Your search keyword '"Bradham K"' showing total 4 results

1. Determination of hand soil loading, soil transfer, and particle size variations after hand-pressing and hand-mouthing activities.

Author

Hsi HC, Hu CY, Tsou MC, Hu HJ, Özkaynak H, Bradham K, Hseu ZY, Dang W, and Chien LC

Subjects

Environmental Exposure statistics & numerical data, Humans, Particle Size, Silicon Dioxide, Soil chemistry, Environmental Exposure analysis, Skin chemistry, Soil Pollutants analysis

Abstract

Hand-pressing trials and hand-to-mouth soil transfer experiments were conducted to better understand soil loadings, soil transfer ratios for three mouthing activities, and variations in particle size distributions under various conditions. Results indicated that sand caused higher soil loadings on the hand than clay. When the moisture level of clay soil exceeded its liquid limit, soil loadings also increased. Greater pressing pressures also led to larger clay loadings. Clay with a moisture content close to its plastic limit caused the smallest soil loadings due to strong soil cohesion. Particle sizes of the transferred clay were larger than that of the original clay, indicating that hand-pressing and the pressure exerted may have enhanced clay particles of larger sizes adhering onto the hand. Nevertheless, the sizes of most particles that adhered to the hand were still smaller than 150 μm. Higher pressing pressures and greater moisture contents resulted in larger soil loadings on the hand, and transfer ratios became smaller. Transfer ratios from palm-licking with clay particles were smaller than those from finger-mouthing, which may have been due to finer particles that more readily adhered to the skin of the palm and that were transferred from the hand to the mouth with greater difficulty., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2018

2. Role of complex organic arsenicals in food in aggregate exposure to arsenic.

Author

Thomas DJ and Bradham K

Subjects

Arsenic Poisoning epidemiology, Food, Humans, Risk Assessment, Arsenicals, Carcinogens, Environmental Exposure statistics & numerical data, Food Contamination statistics & numerical data

Abstract

For much of the world's population, food is the major source of exposure to arsenic. Exposure to this non-essential metalloid at relatively low levels may be linked to a wide range of adverse health effects. Thus, evaluating foods as sources of exposure to arsenic is important in assessing risk and developing strategies that protect public health. Although most emphasis has been placed on inorganic arsenic as human carcinogen and toxicant, an array of arsenic-containing species are found in plants and animals used as foods. Here, we 2evaluate the contribution of complex organic arsenicals (arsenosugars, arsenolipids, and trimethylarsonium compounds) that are found in foods and consider their origins, metabolism, and potential toxicity. Commonalities in the metabolism of arsenosugars and arsenolipids lead to the production of di-methylated arsenicals which are known to exert many toxic effects. Evaluating foods as sources of exposure to these complex organic arsenicals and understanding the formation of reactive metabolites may be critical in assessing their contribution to aggregate exposure to arsenic., (Copyright © 2016. Published by Elsevier B.V.)

Published

2016

3. Estimating dermal transfer of copper particles from the surfaces of pressure-treated lumber and implications for exposure.

Author

Platten WE 3rd, Sylvest N, Warren C, Arambewela M, Harmon S, Bradham K, Rogers K, Thomas T, and Luxton TP

Subjects

Environmental Monitoring, Copper analysis, Environmental Exposure statistics & numerical data, Particulate Matter analysis, Wood chemistry

Abstract

Lumber pressure-treated with micronized copper was examined for the release of copper and copper micro/nanoparticles using a surface wipe method to simulate dermal transfer. In 2003, the wood industry began replacing CCA treated lumber products for residential use with copper based formulations. Micronized copper (nano to micron sized particles) has become the preferred treatment formulation. There is a lack of information on the release of copper, the fate of the particles during dermal contact, and the copper exposure level to children from hand-to-mouth transfer. For the current study, three treated lumber products, two micronized copper and one ionic copper, were purchased from commercial retailers. The boards were left to weather outdoors for approximately 1year. Over the year time period, hand wipe samples were collected periodically to determine copper transfer from the wood surfaces. The two micronized formulations and the ionic formulation released similar levels of total copper. The amount of copper released was high initially, but decreased to a constant level (~1.5mgm(-2)) after the first month of outdoor exposure. Copper particles were identified on the sampling cloths during the first two months of the experiment, after which the levels of copper were insufficient to collect interpretable data. After 1month, the particles exhibited minimal changes in shape and size. At the end of 2-months, significant deterioration of the particles was evident. Based on the wipe sample data, a playground visit may result in a potential exposure to 2.58mg of copper, which is near or exceeds the daily tolerable upper intake limits for children under the age of 8, if completely ingested through hand-to-mouth transfer. While nanoparticles were found, there is not enough information to estimate the exposure from the released particles due to a lack of published literature on copper carbonate., (Published by Elsevier B.V.)

Published

2016

4. Development of an Environmental Relative Moldiness index for US homes.

Author

Vesper S, McKinstry C, Haugland R, Wymer L, Bradham K, Ashley P, Cox D, Dewalt G, and Friedman W

Subjects

Colony Count, Microbial, Fungi classification, Housing, Humans, Polymerase Chain Reaction, Air Microbiology, Air Pollution, Indoor analysis, Dust analysis, Environmental Exposure analysis, Fungi isolation & purification

Abstract

Objective: The objective of this study was to establish a national relative moldiness index for homes in the United States., Methods: As part of the Housing and Urban Development's American Healthy Homes Survey, dust samples were collected by vacuuming 2 m in the bedrooms plus 2 m in the living rooms from a nationally representative 1096 homes in the United States using the Mitest sampler. Five milligrams of sieved (300 mum pore, nylon mesh) dust was analyzed by mold-specific quantitative polymerase chain reaction for the 36 indicator species in 1096 samples., Results: On the basis of this standardized national sampling and analysis, an "Environmental Relative Moldiness Index" was created with values ranging from about -10 to 20 or above (lowest to highest)., Conclusions: The Environmental Relative Moldiness Index scale may be useful for home mold-burden estimates in epidemiological studies.

Published

2007