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Author: Mallory Arden Lushenko Publisher: ISBN: Category : Languages : en Pages : 199
Book Description
Contamination of fish by heavy metals, chlorinated pesticides, and polychlorinated biphenyls (PCBs) can compromise the health of recreational and subsistence anglers consuming the fish they catch. This investigation quantified chemical contaminants in fish muscle and liver tissue samples and followed methods of the U.S. Environmental Protection Agency (EPA) to estimate the hazard indexes and cancer risks associated with consuming fish caught in the waters off the Imperial Beach Pier in Imperial Beach, California. Similar risk assessment studies have been performed for other areas of Southern California but no such investigations have been undertaken for Imperial Beach. All fish samples were donated by Imperial Beach Pier anglers participating in a fishing derby on August 30, 2008. A total of 8 fish samples (3 jacksmelt, 3 mackerel, 1 yellowfin croaker, 1 white croaker) were collected and frozen until they were transported to CRG Marine Laboratories, Inc. for analysis of chemical contaminants. Different instrumentation, per the U.S. EPA methodologies, was used for the specific analytes. A mean ingestion value of 31.2 g/day and a subsistence ingestion value of 142.2 g/day were used along with the mean and maximum concentrations, respectively, to estimate the risk values for each chemical contaminant in muscle tissue. The level of exposure resulting from the consumption of each chemical in the fish tissue was estimated in an average daily dose equation. For noncarcinogenic chemicals, the average daily dose was divided by the oral reference dose, as specified by the U.S. EPA, for each chemical to estimate the hazard index. Estimation of risk for carcinogenic chemicals was calculated by multiplying the average daily dose by the cancer potency factor, also designated by the U.S. EPA. Hazard indexes were calculated for organic arsenic, cadmium, chromium (VI), methylmercury, nickel, selenium, and zinc while cancer risk calculations were done for total chlordane, total DDT, individual PCB congeners detected, and total PCBs. All noncarcinogenic chemicals yielded hazard index (HI) values below 1.0, with the exception of mean and subsistence level ingestion of organic arsenic, with HI values of 1.031 and 8.103, respectively, and subsistence level ingestion of methylmercury, which had a HI of 1.424. Cancer risk calculations exceeding the U.S. EPA's acceptable risk level of 1 in 1,000,000 (or 10-6) included total chlordane at the subsistence level ingestion (1.780 x 10-6), total DDT at the mean ingestion level (7.184 x 10-6), and each PCB congener at the subsistence ingestion level (2.034 x 10-6). Inorganic arsenic at mean and subsistence ingestion levels (5.154 x 10-5 and 4.053 x 10-4, respectively), total DDT at the subsistence ingestion level (7.538 x 10-5), and total PCBs at mean and subsistence ingestion levels (1.159 x 10-5 and 5.290 x 10-5, respectively) all exceeded the U.S. EPA acceptable cancer risk as well as the California EPA's less stringent acceptable risk level of 1 in 100,000 (or 10-5). Regarding the risks of fish liver tissue consumption, the mean mass of the livers collected was 2.48 g and an assumption was made that 3 fish livers of this mass were consumed per week, yielding a mean daily intake value of 1.06 g/day. The presence of metals was not analyzed in liver tissue samples, thus only cancer risk calculations for detected chlorinated pesticides and PCB congeners were performed using the arithmetic mean chemical concentration found in the samples. Of all carcinogenic chemicals detected in the liver samples, only the total PCBs concentration yielded a cancer risk exceeding the U.S. EPA acceptable risk level, with a risk value of 2.804 x 10-6. Some of the chemicals studied, such as arsenic and mercury, occur naturally in the environment and present a "natural" risk because of their behavior in the marine environment. Due to their ban in the U.S. and decreased use in Mexico, the concentrations of the "legacy" pollutants, such as DDT andPCBs, should continue to decline to within de minimus levels over the next decade or two. The results of this study have shown that some of the chemicals analyzed exert a marginal level of unacceptable risk at present, particularly when consumed at subsistence levels; thus, it is important that continued research be conducted to better establish fish consumption data and to aid in the creation of accurate fish consumption guidelines for anglers on the Imperial Beach Pier.
