tons of AO168O and 442.7 (384.8 -500.6; IC = 95%) tons of AO1010 were exposed to the environment due to the incorrect disposal of masks in the second half of 2020. Although the combined mass of these synthetic components only represents 0.017% of the masks discarded in the same period, its concentration is sufficient to increase the risk of damage to the environment(AU)
Subject(s)
Humans , Disposable Equipment , Environmental Pollution , Personal Protective Equipment , COVID-19/prevention & control , Masks , Waste Products , Environmental Health , Microplastics/toxicityABSTRACT
La contaminación por microplásticos (MPs) de tamaño menor a 5 mm ha tomado relevancia en los últimos años debido a su impacto en los ecosistemas. En Guatemala, se carece de información relacionada con MPs, por lo que este estudio tuvo como objetivo evaluar la abundancia y características de MPs en cuatro playas del Pacífico de Guatemala, Ocós, Tulate, Sipacate y Las Lisas. Se colectaron muestras de arena en mayo y octubre de 2019. Los MPs se aislaron y se clasificaron por forma, y el tipo de polímero se identificó a través de un equipo de espectroscopia infrarroja con transformada de Fourier (ATR-FTIR). La abundancia expresada en MPs/m2 en mayo fue de 25.6, 5.6, 0.8 y 0 MPs/m2 para Tulate, Las Lisas, Ocós y Sipacate; mientras que en octubre fue de 59.6, 23.2, 17.6 y 17.6 MPs/m2 en Tulate, Ocós, Las Lisas y Sipacate. Fragmentos, foam, pellets y láminas fueron las formas predominantes de MPs que se encontraron en las playas. El análisis por ATR-FTIR muestra que los principales polímeros identificados en las playas son polietileno, poliestireno y polipropileno. Los resultados de este estudio indican que las playas del Pacífico de Guatemala están contaminadas por MPs de diferentes tipos de polímeros. Además, estos resultados ofrecen información importante a los responsables de la toma de decisiones sobre la eliminación y el manejo de la basura plástica marina.
Microplastics < 5 mm (MPs) pollution has gained relevance in the last years because of its impact on the ecosystems. In Guatemala, information related to MPS as an environmental stressor is lacking, that is why this study aimed to assess the abundance and characteristics of MPS in four beaches to the Pacific Ocean of Guatemala, Ocós, Tulate, Sipacate, and Las Lisas. Sand samples were collected in May and October 2019. MPs were isolated and classified by shape and the type of polymer was identified by using Attenuated Total Reflec-tion-Fourier Transform Infrared Spectroscopy (ATR-FTIR). The abundance expressed in MPs/m2 in May was 25.6, 5.6, 0.8 and 0 MPs/m2 in Tulate, Las Lisas, Ocós, and Sipacate; whereas in October was 59.6, 23.2, 17.6, and 17.6 M Ps /m2 in Tulate, Las Lisas, Ocós and Sipacate. Fragments, foam, pellets, and film were the predominant shapes found on the beaches. The ATR-FTIR analysis indicates that the main polymers identified in the beaches are polyethylene, polystyrene, and polypropylene. The results of this study indicate that the Pacific Beaches of Guatemala are contaminated by MPs of different types of polymers. These results offer important information to decision makers about disposal and management of marine plastic litter.
Subject(s)
Bathing Beaches , Environmental Pollution/analysis , Microplastics/analysis , Polypropylenes/analysis , Polystyrenes/analysis , Pacific Ocean , Polyethylene/analysis , Microplastics/adverse effects , GuatemalaABSTRACT
Plastics are extensively used in our daily life. However, a significant amount of plastic waste is discharged to the environment directly or via improper reuse or recycling. Degradation of plastic waste generates micro- or nano-sized plastic particles that are defined as micro- or nanoplastics (MNPs). Microplastics (MPs) are plastic particles with a diameter less than 5 mm, while nanoplastics (NPs) range in diameter from 1 to 100 or 1000 nm. In the current review, we first briefly summarized the environmental contamination of MNPs and then discussed their health impacts based on existing MNP research. Our review indicates that MNPs can be detected in both marine and terrestrial ecosystems worldwide and be ingested and accumulated by animals along the food chain. Evidence has suggested the harmful health impacts of MNPs on marine and freshwater animals. Recent studies found MPs in human stool samples, suggesting that humans are exposed to MPs through food and/or drinking water. However, the effect of MNPs on human health is scarcely researched. In addition to the MNPs themselves, these tiny plastic particles can release plastic additives and/or adsorb other environmental chemicals, many of which have been shown to exhibit endocrine disrupting and other toxic effects. In summary, we conclude that more studies are necessary to provide a comprehensive understanding of MNP pollution hazards and also provide a basis for the subsequent pollution management and control.