Over the past 3 years, the Research Project 4 (RP4) Investigators have assembled a cohort of? asthmatics and studied their respiratory responses to Florida red tide by comparing exposure and nonexposure? periods. We have demonstrated statistically significant changes in inflammatory markers,? respiratory function and reported symptoms in asthmatics with only 1 hour of acute beach exposure; no? significant changes were observed during similar non-exposure periods. Parallel to these studies, the? Investigators have assisted the Centers for Disease Control and Prevention (CDC) and the Florida Dept? of Health (FDOH) in assembling and evaluating an occupational cohort. This represents the first time that? possible health effects from exposure to aerosolized Florida red tide toxins have been evaluated? epidemiologically in human populations.? Over the next 5 years, working with the Toxin Probes and Assays Core, the Field Logistics and Development Core, and Project by Cheng, we propose? to continue studying the exposures and health effects for humans due to aerosol exposures to Florida? Red Tide, using new measures of exposure and physiologic effects. Specifically, we will annually collect? pre- and post-exposure health effects and environmental exposure data at a time when a Florida red tide? occurs and at a time with no Florida red tide for 1 hour of beach exposure. In addition, the investigators? will annually conduct a 5 day Follow-up Study directly following the 1 hour Acute Exposure Study to? collect data on persistent and delayed health effects from the acute exposure, as well as from possible? repetitive exposures to Florida red tides toxins over 5 days. Additional data will be collected every 6? months to evaluate the severity and controllability of the asthmatics in the prior 6 months. The data from? these annual studies (exposed and unexposed) will be evaluated longitudinally to explore possible? chronic effects of varying Florida red tide toxin levels on the health of asthmatics, as well as? subpopulations among the asthmatics.? Based on the results of the animals models ( Projects by Benson and Abraham) and our epidemiologic work, we? will use the following measurable physiologic effects: reported symptoms and measures of asthma? controllability, spirometry, nasal swabs for inflammatory mediators, and exhaled condensates for? acidification and selected cytokines, as well as the exposure measures of environmental and personal? monitoring and nasal swabs for brevetoxins. The possible association between the uncontrollability of? asthma associated with Florida red tide toxin exposure over time will be evaluated. In addition, the? possible dose response relationship will be explored between long term exposure to Florida red tide? toxins and their effects on measurable physiologic effects in asthmatics by evaluating coastal vs inland? residents. Over the proposed 5 years, the project investigators will also take advantage of advancements in? the science made by the other Projects to refine methods for measuring human exposures and? physiologic effects from this environmental occurrence. The data from these studies will provide? valuable medical and public health information concerning acute, subacute and chronic respiratory? effects of aerosolized red tide toxin exposures annually in asthmatics over a 5 year period.?

Agency
National Institute of Health (NIH)
Institute
National Institute of Environmental Health Sciences (NIEHS)
Type
Research Program Projects (P01)
Project #
5P01ES010594-07
Application #
7479617
Study Section
Special Emphasis Panel (ZES1)
Project Start
Project End
Budget Start
2007-07-01
Budget End
2008-06-30
Support Year
7
Fiscal Year
2007
Total Cost
$332,256
Indirect Cost
Name
University of North Carolina Wilmington
Department
Type
DUNS #
040036584
City
Wilmington
State
NC
Country
United States
Zip Code
28403
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Goodman, Allan; McCall, Jennifer R; Jacocks, Henry M et al. (2014) Structure activity relationship of brevenal hydrazide derivatives. Mar Drugs 12:1839-58
McCall, Jennifer R; Goodman, Allan J; Jacocks, Henry M et al. (2014) Development of a fluorescence assay for the characterization of brevenal binding to rat brain synaptosomes. J Nat Prod 77:2014-20
Gold, Elena P; Jacocks, Henry M; Bourdelais, Andrea J et al. (2013) Brevenal, a brevetoxin antagonist from Karenia brevis, binds to a previously unreported site on mammalian sodium channels. Harmful Algae 26:12-19
McCall, Jennifer R; Jacocks, Henry M; Baden, Daniel G et al. (2012) Development of a competitive fluorescence-based synaptosome binding assay for brevetoxins. Harmful Algae 19:85-91
Zhou, Yue; Sun, Jaijie; Cheng, Yung-Sung (2011) Comparison of deposition in the USP and physical mouth-throat models with solid and liquid particles. J Aerosol Med Pulm Drug Deliv 24:277-84
Bean, Judy A; Fleming, Lora E; Kirkpatrick, Barbara et al. (2011) Florida Red Tide Toxins (Brevetoxins) and Longitudinal Respiratory Effects in Asthmatics. Harmful Algae 10:744-748
Benson, Janet M; Wolf, Molly L; Kajon, Adriana et al. (2011) Brevetoxin inhalation alters the pulmonary response to influenza A in the male F344 rat. J Toxicol Environ Health A 74:313-24
Murrell, Rachel N; Gibson, James E (2011) Brevetoxin 2 alters expression of apoptotic, DNA damage, and cytokine genes in Jurkat cells. Hum Exp Toxicol 30:182-91
Fleming, Lora E; Kirkpatrick, Barbara; Backer, Lorraine C et al. (2011) Review of Florida Red Tide and Human Health Effects. Harmful Algae 10:224-233

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