Jeffrey Lodwick scite author profile

Jeffrey Lodwick

5Publications

40Citation Statements Received

41Citation Statements Given

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Affiliations

Occupational Safety & Health Administration, National Institute for Occupational Safety and Health, University of Cincinnati

Publications

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An outbreak of work‐related asthma and silicosis at a US countertop manufacturing and fabrication facility

Tustin

Kundu-Orwa

Lodwick

et al. 2021

American J Industrial Med

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Background: Outbreaks of severe silicosis have affected workers who fabricate artificial stone countertops. Work-related asthma (WRA) has not been a prominent feature of those prior outbreaks.Methods: This report describes an outbreak of WRA and silicosis at a facility that manufactures and fabricates chemical-resistant countertops comprised of sand, epoxy resin, and phthalic anhydride (PA), a known respiratory sensitizer. The multidisciplinary investigation included clinical examinations of workers, an industrial hygiene survey with qualitative and quantitative exposure assessments, and a crosssectional questionnaire.Results: Engineering controls and personal protective equipment were inadequate. Some workers were exposed to PA or silica above permissible exposure limits established by the Occupational Safety and Health Administration (OSHA). Clinical and epidemiologic investigations identified 16 workers with confirmed or suspected WRA. Two years later, after OSHA began to enforce its new silica standards, 12 workers received medical surveillance for silicosis. Of these 12 workers, four (33.3%) were diagnosed with silicosis based on abnormal chest computed tomography examinations.Conclusions: Artificial stone countertop workers can develop asthma or silicosis.Risk of asthma may be highest in workers exposed to asthmagens such as PA and epoxy resins while manufacturing the artificial stone material.

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Estimation of radon exposures to workers at the Fernald Feed Materials Production Center 1952–1988

Hornung

Pinney

Lodwick

et al. 2008

J Expo Sci Environ Epidemiol

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The Feed Materials Production Center (FMPC) at Fernald, Ohio produced uranium metal products for use in Department of Energy defense programs. Radium-contaminated waste material was stored on-site in two K-65 silos on the west side of the facility and provided a source of 222 Ra. The initial objective of this study was to estimate radon exposures to employees at FMPC working from 1952 to 1988. A modified Gaussian plume model was used to estimate exposures to workers. In an effort to validate these model-based estimates, we used 138 CR-39 film assays from window glass sampled in buildings throughout the site. Results from the CR-39 assays indicated a second substantial source of radon, the smaller Q-11 silos located in the production area. A response-surface regression analysis using a cubic spline model was fit to the CR-39 data to estimate 210 Po surface activity levels at geographic coordinates throughout the facility. Knowledge of the age of the glass, the amount of contaminated waste in the Q-11 silos, and 210 Po decay rates were used to estimate annual exposures to radon decay products (WLM: working level months). Estimated WLM levels associated with the Q-11 source term indicated that employees working in the vicinity during the period when they were filled with radium-contaminated waste (1952)(1953)(1954)(1955)(1956)(1957)(1958) received substantially higher radon exposures than those from the K-65 source during this period. Results of the two models, corresponding to the K-65 and Q-11 sources, were combined to estimate WLM levels by year for each of the 7143 Fernald workers during the period 1952-1988. Estimated cumulative exposures to individual workers ranged from o0.5 to 751 WLM. Estimated radon exposures from this newly discovered source have important implications for future epidemiologic studies of lung cancer in workers at the Fernald facility.

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Design, Fabrication & Evaluation of a New Calibration Phantom for In vivo Measurement of Bone-seeking Radionuclides

Spitz¹,

Lodwick²

2000

Radiation Protection Dosimetry

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A New Anthropometric Phantom for Calibrating in Vivo Measurements of Stable Lead in the Human Leg Using X-Ray Fluorescence

Spitz

Jenkins²,

Lodwick³

et al. 2000

Health Physics

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A new anthropometric phantom has been developed for calibrating in vivo measurements of stable lead deposited in bone using x-ray fluorescence. The phantom reproduces the shape of the mid shaft of the adult human leg and is fabricated using polyurethanes and calcium carbonate to produce materials that exhibit the same density, energy transmission, and calcium content as cortical bone, bone marrow, and muscle. The phantom includes a removable tibia fabricated using simulants for cortical bone and bone marrow to which a precise amount of stable lead has been added to cortical bone. The formulations used in fabricating the new anthropometric phantom are much more uniform in density and composition than the conventional phantom made from Plexiglas cylinders filled with plaster-of-Paris. The energy spectrum from an x-ray fluorescence measurement of the phantom using a 109Cd source is indistinguishable from an in vivo x-ray fluorescence measurement of the human leg, demonstrating that the materials used in the phantom exhibit the same radiological properties as human tissue. Likewise, results from x-ray fluorescence measurements of the phantom exhibit the same positional dependency as the human leg and vary by approximately 36% when, for example, the phantom containing 54 ppm of stable lead in the tibia was rotated by only 15 degrees. The detection limit for a 30 min 109Cd K shell x-ray fluorescence in vivo measurement is approximately 20 ppm determined from a background measurement using the new phantom containing no added lead in the muscle, bone, or bone marrow. The new anthropometric phantom significantly improves in vivo x-ray fluorescence calibration measurements by (1) faithfully reproducing the anatomy of the human leg, (2) having components that exhibit radiological properties similar to that of human tissue, and (3) providing a realistic calibration standard that can be used for in vivo x-ray fluorescence intercomparison measurements.

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Solubility of Airborne Uranium Compounds at the Fernald Environmental Management Project

Heffernan¹,

Lodwick²,

Spitz³

et al. 2001

Health Physics

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Jeffrey Lodwick

An outbreak of work‐related asthma and silicosis at a US countertop manufacturing and fabrication facility

Estimation of radon exposures to workers at the Fernald Feed Materials Production Center 1952–1988

Design, Fabrication & Evaluation of a New Calibration Phantom for In vivo Measurement of Bone-seeking Radionuclides

A New Anthropometric Phantom for Calibrating in Vivo Measurements of Stable Lead in the Human Leg Using X-Ray Fluorescence

Solubility of Airborne Uranium Compounds at the Fernald Environmental Management Project

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