Persistence of Vibrio vulnificus in tissues of Gulf Coast oysters, Crassostrea virginica, exposed to seawater disinfected with UV light.

Vibrio vulnificus is an estuarine bacterium which can cause opportunistic infections in humans consuming raw Gulf Coast oysters, Crassostrea virginica. Although V. vulnificus is known as a ubiquitous organism in the Gulf of Mexico, its ecological relationship with C. virginica has not been adequately defined. The objective of the present study was to test the hypothesis that V. vulnificus is a persistent microbial flora of oysters and unamenable to traditional methods of controlled purification, such as UV light depuration. Experimental depuration systems consisted of aquaria containing temperature-controlled seawater treated with UV light and 0.2-microns-pore-size filtration. V. vulnificus was enumerated in seawater, oyster shell biofilms, homogenates of whole oyster meats, and tissues including the hemolymph, digestive region, gills, mantle, and adductor muscle. Results showed that depuration systems conducted at temperatures greater than 23 degrees C caused V. vulnificus counts to increase in oysters, especially in the hemolymph, adductor muscle, and mantle. Throughout the process, depuration water contained high concentrations of V. vulnificus, indicating that the disinfection properties of UV radiation and 0.2-microns-pore-size filtration were less than the rate at which V. vulnificus was released into seawater. Approximately 10(5) to 10(6) V. vulnificus organisms were released from each oyster per hour, with 0.05 to 35% originating from shell surfaces. These surfaces contained greater than 10(3) V. vulnificus organisms per cm2. In contrast, when depuration seawater was maintained at 15 degrees C, V. vulnificus was not detected in seawater and multiplication in oyster tissues was inhibited.     

Persistence of Vibrio vulnificus in tissues of Gulf Coast oysters, Crassostrea virginica, exposed to seawater disinfected with UV light.

Vibrio vulnificus is an estuarine bacterium which can cause opportunistic infections in humans consuming raw Gulf Coast oysters, Crassostrea virginica. Although V. vulnificus is known as a ubiquitous organism in the Gulf of Mexico, its ecological relationship with C. virginica has not been adequately defined. The objective of the present study was to test the hypothesis that V. vulnificus is a persistent microbial flora of oysters and unamenable to traditional methods of controlled purification, such as UV light depuration. Experimental depuration systems consisted of aquaria containing temperature-controlled seawater treated with UV light and 0.2-microns-pore-size filtration. V. vulnificus was enumerated in seawater, oyster shell biofilms, homogenates of whole oyster meats, and tissues including the hemolymph, digestive region, gills, mantle, and adductor muscle. Results showed that depuration systems conducted at temperatures greater than 23 degrees C caused V. vulnificus counts to increase in oysters, especially in the hemolymph, adductor muscle, and mantle. Throughout the process, depuration water contained high concentrations of V. vulnificus, indicating that the disinfection properties of UV radiation and 0.2-microns-pore-size filtration were less than the rate at which V. vulnificus was released into seawater. Approximately 10(5) to 10(6) V. vulnificus organisms were released from each oyster per hour, with 0.05 to 35% originating from shell surfaces. These surfaces contained greater than 10(3) V. vulnificus organisms per cm2. In contrast, when depuration seawater was maintained at 15 degrees C, V. vulnificus was not detected in seawater and multiplication in oyster tissues was inhibited.     

Distribution of Vibrio vulnificus in the Chesapeake Bay.

Vibrio vulnificus is a potentially lethal human pathogen capable of producing septicemia in susceptible persons. Disease is almost always associated with consumption of seafood, particularly raw oysters, or with exposure of wounds to seawater. An oligonucleotide DNA probe (V. vulnificus alkaline phosphatase-labeled DNA probe [VVAP]), previously shown to be highly specific for V. vulnificus, was used to enumerate this species in environmental samples collected from the Chesapeake Bay between April 1991 and December 1992. Total aerobic, heterotrophic, culturable bacteria were enumerated by plate counts on nonselective medium. The number of V. vulnificus organisms was determined by colony lifts of spread plates for subsequent hybridization with VVAP. V. vulnificus was not detected in any samples collected during February and March (water temperature of < 8 degrees C) but was found in 80% of the water samples collected during May, July, September, and December (water temperature of > 8 degrees C), with concentrations ranging from 3.0 x 10(1) to 2.1 x 10(2)/ml (ca. 8% of the total culturable heterotrophic bacteria). In a multiple regression analysis, increased V. vulnificus concentrations were correlated with lower salinities and with isolation from samples collected closer to the bottom. Isolation from oysters was demonstrable when water temperatures were 7.6 degrees C, with concentrations ranging from 1.0 x 10(3) to 4.7 x 10(4)/g (ca. 12% of total culturable bacteria). In samples collected in May and July, V. vulnificus was identified in seven of seven plankton samples and four of nine sediment samples. Our data demonstrate that V. vulnificus is a widespread and important component of the bacterial population of the Chesapeake Bay, with counts that are comparable to those reported from the Gulf of Mexico.     