Author: Mallory Arden Lushenko Publisher: ISBN: Category : Languages : en Pages : 199
Book Description
Contamination of fish by heavy metals, chlorinated pesticides, and polychlorinated biphenyls (PCBs) can compromise the health of recreational and subsistence anglers consuming the fish they catch. This investigation quantified chemical contaminants in fish muscle and liver tissue samples and followed methods of the U.S. Environmental Protection Agency (EPA) to estimate the hazard indexes and cancer risks associated with consuming fish caught in the waters off the Imperial Beach Pier in Imperial Beach, California. Similar risk assessment studies have been performed for other areas of Southern California but no such investigations have been undertaken for Imperial Beach. All fish samples were donated by Imperial Beach Pier anglers participating in a fishing derby on August 30, 2008. A total of 8 fish samples (3 jacksmelt, 3 mackerel, 1 yellowfin croaker, 1 white croaker) were collected and frozen until they were transported to CRG Marine Laboratories, Inc. for analysis of chemical contaminants. Different instrumentation, per the U.S. EPA methodologies, was used for the specific analytes. A mean ingestion value of 31.2 g/day and a subsistence ingestion value of 142.2 g/day were used along with the mean and maximum concentrations, respectively, to estimate the risk values for each chemical contaminant in muscle tissue. The level of exposure resulting from the consumption of each chemical in the fish tissue was estimated in an average daily dose equation. For noncarcinogenic chemicals, the average daily dose was divided by the oral reference dose, as specified by the U.S. EPA, for each chemical to estimate the hazard index. Estimation of risk for carcinogenic chemicals was calculated by multiplying the average daily dose by the cancer potency factor, also designated by the U.S. EPA. Hazard indexes were calculated for organic arsenic, cadmium, chromium (VI), methylmercury, nickel, selenium, and zinc while cancer risk calculations were done for total chlordane, total DDT, individual PCB congeners detected, and total PCBs. All noncarcinogenic chemicals yielded hazard index (HI) values below 1.0, with the exception of mean and subsistence level ingestion of organic arsenic, with HI values of 1.031 and 8.103, respectively, and subsistence level ingestion of methylmercury, which had a HI of 1.424. Cancer risk calculations exceeding the U.S. EPA's acceptable risk level of 1 in 1,000,000 (or 10-6) included total chlordane at the subsistence level ingestion (1.780 x 10-6), total DDT at the mean ingestion level (7.184 x 10-6), and each PCB congener at the subsistence ingestion level (2.034 x 10-6). Inorganic arsenic at mean and subsistence ingestion levels (5.154 x 10-5 and 4.053 x 10-4, respectively), total DDT at the subsistence ingestion level (7.538 x 10-5), and total PCBs at mean and subsistence ingestion levels (1.159 x 10-5 and 5.290 x 10-5, respectively) all exceeded the U.S. EPA acceptable cancer risk as well as the California EPA's less stringent acceptable risk level of 1 in 100,000 (or 10-5). Regarding the risks of fish liver tissue consumption, the mean mass of the livers collected was 2.48 g and an assumption was made that 3 fish livers of this mass were consumed per week, yielding a mean daily intake value of 1.06 g/day. The presence of metals was not analyzed in liver tissue samples, thus only cancer risk calculations for detected chlorinated pesticides and PCB congeners were performed using the arithmetic mean chemical concentration found in the samples. Of all carcinogenic chemicals detected in the liver samples, only the total PCBs concentration yielded a cancer risk exceeding the U.S. EPA acceptable risk level, with a risk value of 2.804 x 10-6. Some of the chemicals studied, such as arsenic and mercury, occur naturally in the environment and present a "natural" risk because of their behavior in the marine environment. Due to their ban in the U.S. and decreased use in Mexico, the concentrations of the "legacy" pollutants, such as DDT andPCBs, should continue to decline to within de minimus levels over the next decade or two. The results of this study have shown that some of the chemicals analyzed exert a marginal level of unacceptable risk at present, particularly when consumed at subsistence levels; thus, it is important that continued research be conducted to better establish fish consumption data and to aid in the creation of accurate fish consumption guidelines for anglers on the Imperial Beach Pier.
