Human Fatalities from Cyanobacteria: Chemical and Biological Evidence for Cyanotoxins.An outbreak of acute liver failure Acute liver failure is the appearance of severe complications rapidly after the first signs of liver disease (such as jaundice), and indicates that the liver has sustained severe damage (loss of function of 80-90% of liver cells). occurred at a dialysis center in Caruaru, Brazil (8 [degrees] 17' S, 35 [degrees] 58' W), 134 km from Recife, the state capital of Pernambuco Pernambuco (pərnəmb  `k ), state (1991 pop. 7,127,855), 37,946 sq mi (98,280 sq km), NE Brazil, on the Atlantic Ocean. . At the clinic, 116
(89%) of 131 patients experienced visual disturbances, nausea, and
vomiting after routine hemodialysis treatment on 13-20 February 1996.
Subsequently, 100 patients developed acute liver failure, and of these
76 died. As of December 1996, 52 of the deaths could be attributed to a
common syndrome now called Caruaru syndrome. Examination of
phytoplankton phytoplanktonFlora of freely floating, often minute organisms that drift with water currents. Like land vegetation, phytoplankton uses carbon dioxide, releases oxygen, and converts minerals to a form animals can use. from the dialysis clinic's water source, analyses of the clinic's water treatment system, plus serum and liver tissue of clinic patients led to the identification of two groups of cyanobacterial toxins, the hepatotoxic hep·a·to·tox·ic adj. Damaging or destructive to the liver. hepatotoxic causing liver damage. cyclic peptide microcystins and the hepatotoxic alkaloid cylindrospermopsin. Comparison of victims' symptoms and pathology using animal studies of these two cyanotoxins leads us to conclude that the major contributing factor to death of the dialyses patients was intravenous exposure to microcystins, specifically microcystin-YR, -LR, and -AR. From liver concentrations and exposure volumes, it was estimated that 19.5 [micro]g/L microcystin was in the water used for dialysis treatments. This is 19.5 times the level set as a guideline for safe drinking water supplies by the World Health Organization. Key words: cyanobacteria cyanobacteria (sī'ənōbăktĭr`ēə, sī-ăn'ō–) or blue-green algae, photosynthetic bacteria that contain chlorophyll. , cyanotoxins, cylindrospermopsins, microcystins, toxins. Environ Health Perspect 109:663-668 (2001). [Online 20 June 2001] http://ehpnet1.niehs.nih.gov/docs/2001/109p663-668carmichael/abstract.html Poisonings by waterblooms of toxic cyanobacteria (cyanobacteria toxin poisonings; CTP CTP (cytidine triphosphate): see cytosine. (1) (Computer-To-Plate) The production of printing plates directly from the computer without requiring film as an intermediate step. ) are a significant part of the concern over harmful algal blooms (1-4). The toxins, called cyanotoxins, are responsible for intermittent but repeated widespread poisonings of wild and domestic animals and aquacultured fish. Cyanotoxins include neurotoxic neurotoxic pertaining to or emanating from a neurotoxin. neurotoxic state a case of poisoning by a neurotoxin. neurotoxic adjective anatoxin-a and anatoxin-a(s), paralytic paralytic /par·a·lyt·ic/ (par?ah-lit´ik) 1. affected with or pertaining to paralysis. 2. a person affected with paralysis. par·a·lyt·ic adj. 1. shellfish poisons (PSP (PlayStation Portable) See PlayStation. ; saxitoxin saxitoxin /saxi·tox·in/ (sak´si-tok?sin) a powerful neurotoxin synthesized and secreted by certain dinoflagellates, which accumulates in the tissues of shellfish feeding on the dinoflagellates and may cause a severe toxic reaction in and analogues), and hepatotoxic microcystins, nodularins, and cylindrospermopsins (1). Human poisonings have, in the past, been suspected but not confirmed due to a lack of information regarding vectors or circumstances that would confirm the presence of cyanotoxins in human food or water supplies, plus a shortage of appropriate methods of detection. Because most CTP occur only when waterblooms accumulate as thick surface scums, humans do not experience acute