Effects of temperature and salinity on the survival of Vibrio vulnificus in seawater and shellfish.

Sterilized seawater was used to assess the effects of temperature and salinity on the survival of Vibrio vulnificus. In the temperature range of 13 to 22 degrees C, numbers of V. vulnificus increased during the 6-day incubation. Temperatures outside this range reduced the time of V. vulnificus survival in sterile 10-ppt seawater. At these restrictive temperatures, V. vulnificus numbers were reduced by 90% after 6 days of incubation. Incubation between 0.5 and 10.5 degrees C demonstrated that V. vulnificus survives poorly below 8.5 degrees C. At salinities between 5 and 25 ppt and at 14 degrees C, V. vulnificus numbers actually increased or remained unchanged after 6 days of incubation. At salinities of 30, 35, and 38 ppt, numbers of V. vulnificus decreased 58, 88, and 83%, respectively. V. vulnificus could not be recovered from deionized water, indicating lysis. When a rifampin-resistant strain of V. vulnificus was used to inoculate sterilized and unsterilized seawater (20 ppt, 20 degrees C), numbers increased in sterile seawater but decreased to undetectable levels in 14 days in the unsterilized seawater, indicating that biological factors may play a role in the survival of V. vulnificus in the environment. Since our studies demonstrated sensitivity to low temperatures, the survival of V. vulnificus in naturally contaminated oysters at temperatures of 0, 2, and 4 degrees C was also determined. Numbers of endogenous V. vulnificus in oyster shellstock increased by more than 100-fold in shellstock stored at 30 degrees C but were reduced approximately 10- and 100-fold after 14 days at 2 to 4 degrees C and 0 degrees C, respectively. We conclude that both biological and physicochemical factors are important to the survival of V. vulnificus in the environment and that temperature is critical to controlling its growth in oyster shellstock.     

Occurrence, seasonality and genetic diversity of Vibrio vulnificus in coastal seaweeds and water along the Kii Channel, Japan

Vibrio vulnificus is a ubiquitous toxigenic bacterium found in a coastal environment but little is known about its occurrence and seasonality among seaweeds, which are widely consumed as seafood in Japan. Therefore, we have observed the bacterium's abundance in seawater and seaweed samples from three areas of the Kii Channel, Japan, during June 2003 to May 2004. A total of 192 samples were collected: 24 from each source in summer, autumn, winter and spring. The samples were selectively cultivated following the most probable number (MPN) technique. Vibrio vulnificus population ranged from 0 to 10(3) MPN 100 mL(-1) seawater or 10 g seaweeds; higher counts were observed during summer. The optimum temperature, salinity and pH for the bacterium were 20-24 degrees C, 24-28 p.p.t. and 7.95-8.15, respectively. However, seaweeds always contained higher V. vulnificus than seawater. Among 280 V. vulnificus strains, detected by species-specific colony hybridization and PCR, 78, 74, 11 and 16 were from seaweeds and 46, 42, 2 and 11 were from seawater during summer, autumn, winter and spring, respectively. Ribotyping of 160 selected strains revealed a higher genotypic diversity (18 patterns) among strains from seaweeds than from seawater (10 patterns). Seaweeds can thus act as a potential habitat for V. vulnificus and are more unsafe for consumption during summer.     

Offshore suspension relaying to reduce levels of Vibrio vulnificus in oysters (Crassostrea virginica).

