Neurological effects of aerosolized red tide neurotoxins
Roskamp Institute, Inc., Sarasota FL
Investigators
Abstract
The observed increased occurrences of harmful algal blooms (HABs), eutrophication and nutrient pollution and raise concerns that HABs are negatively impacting aquatic ecosystems, coastal resources and the health of coastal communities. Among these HABs, Karenia (K.) brevis affects many Gulf Coast communities, particularly southwest Florida. Over the last decade, K. brevis blooms have caused massive destruction to marine life and morbidity and mortality of marine mammals. These harmful effects of K. brevis are attributed to the release of potent neurotoxins, brevetoxins (PbTx). Currently, the impact on the central nervous system (CNS) of aerosolized PbTx exposure in humans is not yet known. Human consumption of PbTx causes Neurotoxic Shellfish Poisoning (NSP), including a wide range of neurological symptoms. We recently showed that SW Florida residents exposed to aerosolized PbTx are experiencing NSP-like (NSPL) symptoms, and those with past medical histories (PMHx) of migraine and chronic fatigue syndrome (CFS) were particularly vulnerable to the neurological effects of aerosolized PbTx. Carriers of the apolipoprotein E (APOE) e4 allele genetically at a higher risk of cognitive impairment more frequently experience memory problems and fatigue during red tide blooms. We have detected PbTx in blood and antibodies against PbTx correspond with reporting of NSPL symptoms following exposure to aerosolized PbTx. However, a dose-response relationship between aerosolized PbTx exposure and the emergence of NSPL and neurological symptoms is currently unknown. Therefore, we will determine a dose-response relationship between aerosolized PbTx exposure and NSPL and neurological symptoms. We will determine whether individuals with preexisting neurological conditions or e4 carriers more frequently experience NSPL compared to general residents and non-carriers. We will also determine whether PbTx in biospecimens and blood PbTx antibodies can serve as biomarkers of NSPL and neurological symptoms. Currently, there is no information available on PbTx pharmacokinetics (PK) in humans. Therefore, we will determine the PK parameters using PbTx in biospecimens and determine their relationship to NSPL and neurological symptoms. Using physiology-based PK modeling, we will estimate the amounts of PbTx that can reach the human brain, which will be critical for understanding the adverse brain health effects from aerosolized PbTx exposure. The proposed work will inform future decision-making for developing strategies to minimize the risks of neurological symptoms in humans following aerosolized PbTx exposure. Given the occurrences of powerful hurricanes in the Pacific and Atlantic Oceans and subsequent occurrences of intense HABs in coastal waters, the proposed work will provide a roadmap for future investigations into studying the adverse human health impact from exposure to HAB toxins.
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