Author: United States. Environmental Protection Agency. Office of Science and Technology Publisher: ISBN: Category : Fish as food Languages : en Pages : 400
Author: Pravat Kumar Shit Publisher: Springer Nature ISBN: 3031092708 Category : Science Languages : en Pages : 732
Book Description
This book demonstrates the measurement, monitoring, mapping and modelling of soil pollution and land resources. This book explores state-of-the-art techniques based on open sources software & R statistical programming and modelling in modern geo-computation techniques specifically focusing on the recent trends in data mining/machine learning techniques and robust modelling in soil resources. Soil and agricultural systems are an integral part of the global environment and human well‐being, providing multiple goods and services essential for people worldwide and crucial for sustainable development. Soil contamination is an environmental hazard and has become a big issue related to environmental health. The challenge of the twenty-first century is to reduce the contaminant load and bring it to below permissible level. The contamination is not only a problem affecting local environments at the place of occurrence but also spreading to other regions because of easy transportation of pollutants. This leads to direct and indirect contamination of land and aquatic systems, surface water and groundwater, inducing significant risks for natural ecosystems. In this context, the spatial modelling, prediction, efficient use, risk assessment, protection and management of soil resources in the agriculture system are the key to achieving sustainable development goals and ensuring the promotion of an economically, socially and environmental sustainability future. The aim of this book on soil contaminants and environmental health: application of geospatial technology is to identify the soil and sediment quality, sources of contaminants and risk assessment and focuses on the decision-making and planning point of view through GIS data management techniques. This book covers major topics such as spatial modelling in soil and sediments pollution and remediation; radioactive wastes, microbiology of soil and sediments, soil salinity and sodicity, pollution from landfill sites, soil erosion and contamination from agricultural activities, heavy metal pollution and health risk; environmental impact and risk assessment, sustainable land use, landscape management and governance, soil degradation and risk assessment, agricultural soil pollution, pollution due to urban activities, soil pollution by industrial effluents and solid wastes, pollution control and mitigation in extreme environments. The content of this book is of interest to researchers, professionals and policy-makers whose work is in soil science and agriculture practices. The book equips with the knowledge and skills to tackle a wide range of issues manifested in geographic data, including those with scientific, societal and environmental implications.
Author: California Environmental Protection Agency. Office of Environmental Health Hazard Assessment Publisher: ISBN: Category : Fishes Languages : en Pages : 149
Author: Institute of Medicine Publisher: National Academies Press ISBN: 0309043875 Category : Medical Languages : en Pages : 449
Book Description
Can Americans continue to add more seafood to their diets without fear of illness or even death? Seafood-caused health problems are not widespread, but consumers are at risk from seafood-borne microbes and toxinsâ€"with consequences that can range from mild enteritis to fatal illness. At a time when legislators and consumer groups are seeking a sound regulatory approach, Seafood Safety presents a comprehensive set of practical recommendations for ensuring the safety of the seafood supply. This volume presents the first-ever overview of the field, covering seafood consumption patterns, where and how seafood contamination occurs, and the effectiveness of regulation. A wealth of technical information is presented on the sources of contaminationâ€"microbes, natural toxins, and chemical pollutantsâ€"and their effects on human health. The volume evaluates methods used for risk assessment and inspection sampling.
Author: Mallory Arden Lushenko
Author: Mallory Arden Lushenko
Author: Sunday Cookey Ekpo
Author: 
Author: United States. Environmental Protection Agency. Office of Science and Technology
Author: Pravat Kumar Shit
Author: California Environmental Protection Agency. Office of Environmental Health Hazard Assessment
Author: 
Author: James Edward Howell
Author: Institute of Medicine
Author: