RESUMEN
Marine phycotoxins are a multiplicity of bioactive compounds which are produced by microalgae and bioaccumulate in the marine food web. Phycotoxins affect the ecosystem, pose a threat to human health, and have important economic effects on aquaculture and tourism worldwide. However, human health and food safety have been the primary concerns when considering the impacts of phycotoxins. Phycotoxins toxicity information, often used to set regulatory limits for these toxins in shellfish, lacks traceability of toxicity values highlighting the need for predefined toxicological criteria. Toxicity data together with adequate detection methods for monitoring procedures are crucial to protect human health. However, despite technological advances, there are still methodological uncertainties and high demand for universal phycotoxin detectors. This review focuses on these topics, including uncertainties of climate change, providing an overview of the current information as well as future perspectives.
Asunto(s)
Toxinas Marinas , Microalgas , Contaminantes del Agua , Animales , Cambio Climático , Humanos , Toxinas Marinas/análisis , Toxinas Marinas/uso terapéutico , Toxinas Marinas/toxicidad , Contaminantes del Agua/análisis , Contaminantes del Agua/uso terapéutico , Contaminantes del Agua/toxicidadRESUMEN
High accumulations of phytoplankton species that produce toxins are referred to as harmful algal blooms (HABs). HABs represent one of the most important sources of contamination in marine environments, as well as a serious threat to public health, fisheries, aquaculture-based industries, and tourism. Therefore, methods effectively controlling HABs with minimal impact on marine ecology are required. Marine dinoflagellates of the genera Dinophysis and Prorocentrum are representative producers of okadaic acid (OA) and dinophysistoxins responsible for the diarrhetic shellfish poisoning (DSP) which is a human intoxication caused by the consumption of shellfish that bioaccumulate those toxins. In this work we explore the use of natural clay for removing Prorocentrum lima. We evaluate the adsorption properties of clays in seawater containing the dinoflagellates. The experimental results confirmed the cell removal through the flocculation of algal and mineral particles leading to the formation of aggregates, which rapidly settle and further entrain cells during their descent. Moreover, the microscopy images of the samples enable one to observe the clays in aggregates of two or more cells where the mineral particles were bound to the outer membranes of the dinoflagellates. Therefore, this preliminary data offers promising results to use these clays for the mitigation of HABs.
Asunto(s)
Silicatos de Aluminio/química , Bentonita/química , Dinoflagelados/aislamiento & purificación , Caolín/química , Agua de Mar/parasitología , Contaminantes del Agua/aislamiento & purificación , Adsorción , Arcilla , Floculación , Floraciones de Algas Nocivas , Tamaño de la Partícula , Propiedades de SuperficieRESUMEN
Paralytic shellfish poisoning is one of the most severe forms of food poisoning. The toxins responsible for this type of poisoning are metabolic products of dinoflagellates, which block neuronal transmission by binding to the voltage-gated Na(+) channel. Accumulation of paralytic toxins in shellfish is an unpredictable phenomenon that necessitates the implementation of a widespread and thorough monitoring program for mollusk toxicity. All of these programs require periodical collection and analysis of a wide range of shellfish. Therefore, development of accurate analytical protocols for the rapid determination of toxicity levels would streamline this process. Our laboratory has developed a fluorimetric microplate bioassay that rapidly and specifically determines the presence of paralytic shellfish toxins in many seafood samples. This method is based on the pharmacological activity of toxins and involves several steps: (i) Incubation of excitable cells in 96 well microtiter plates with the fluorescent dye, bis-oxonol, the distribution of which across the membrane is potential-dependent. (ii) Cell depolarization with veratridine, a sodium channel-activating toxin. (iii) Dose-dependent inhibition of depolarization with saxitoxin or natural samples containing paralytic shellfish toxins. Measuring toxin-induced changes in membrane potential allowed for quantification and estimation of the toxic potency of the samples. This new approach offers significant advantages over classical methods and can be easily automated.