Oysters naturally contaminated with 10(3) to 10(4) most probable numbers (MPN) of Vibrio vulnificus per g were relayed to offshore waters (salinity, 30 to 34 ppt), where they were suspended in racks at a depth of 7.6 m. V. vulnificus counts in oysters were reduced to < 10 MPN/g within 7 to 17 days in five of the six studies. At the end of the studies (17 to 49 days), V. vulnificus levels were reduced further and ranged from a mean of 0.23 to 2.6 MPN/g. Oyster mortalities during relaying were < 6%. The reduction of V. vulnificus in relayed oysters is associated with exposure to high-salinity environments essentially devoid of V. vulnificus. Offshore suspension relaying may be a method that industry can employ to reduce V. vulnificus levels in raw Gulf Coast oysters.     

Survival of Vibrio vulnificus in shellstock and shucked oysters (Crassostrea gigas and Crassostrea virginica) and effects of isolation medium on recovery.

When two species of shellstock oysters were artificially contaminated with Vibrio vulnificus, the bacterium survived when the oysters were stored at 10 degrees C and below. Large numbers of endogenous V. vulnificus cells were found after 7 days at both 0.5 and 10 degrees C in uninoculated control oysters (Crassostrea virginica). Oysters allowed to take up V. vulnificus from seawater retained the bacterium for 14 days at 2 degrees C. The presence of V. vulnificus in the drip exuded from the shellstock presented a possibility of contamination of other shellstock in storage. V. vulnificus injected into shucked Pacific (Crassostrea gigas) and Eastern (C. virginica) oysters survived at 4 degrees C for at least 6 days. An 18-h most-probable-number enrichment step in alkaline peptone water gave higher recovery levels of V. vulnificus than did direct plating to selective agars. The survival of this pathogen in both shellstock and shucked oysters suggests a potential for human illness, even though the product is refrigerated.     

Densities of Vibrio vulnificus in the intestines of fish from the U.S. Gulf Coast.

Densities of Vibrio vulnificus in the intestinal contents of various finfish, oysters, and crabs and in sediment and waters of the U.S. Gulf Coast were determined by the most probable number procedure. Species were identified by enzyme immunoassay. During the winter, densities of V. vulnificus were low, and the organism was isolated more frequently from sheepshead fish than from sediment and seawater. From April to October, V. vulnificus densities were considerably higher (2 to 5 logs) in estuarine fish than in surrounding water, sediment, or nearby oysters and crustacea. Highest densities were found in the intestinal contents of certain bottom-feeding fish (10(8)/100 g), particularly those that consume mollusks and crustaceans. Densities of V. vulnificus in fish that feed primarily on plankton and other finfish were similar to those in oysters, sediment, and crabs (10(5)/100 g). V. vulnificus was found infrequently in offshore fish. The presence of high densities of V. vulnificus in the intestines of common estuarine fish may have both ecological (growth and transport) and public health (food and wound infections) implications.     

Survival of Vibrio vulnificus in shellstock and shucked oysters (Crassostrea gigas and Crassostrea virginica) and effects of isolation medium on recovery

When two species of shellstock oysters were artificially contaminated with Vibrio vulnificus, the bacterium survived when the oysters were stored at 10 degrees C and below. Large numbers of endogenous V. vulnificus cells were found after 7 days at both 0.5 and 10 degrees C in uninoculated control oysters (Crassostrea virginica). Oysters allowed to take up V. vulnificus from seawater retained the bacterium for 14 days at 2 degrees C. The presence of V. vulnificus in the drip exuded from the shellstock presented a possibility of contamination of other shellstock in storage. V. vulnificus injected into shucked Pacific (Crassostrea gigas) and Eastern (C. virginica) oysters survived at 4 degrees C for at least 6 days. An 18-h most-probable-number enrichment step in alkaline peptone water gave higher recovery levels of V. vulnificus than did direct plating to selective agars. The survival of this pathogen in both shellstock and shucked oysters suggests a potential for human illness, even though the product is refrigerated.     