intoxication because they generally avoid contact with such high cell concentrations. In addition, drinking water supplies usually receive a degree of treatment that prevents high concentrations of cyanotoxins from being present. This spares humans from severe poisoning episodes by the oral route. However, the oral route of exposure is not the only one possible for humans. This article provides biological and chemical evidence for the first documented lethality to humans from cyanobacterial hepatotoxins, occurring via the intravenous route, in a dialysis clinic in the city of Caruaru, Brazil, during 1996. Caruaru is a city of about 350,000 people 2 hr west of Recife, the capital of the Brazilian state of Pernambuco. Two renal dialysis centers (A and B) serve the population, with center A receiving water from the city's water treatment plant, which is delivered by truck. Center B obtains reticulated reticulated /re·tic·u·lat·ed/ (-lat?ed) reticular. reticulated reticular. water from the city's water treatment plant. Beginning on 13 February 1996, center A patients receiving routine renal dialysis treatment began to complain of headache, eye pain, blurred vision, nausea, and vomiting. The first patient died suddenly on 20 February at center A. Fifty-one patients died by the middle of April, and a total of 76 deaths were reported in the course of our studies, which ended in October 1997. Through the cooperation of health and medical authorities in Pernambuco and the Centers for Disease Control (CDC See Control Data, century date change and Back Orifice. CDC - Control Data Corporation ) in Atlanta, Georgia, we obtained liver samples from 52 of these 76 victims. From these case reports, a pattern of disease was described that is now referred to as Caruaru syndrome. Caruaru syndrome is characterized by painful, extreme hepatomegaly hepatomegaly /hep·a·to·meg·a·ly/ (hep?ah-to-meg´ah-le) enlargement of the liver. hep·a·to·meg·a·ly n. The abnormal enlargement of the liver. Also called megalohepatia. , jaundice, and a bleeding diathesis manifested by ecchymosis ECCHYMOSIS, med. jur. Blackness. It is an extravasation of blood by rupture of capillary vessels, and hence it follows contusion; but it may exist, as in cases of scurvy, and other morbid conditions, without the latter. Ryan's Med. Jur. 172. , epistaxis epistaxis /ep·i·stax·is/ (-stak´sis) nosebleed; hemorrhage from the nose, usually due to rupture of small vessels overlying the anterior part of the cartilaginous nasal septum. ep·i·stax·is n. , and methrorrhagia; elevated transaminases, variable hyperbilirubinemia, prolonged prothrombin time, and severe hypertrigliceridemia; and disruption of liver plates, liver cell deformity, necrosis, apoptosis, cholestasis Cholestasis Definition Cholestasis is a condition caused by rapidly developing (acute) or long-term (chronic) interruption in the excretion of bile (a digestive fluid that helps the body process fat). , cytoplasmic vacuolization, mixed leukocyte leukocyte (l `kəsīt'): see blood. leukocyte or white blood cell or white corpuscle infiltration and multinucleated multinucleated characterized by having more than one nucleus per cell. multinucleated giant cell see giant cell. hepatocytes observed upon light microscopy and intracellular edema, mitochondrial mitochondrial pertaining to mitochondria. mitochondrial RNAs a unique set of tRNAs, mRNAs, rRNAs, transcribed from mitochondrial DNA by a mitochondrial-specific RNA polymerase, that account for about 4% of the total cell RNA that changes, rough and smooth endoplasmic endoplasmic pertaining to or arising from endoplasm. endoplasmic ribosomes small, cytoplasmic granules consisting of approximately 60% RNA and 40% protein. reticulum reticulum /re·tic·u·lum/ (re-tik´u-lum) pl. retic´ula [L.] 1. a small network, especially a protoplasmic network in cells. 