Real-time PCR analysis of Vibrio vulnificus from oysters

Vibrio vulnificus is an opportunistic human pathogen commonly found in estuarine environments. Infections are associated with raw oyster consumption and can produce rapidly fatal septicemia in susceptible individuals. Standard enumeration of this organism in shellfish or seawater is laborious and inaccurate; therefore, more efficient assays are needed. An oligonucleotide probe derived from the cytolysin gene, vvhA, was previously used for colony hybridizations to enumerate V. vulnificus. However, this method requires overnight growth, and vibrios may lack culturability under certain conditions. In the present study, we targeted the same locus for development of a TaqMan real-time PCR assay. Probe specificity was confirmed by amplification of 28 V. vulnificus templates and by the lack of a PCR product with 22 non-V. vulnificus strains. Detection of V. vulnificus in pure cultures was observed over a 6-log-unit linear range of concentration (10(2) to 10(8) CFU ml(-1)), with a lower limit of 72 fg of genomic DNA micro l of PCR mixture(-1) or the equivalent of six cells. Similar sensitivity was observed in DNA extracted from mixtures of V. vulnificus and V. parahaemolyticus cells. Real-time PCR enumeration of artificially inoculated oyster homogenates correlated well with colony hybridization counts (r(2) = 0.97). Numbers of indigenous V. vulnificus cells in oysters by real-time PCR showed no significant differences from numbers from plate counts with probe (t test; P = 0.43). Viable but nonculturable cells were also enumerated by real-time PCR and confirmed by the BacLight viability assay. These data indicate that real-time PCR can provide sensitive species-specific detection and enumeration of V. vulnificus in seafood.     

Development of a quantitative real-time polymerase chain reaction targeted to the toxR for detection of Vibrio vulnificus

The TaqMan assay, a quantitative real-time polymerase chain reaction (PCR), was developed to target the ToxR gene (toxR) of Vibrio vulnificus. The toxR of V. vulnificus was cloned and sequenced. Based on these results, we designed specific primers and a probe for use in the quantitative PCR assay. Twenty-nine strains of V. vulnificus that were obtained from various sources produced a single PCR product. The amount of final amplification product and threshold cycle number were the same among the strains. We used the method to detect V. vulnificus in seawater and oyster samples. We developed standard curves to quantitate V. vulnificus numbers using the PCR from seawater and oyster samples. The standard curves were not different from that of the pure culture of V. vulnificus. We found the assay was very sensitive detecting as few as 10 microbes per milliliter of seawater and oyster homogenate. Moreover, we evaluated the TaqMan assay to detect V. vulnificus in seawater samples. The numbers of V. vulnificus counted by the TaqMan assay were similar to those by a culture method in almost samples. The TaqMan assay was performed within 2 h compared to days using the culture method. The results indicate the TaqMan assay method used in this study was rapid, effective and quantitative for monitoring V. vulnificus contamination in seawater and seafoods such as oysters.     

Temperature effects on the viable but non-culturable state of Vibrio vulnificus

Abstract The non-culturable state of Vibrio vulnificus , strain C7184, was studied in artificial seawater microcosms held at 5, 10, 15, 20, and 30°C. Plate counts were made on a non-selective medium, total cell counts were monitored by acridine orange epifluorescence, and direct viable counts (DVSs) by the method of Kogure et al. (Can J. Microbiol. 25, 415–420; 1986) and by the INT method. From an initial inoculum of 10⁷ cells/ml, V. vulnificus became non-culturable within 40 days at 5°C, although both indicators of viability revealed a viable population exceeding 10⁶ cells/ml. Cells at all higher temperatures remained culturable (at least 10⁴/ml) throughout the study. The non-culturable states of the opaque and translucent colony variants of V. vulnificus , as well as those of six other clinical and environmental strains of V. vulnificus , were examined at 5°C; all but one strain and both colony variants also became non-culturable within 40 days. In contrast, six other Vibrio spp. ( V. cholerae, V. mimicus, V. parahaemolyticus, V. natriegens, V. proteolyticus , and V. campbelli ) remained culturable at 5°C. Thus, entrance of V. vulnificus into the non-culturable state appears to be highly temperature dependent and, among the vibrios, this species may be especially sensitive to low temperature. The public health aspects of these findings are discussed.     

Effects of temperature abuse on survival of Vibrio vulnificus in oysters.

Opaque and translucent morphotypes of a TnphoA-containing strain of Vibrio vulnificus were fed to oysters, which were subsequently stored at temperatures ranging from 0.5 to 22 degrees C for 10 days. Samples of oysters were homogenized and plated at intervals to determine the cell density of V. vulnificus and total aerobic population of bacteria present. At all temperatures, the numbers of V. vulnificus (both morphotypes) declined over the 10-day study period. The same observation was made with a lower inoculum of V. vulnificus. Identical experiments with shucked oysters showed a more rapid decrease in V. vulnificus. Identical experiments with shucked oysters showed a more rapid decrease in V. vulnificus to levels below limits of detection. Little change in the total bacterial counts was observed in shellstock oysters at any of the test temperatures, whereas incubation at the higher temperatures (17 and 22 degrees C) resulted in large increases in total counts in shucked oysters. These data suggest that temperature abuse of oysters may not be a factor in increasing the public health risk of V. vulnificus through raw oyster consumption. However, the data also suggest that even with proper storage, indigenous levels of V. vulnificus may remain sufficiently higher in shellstock oysters to produce infection in compromised hosts.     

Effects of temperature abuse on survival of Vibrio vulnificus in oysters.

Opaque and translucent morphotypes of a TnphoA-containing strain of Vibrio vulnificus were fed to oysters, which were subsequently stored at temperatures ranging from 0.5 to 22 degrees C for 10 days. Samples of oysters were homogenized and plated at intervals to determine the cell density of V. vulnificus and total aerobic population of bacteria present. At all temperatures, the numbers of V. vulnificus (both morphotypes) declined over the 10-day study period. The same observation was made with a lower inoculum of V. vulnificus. Identical experiments with shucked oysters showed a more rapid decrease in V. vulnificus. Identical experiments with shucked oysters showed a more rapid decrease in V. vulnificus to levels below limits of detection. Little change in the total bacterial counts was observed in shellstock oysters at any of the test temperatures, whereas incubation at the higher temperatures (17 and 22 degrees C) resulted in large increases in total counts in shucked oysters. These data suggest that temperature abuse of oysters may not be a factor in increasing the public health risk of V. vulnificus through raw oyster consumption. However, the data also suggest that even with proper storage, indigenous levels of V. vulnificus may remain sufficiently higher in shellstock oysters to produce infection in compromised hosts.     

C9泄漏事故对海湾生态系统服务的影响评估——以x海湾为例

海湾是海洋中最易受人类活动干扰的区域,构建C9泄漏造成的海湾生态系统服务损失评估框架并进行定量评估对维护海湾生态安全具有重要意义。本研究以x海湾C9泄漏事故为例,基于生态系统服务损失视角,综合应用市场价值法、替代成本法、碳税法及能值分析法,结合海湾生态过程,针对C9泄漏事故造成的关键生态系统服务(食品生产、气体调节、气候调节、废物处理、人体健康、养分循环、物种多样性维持、休闲娱乐)损失建立货币价值评估模式,分析了x海湾生态系统服务损失情况。结果表明: C9泄漏造成的x海湾关键生态系统服务损失总价值为1.93亿元,单位面积损失的货币价值达1.19亿元·km^-2,是一般海洋溢油事件的2800余倍。其中,食品生产服务损失占总损失价值的77.1%,远高于一般近海溢油事故对人类的生产生活的影响。研究结果可为C9等有毒物质泄漏造成的海湾生态系统服务损失评估提供参考,为政府决策和国土空间规划提供依据。     

Antacid increases survival of Vibrio vulnificus and Vibrio vulnificus phage in a gastrointestinal model.

Viable counts of three strains of Vibrio vulnificus and its phage were determined during exposure to a mechanical gastrointestinal model with or without antacid for 9 h at 37 degrees C. V. vulnificus was eliminated (>4-log reduction) within 30 min in the gastric compartment (pH decline from 5.0 to 3.5). Viable V. vulnificus cells delivered from the gastric compartment during the first 30 min of exposure reached 10(6) to 10(8) CFU/ml in the intestinal compartment after 9 h (pH 7.0). Phages were eliminated within 45 min in the gastric compartment (pH decline from 5.1 to 2.5). Less than a 2-log reduction of phage was observed in the intestinal compartment after 9 h (pH 7.0). When the gastric compartment contained antacid V. vulnificus counts decreased slightly (<2 log) during 2 h of exposure (pH decline from 7.7 to 6.0), while counts in the intestinal compartment (pH 7.5) reached 10(7) to 10(9) CFU/ml. Phage numbers decreased 1 log after 2 h in the gastric compartment (pH decline from 7.7 to 5.7) containing antacid and decreased 1 log in the intestinal compartment (pH 7.6) after 9 h. Presence of antacid in the gastric compartment of the model greatly increased the ability of both V. vulnificus and its phage to survive simulated gastrointestinal transit and may be a factor involved with oyster-associated illness.     

Viability of Vibrio vulnificus in Association with Hemocytes of the American Oyster (Crassostrea virginica)

Certain indigenous estuarine bacteria, such as Vibrio vulnificus, may cause opportunistic human infections after consumption of raw oysters or exposure of tissues to seawater. V. vulnificus is known to be closely associated with oyster (Crassostrea virginica) tissues and is not removed by controlled purification methods, such as UV light-assisted depuration. In fact, when live shellfish are subjected to controlled purification, the number of V. vulnificus cells can markedly increase. A review of previous studies showed that few workers have examined mechanisms in oysters which may influence the persistence of V. vulnificus in shellfish, such as the fate of V. vulnificus following phagocytosis by molluscan hemocytes. The objectives of this study were to define the intracellular viability and extracellular viability of V. vulnificus during the phagocytic process and to study the release of specific lysosomal enzymes. The viability of a virulent estuarine V. vulnificus isolate with opaque morphology was compared with the viability of a translucent, nonvirulent form, the viability of Vibrio cholerae, and the viability of Escherichia coli in phagocytosis experiments. Our results showed that the levels of phagocytosis and bactericidal degradation of the opaque V. vulnificus isolate were less than the levels of phagocytosis and bactericial degradation of the translucent morphotype. These findings indicate that encapsulation may contribute to resistance to ingestion and degradation by hemocytes. The rates of intracellular death of V. cholerae and E. coli exceeded the rate of intracellular death of the opaque V. vulnificus isolate, even though the ingestion or uptake rates did not differ significantly. The levels of lysozyme activity and acid phosphatase activity were not significantly different in hemocyte monolayers inoculated with V. vulnificus.     

Ozone depuration of Vibrio vulnificus from the southern quahog clam, Mercenaria campechiensis

Southern quahog clams, Mercenaria campechiensis, were dosed with Vibrio vulnificus and placed in a pilot-scale depuration system using ozonated recirculated artificial seawater. Twenty-four hours of treatment with ozone-treated recirculating artificial seawater reduced the numbers of V. vulnificus in the shellfish meats by an average of 2 log units when compared to natural die-off in control clams. The oxidant levels (up to 3 mg/liter) did not adversely affect shellfish pumping during the depuration process.     

Detecting potentially virulent Vibrio vulnificus strains in raw oysters by quantitative loop-mediated isothermal amplification

Vibrio vulnificus is a leading cause of seafood-related deaths in the United States. Sequence variations in the virulence-correlated gene (vcg) have been used to distinguish between clinical and environmental V. vulnificus strains, with a strong association between clinical ones and the C sequence variant (vcgC). In this study, vcgC was selected as the target to design a loop-mediated isothermal amplification (LAMP) assay for the rapid, sensitive, specific, and quantitative detection of potentially virulent V. vulnificus strains in raw oysters. No false-positive or false-negative results were generated among the 125 bacterial strains used to evaluate assay specificity. The detection limit was 5.4 CFU per reaction for a virulent V. vulnificus strain (ATCC 33815) in pure culture, 100-fold more sensitive than that of PCR. In spiked raw oysters, the assay was capable of detecting 2.5 × 10(3) CFU/g of V. vulnificus ATCC 33815, while showing negative results for a nonvirulent V. vulnificus strain (515-4c2) spiked at 10(7) CFU/g. After 6 h of enrichment, the LAMP assay could detect 1 CFU/g of the virulent V. vulnificus strain ATCC 33815. Standard curves generated in pure culture and spiked oysters suggested a good linear relationship between cell numbers of the virulent V. vulnificus strain and turbidity signals. In conclusion, the LAMP assay developed in this study could quantitatively detect potentially virulent V. vulnificus in raw oysters with high speed, specificity, and sensitivity, which may facilitate better control of V. vulnificus risks associated with raw oyster consumption.     

Isolation and Characterization of Vibrio vulnificus from Two Florida Estuaries

Vibrio vulnificus was enumerated in seawater and shellfish from two Florida estuaries at selected seasonal intervals. There were significant fluctuations in the presence and numbers of V. vulnificus. Relatively high seawater temperature and salinity favored the presence of V. vulnificus in both seawater and shellfish samples.