2. reticular tissue. injuries, lipid vacuoles, and residual bodies observed upon electron microscopy (5-7). This outbreak received much attention from the media and public health authorities in Brazil and has been reported in many countries. The background of this case and a summary of the epidemiology have been published (6,7). Over the intervening period, we have examined the limnological lim·nol·o·gy n. The scientific study of the life and phenomena of fresh water, especially lakes and ponds. [Greek limn and case report data and analyzed most of the liver tissues provided and some of the serum samples. These results have allowed us to address some important questions regarding these human fatalities: What were the possible toxigenic toxigenic /tox·i·gen·ic/ (tok?si-jen´ik) 1. producing or elaborating toxins. 2. derived from or containing toxins. tox·i·gen·ic adj. Producing a poison; toxicogenic. cyanobacteria present in the reservoir that supplied water to Caruaru and the dialysis clinic? Which cyanotoxins were present, and at what concentrations? Were the concentrations of cyanotoxins present in the dialysis center high enough to produce liver failure and death? Materials and Methods Phytoplankton collections and identifications. Water treatment personnel were not doing phytoplankton counts or identification during the month of February 1996, and so samples of phytoplankton were not available from the time of the initial outbreak. Subsurface phytoplankton samples from Tabocas Reservoir (Caruaru water supply) were, however, collected retrospectively at the end of March 1996, identified, and quantified. Subsamples used for phytoplankton identification and quantification were preserved with Lugol's iodine solution. Direct counting of preserved cells was carried out with Utermohl's counting techniques using a counting chamber and inverted microscope. Analyses for cyanotoxins. Samples of carbon, sand, and cation/anion exchange resin from the in-house filters at both clinics A and B were analyzed using a polyclonal antibody against the cyclic peptide hepatotoxins, the microcystins, in an enzyme-linked immunosorbant assay (ELISA ELISA (e-li´sah) Enzyme-Linked Immuno-Sorbent Assay; any enzyme immunoassay using an enzyme-labeled immunoreactant and an immunosorbent. ELISA n. ) (8,9). This antibody was raised against microcystin-LR but cross-reacts with many of the known microcystin analogues. Blood sera and liver from affected and control patients provided by state health personnel in Pernambuco and sent through the CDC were also examined by ELISA (see tissue extraction method, below). Samples of carbon, cation cation (kăt'ī`ən), atom or group of atoms carrying a positive charge. The charge results because there are more protons than electrons in the cation. and anion exchange resin, and sand from clinic A and carbon and sand from clinic B were extracted 3 times with 10 volumes of 100% methanol for 12 hr. Extracts were dried and resuspended in distilled water and applied to C 18 cartridges (6 mg). Deionized water and 20 and 100% methanol eluates were collected and dried. The 100% methanol extracts (both filter and tissue extracts) were resuspended in 1:1 methanol/[H.sub.2]O and diluted [10.sup.-1], [10.sup.-2], and [10.sup.-3] with phosphate-buffered saline and assayed by ELISA. We used 52 liver samples representing 39 victims (covering February-December 1996) in our analyses (13 replicate samples were also analyzed). Liver samples were homogenized ho·mog·e·nize v. ho·mog·e·nized, ho·mog·e·niz·ing, ho·mog·e·niz·es v.tr. 1. To make homogeneous. 2. a. To reduce to particles and disperse throughout a fluid. b. in 100% methanol (2 times over 24 hr) using a volume of 10 mL for liver [is less than] 1 g and 10 mL/g for tissue [is greater than] 1 g. Extracts were centrifuged at 7000 x g. Methanol supernatants were combined and mixed with a 3-times volume of hexane hexane /hex·ane/ (hek´san) a saturated hydrogen obtained by distillation from petroleum. hex·ane n. . The hexane layer was discarded and the methanol extract was placed in 40 mL distilled water and applied to C18 silica cartridges. Water and 20 and 100% methanol eluates were collected. The 100% methanol extracts were dried, resuspended in 1:1 methanol/[H.sub.2]O, and diluted [10.sup.-1], [10.sup.-2], and [10.sup.-3] with phosphate-buffered saline and assayed by ELISA. We used 17 serum samples representing 12 victims in our analyses reported here. Serum samples (200 [micro]L-1.0 mL) were diluted 4 times with double-distilled [H.sub.2]O, and the diluted serum was loaded onto a C 18 silica cartridge. The C 18 cartridge was processed as described above for liver samples and assayed by ELISA. We obtained control liver samples from five persons from the pathology unit at the Federal University of Pernambuco. These samples represented persons not associated with dialysis treatment in Caruaru. Control sera (n = 12) were from volunteer health personnel in Caruaru, Recife, and Atlanta. These samples were extracted for analyses in the same way as victim samples were. Chemical analyses for microcystins in liver and serum samples were done by ELISA-guided HPLC-photodiode array (PDA (Personal Digital Assistant) A handheld computer for managing contacts, appointments and tasks. It typically includes a name and address database, calendar, to-do list and note taker, which are the functions in a personal information manager (see PIM). ) separation of microcystins from liver tissues. HPLC HPLC high-performance liquid chromatography. HPLC high performance liquid chromatography. HPLC High-performance liquid chromatography Lab instrumentation A highly sensitive analytic method in which analytes are placed chromatograms were obtained on a Waters 2690 Millennium system (Waters, Milford, MA, USA). HPLC column conditions were: column, Waters [micro] Bondapak C18, 3.9 x 300 mm; mobile phase, isocratic-60% methanol/40% 0.05% trifluoroacetic acid; flow rate, 1 mL/min, Waters 996 PDA detector. The separated microcystins were further analyzed by matrix-assisted laser desorption Desorption A process in which atomic and molecular species residing on the surface of a solid leave the surface and enter the surrounding gas or vacuum. ionization/time of flight (MALDI/TOF) and electrospray ionization (ESI (Edge Side Includes) A markup language for Web pages that enables elements of a Web page to be dynamically assembled in servers distributed throughout the Internet. ) mass spectrometry (MS). MALDI MALDI Matrix-Assisted Laser Desorption/Ionization spectra were acquired on a VG TofSpec mass spectrometer (VG Analytical Fisons Instruments, Manchester, UK) in the linear mode, using a 337 nm [N.sub.2] laser. The MALDI/TOF ionization method has emerged as a powerful analytical method (10), with a high sensitivity and tolerance for small amounts of salt and buffer that allow low-level detection of analyses (sub-femto-mole) in complex mixtures. The thin-film coating method was used in these analyses (11). ESI spectra were acquired on a VG Quattro mass spectrometer (VG Biotech, Fisons, Manchester, UK). Cesium chloride was used for the calibration. During the time in which microcystins were being analyzed, it became apparent that we should also examine the samples for other cyanotoxins. After the first analyses for microcystins, other studies demonstrated a wide occurrence of Cylindrospermopsis (Anabaenopsis) in Brazil. Because this cyanobacterium cy·a·no·bac·te·ri·um n. pl. cy·a·no·bac·te·ri·a A photosynthetic bacterium of the class Coccogoneae or Hormogoneae, generally blue-green in color and in some species capable of nitrogen fixation. is capable of producing the alkaloid hepatotoxin hepatotoxin /hep·a·to·tox·in/ (hep´ah-to-tok?sin) a toxin that destroys liver cells.hep´atotoxic hep·a·to·tox·in n. A toxin that is destructive to liver parenchyma. cylindrospermopsin (CYN CYN Canyon ) and deoxy-cylindrospermopsin (deoxy-CYN), analyses for this cyanotoxin were begun in 1998. For CYN/deoxy-CYN analysis of sand, carbon, and ion exchange resins, methanolic extracts (5 g of sample in 20 mL of 100% methanol) were dried under nitrogen gas and the residue taken up in 1:5 methanol/[H.sub.2]O. Due to limited amounts of liver and sera for a given victim, extracts for CYN analyses were the same as those used for microcystin (MCYST) analyses. This extract was filtered and dilutions performed as needed to maintain a response in the linear range of the calibration curve. Analyses were by HPLC/MS/MS using a PE/Sciex API 300 mass spectrometer with turbo-ion spray interface coupled to a Perkin Elmer series 200 HPLC system (Applied Biosystems, Foster City, CA, USA). HPLC separation was achieved on a 150 x 4.6 mm Alltima C18 column (Alltech Associates, Sydney, Australia) run at 35 [degrees] C. The effluent was split to achieve a flow rate of 0.25 mL/min to the MS. The MS was operated in the multiple-reaction monitoring mode using nitrogen gas as the collision gas. The transition 416.2 to 194 Da was used to determine CYN concentration, and the transition 400.2 to 194 Da was used for deoxy-CYN. The limit of detection with the method was 0.01 ng/g (12). Results Phytoplankton analyses. Analysis of phytoplankton from the Tabocas Reservoir at the end of March 1996 demonstrated that toxigenic cyanobacteria were the main phytoplanktic group, representing 99% of the total density of phytoplankton. The average number of cyanobacterial organisms was 24,500/mL (Table 1). Some cyanobacterial picoplanktonic strains isolated from water samples of Tabocas Reservoir after the outbreak were identified as MCYST producers by HPLC and ELISA (13). However, because the water utility was not making phytoplankton counts at the time of the outbreak, toxic cyanobacteria producing microcystin or other cyanotoxins during the period of intoxication could not be examined. An evaluation of previous years' phytoplankton data showed that cyanobacteria were dominant in the reservoir during the summer months since at least 1990 (Figure 1). The most common genera during this time period were Microcystis, Anabaena Anabaena Genus of blue-green algae (cyanobacteria). Found as plankton in shallow water and on moist soil, they occur in both solitary and colonial forms and are capable of nitrogen fixation. , and Anabaenopsis (Cylindrospermopsis). Other studies confirm that toxic cyanobacteria, especially Cylindrospermopsis, are present in other Brazilian water supplies (14-16). Microcystis and Anabaena are known producers of microcystins, while Cylindrospermopsis can produce cylindrospermopsin. For this reason we analyzed samples for these two cyanotoxins. Although the literature reports the neurotoxins anatoxin-a and a(s) to be produced by Anabaena and certain PSPs to be produced by Cylindrospermopsis (3), the lack of reported neurotoxic symptoms in most of the Caruaru victims meant that these toxins were not likely present and therefore we did not analyze samples for those toxins.
Table 1. Phytoplankton counts from Tabocas Reservoir.
Cyanobacteria/mL
Samples from reservoir, Total (% of total
March 1996 phytoplankton/mL phytoplankton)
Center 40,000 39,731 (99.3)
Margin 13,190 13,100 (99.3)
Raw water impounded to water
treatment plant 21,420 20,882 (97.5)
Analyses for cyanotoxins. Examination of carbon, sand, and cation/anion resin exchange filters from the clinic using a polyclonal antibody in an ELISA against microcystin-LR showed microcystin in the microgram microgram /mi·cro·gram/ (µg) (mi´kro-gram) one millionth (10-6) of a gram. mi·cro·gram n. Abbr. per gram range (Table 2). Further examination of methanolic extracts from these carbon, sand, and resins performed by HPLC-electrospray MS/MS MS/MS Tandem Mass Spectroscopy MS/MS Multistage Mass Spectrometry provided chemical evidence for CYN contamination in this material. The highest concentration of this hepatotoxic alkaloid was found in the carbon extract (Table 2).
Table 2. Microcystin (by ELISA) and cylindrospermopsin (by LC/MS/MS)
content of carbon, ion-exchange resin, and sand filters from
dialysis centers A and B in Caruaru, Brazil.
Center/sample source Microcystin Cylindrospermopsin
([micro]g/g) ([micro]g/g)
Center A, carbon 1.0 19.70
Center A, anion resin 0.5 0.02
Center A, cation resin 2.1 0.05
Center A, sand ND ND
Center B, carbon 3.4 ND
Center B, sand ND ND
ND, not detected.
Blood sera and liver from affected and control patients provided by state health officials in Pernambuco and sent through the CDC were examined by ELISA. All patient sera and tissue were positive for microcystins (Table 3). ELISA-guided HPLC-PDA separation of microcystins from liver tissues provided a profile of microcystins present (Figure 2). MALDI/TOF (Figure 3) and ESI (Table 4) MS analysis were used to identify isolated microcystins from liver. Microcystins identified were microcystins-YR, -LR, and -AR. MALDI MS analysis of finished water from dialysis center B also showed the presence of these microcystins (data not shown). [GRAPHS OMITTED]
Table 3. Microcystin values, by ELISA, of liver and serum from
Caruaru dialysis patients.
No. of victims/ Mean microcystin
no. of samples (ng/g)
Month of death (1996)
February 4/7 257.7
March 11/14 255.4
April 8/12 179.6
May 3/4 272.5
July 1/1 471.8
August 4/6 216.8
September 3/3 219.9
October 2/2 50.2
December 1/1 160.4
Patients without date
of death 2/2 145.9
Total no. patients/
no. samples 39/52 223
Mean of serum values(a) 12/17 2.2 (ng/mL)
(a) Values from victims who died and who also had positive liver
values.
Table 4. ESI MS fragment ions from a liver analy-
sis for microcystins.
m/z Fragment ions(a)
135 Ph[CH.sub.2]CH[(OMe).sup.+]
155 [[Mdha-Ala + H].sup.+]
238 [[Co-Glu-Mdha-2H].sup.+]
(a) These fragment ions are characteristic for microcystins
with m/z 135 representing a key fragment ion (Adda)
used in microcystin screening (34,35). ESI MS was
unable to determine the structure of the microcystins
present, probably due to interference by salts in the
extracts, but it did confirm their presence.
Analysis of liver samples for CYN by HPLC-MS/MS did not reveal the parent compound at molecular mass 416 (M+H). These liver extracts had been prepared for MCYST analyses, and the method may not have selected for the more polar alkaloid CYN. Due to limited sample availability, further analyses of remaining liver tissue and sera for CYN is pending while a method is developed for detecting this cyanotoxin in these matrices. Calculation of microcystin exposure. The average microcystin value in 52 liver samples from 39 victims who died from February to December 1996 was 223 ng/g (Table 3). This compares well with values reported in laboratory test animals receiving acute exposure of microcystin-LR (17). ELISA detected 125 ng/g of microcystin-LR in the livers of mice exposed to a lethal intraperitoneal injection of 100 [micro]g/kg (18). We used the average liver concentration of 223 ng/g to estimate the amount of microcystin present in the source water from clinic A. Using an average liver weight for an adult human of 1,500 g gives 335 [micro]g of possible MCYST burden in an average liver from the Caruaru victims. We then used two correction factors that could affect the amount of MCYST in the source water. The first was the amount of MCYST in the liver as a percentage of the total exposure. Laboratory experiments indicate that from 10% to 90% of the total exposure can be found in the liver of mice and rats receiving an acute or lethal dose of MCYST (19,20). Therefore, an application factor of 2 (estimate of 50% uptake in the liver) was used. The second factor was based on the finding that since microcystin is covalently bound to protein phosphatase 1 and protein phosphatase 2A, as much as 80% of the MCYST exposure might not be recognized by the ELISA assay (21,22). Although this estimate is conservative, it means that the MCYST exposure might have been about 7 times higher (2 times and 5 times, respectively). Using this value and dividing by the amount of water used during a typical dialysis treatment (120 L), and assuming 100% dialysis of MCYST across the hollow fiber dialysis filter gives an estimated concentration in the source water of 19.5 [micro]g/L. Although there are several assumptions in estimating this value, it does mean that an environmentally feasible level of MCYST in the source water would have been adequate to cause acute liver failure and death in humans by the intravenous route. If this concentration of MCYST is an accurate estimate, then there was no significant contribution to the toxicity from CYN. This MCYST value is about 20 times higher than the 1 [micro]g/L proposed by the World Health Organization as a safe level for oral consumption of MCYST in drinking water (23). Histology and pathology of liver tissues revealed a pattern of liver plate disruption identical to that found in previous laboratory animal experiments of microcystin exposure (5,24-263. MCYSTs are potent inhibitors of eukaryotic eukaryotic /eu·kary·ot·ic/ (u?kar-e-ot´ik) pertaining to a eukaryon or to a eukaryote. eukaryotic pertaining to eukaryosis. eukaryotic cells see cell. protein serine/threonine phosphatases 1 and 2A (27,28). Substances that inhibit these protein phosphatases are considered to be nonphorbal ester-type tumor promoters (29,30). This means that survivors of Caruaru syndrome could be at higher risk for liver cancer and should be monitored (3); however, the degree to which CYN contributed to the deaths of the dialysis patients is less clear. Until we can evaluate whether CYN is present in the victims' livers, we cannot estimate the possible toxicity due to this cyanotoxin. CYN is a hepatotoxic alkaloid first studied from Australian water supplies. In a retrospective study it has been held as the cause of hepatoenteropathy and renal damage to 148 indigenous peoples using an Australian water supply (31). Comparison of the Caruaru victims' livers with published studies in animals dosed with CYN did not reveal a pattern indicating that this toxin contributed to the toxicity. Because the victims in Caruaru were undergoing renal dialysis, we cannot evaluate whether CYN contributed to renal toxicity. A better understanding of CYN toxicology and biochemistry, both alone and in combination with MCYST, is needed before we can confirm (or rule out) a contributing toxicity factor from this toxin. Discussion The available biological and chemical evidence supports cyanotoxins from the Tabocas Reservoir water supply as being the major factor in the deaths of dialysis patients at clinic A. One important question was how could lethal levels of MCYST (and possibly CYN) be present in waters receiving standard water treatment procedures including sedimentation, coagulation coagulation (kōăg'y lā`shən), the collecting into a mass of minute particles of a solid dispersed throughout a liquid (a sol), usually followed by the precipitation or , filtration, and chlorination chlorination Public health Addition of chlorinated compounds to drinking water as disinfectants. Cf Ozonation. ? The answer is that center A
did not have water directly piped to its facility. Instead, they relied
on water that was trucked to the center for treatment in its in-house
water system--a process that involved sand filtration, carbon
filtration, and cation/anion exchange filtration, followed by a micro
filter. Because removal of chlorine residues was poor, due most likely
to inadequate maintenance of the dialysis center in-house water
treatment system, center A maintenance staff used water from the
city's water treatment system that had received only alum
floculation in order to avoid chlorine residues in the dialysis
treatment water. This water, without the full benefit of water
treatment, contained high levels of cyanotoxins that were not removed by
the small, inadequately maintained, in-house treatment facility of
dialysis center A. This center did not use reverse osmosis in its water
treatment process (32,33). Reverse osmosis is used in several dialysis
centers in Brazil and in the United States and Europe. We conclude that
if reverse osmosis had been used, cyanotoxins would have been less
likely to pass through the filtration process.A newer dialysis center (center B) is also present in Caruaru. Center B received water piped from the municipal water plant that is fully treated, except for carbon filtration. No fatalities that could be contributed to Caruaru syndrome occurred at this center. However, several patients at center B were reported to have some symptoms of Caruaru syndrome after the center used trucked water delivered at the end of March. MCYST was identified in the filter system of center B (Table 2) and patients symptomatic for Caruaru syndrome had MCYST in their serum. One of the questions we have not been able to address is the possibility of repeated exposure to these cyanotoxins. It was not until 7 March 1996, 15 days after the first death, that center A was closed and dialysis patients were sent to other center. Some of these patients were sent to center B, where there was also evidence of exposure to cyanotoxins. Therefore it is possible that multiple exposures occurred. This makes it difficult to establish a dose-response effect. However, we do think that most of the exposure to cyanotoxins came from one or two shipments to center A, and we estimate that the primary exposure to cyanotoxins was due to one to three dialysis treatments. Another important question is whether there may have been some type of treatment that could have removed or detoxified the exposure from cyanotoxins that these dialysis patients experienced. Although there is no treatment for MCYST or CYN exposure, another study treated one clinic A patient with charcoal hemoperfusion (7). Serum analyses of the victim before and after hemoperfusion showed a reduction of MCYST levels, as measured by HPLC-photodiode array detector and ELISA, but levels rose after treatment, and the patient died about 1 week after the charcoal hemoperfusion. Liver samples from this victim were analyzed in our study, and the level was 250 and 430 ng/g (two separate liver samples). We have learned significant information concerning human exposure from MCYST and CYN in this first confirmed outbreak of human poisoning involving cyanotoxins. Because many of the world's reservoir- and lake-based water supplies are subject to increasing levels of nutrients, it is highly probable that repeat episodes of cyanotoxin poisoning will occur unless measures are taken to better understand their role in water-based disease. These measures should consist of programs for watershed management to reduce nutrient inputs, cyanotoxin monitoring programs to alert authorities to the presence of cyanotoxins, and improvements in water treatment techniques to reduce or to remove cyanotoxins from potable water supplies. REFERENCES AND NOTES (1.) Carmichael WW. The cyanotoxins. In: Advances in Botanical Research, Vol 27 (Callow J, ed). London: Academic Press, 1997;211-256. (2.) Hallegraeff GM, Anderson DM, Cembella AD, eds. Manual on Harmful Marine Microalgae. Paris:UNESCO UNESCO: see United Nations Educational, Scientific, and Cultural Organization. UNESCO in full United Nations Educational, Scientific and Cultural Organization , 1995. (3.) Chorus I, Bartram J, eds. Toxic Cyanobacteria in Water: A Guide to their Public Health Consequences, Monitoring and Management. London:E&FN Sport, 1999. (4.) Ressom R, Soong FS, Fitzgerald J, Turczynowicz L, El Saadi O, Roder D, Maynard T, Falconer I, eds. Health Effects of Toxic Cyanobacteria (blue-green algae) Canberra, Australia:Australian Government Public Service, 1994. (5.) Barreto V, Lira V, Figueiredo J, Fittipaldi H Jr, Juca N, Gayotto LC, Raposso F, Barbosa J, Holmes C, Cardo C, et al. Caruaru syndrome-a previously undescribed form of acute toxic liver disease in humans caused by microcystin-LR with a high lethality rate [Abstract]. Hepatology 24:244 (1996). (6.) Jochimsen EM, Carmichael WW, An J, Denise MC, Cookson ST, Holmes CEM CEM contagious equine metritis. CEM selective medium chocolate agar made with Eugon agar and 5% horse blood; used to cultivate Taylorella equigenitalis. , Antunes MBC (Multimedia Benchmark Committee) A graphics benchmark that provides MPEG-2 and other tests. See GPC. , Melo FDA FDA abbr. Food and Drug Administration FDA, n.pr See Food and Drug Administration. FDA, n.pr the abbreviation for the Food and Drug Administration. , Lyra TM, Barreto VST, et al. Liver failure and death after exposure to microcystins at a hemodialysis center in Brazil. N Engl J Med 338(13):873-878 (1998). (7.) Pouria S, Andrade A, Barbosa J, Cavalcanti RL, Barreto VST, Ward CJ, Preiser W, Poon GK, Neild CH, Codd GA. Fatal microcystin intoxication in haemodialysis Noun 1. haemodialysis - dialysis of the blood to remove toxic substances or metabolic wastes from the bloodstream; used in the case of kidney failure hemodialysis unit in Caruaru, Brazil. Lancet 352:21-26 (1998). (8.) Chu FS, Huang X, Wei RD. Enzyme-linked immunosorbent assay enzyme-linked immunosorbent assay n. ELISA. Enzyme-linked immunosorbent assay (ELISA) A diagnostic blood test used to screen patients for AIDS or other viruses. for microcystins in blue-green algal blooms. J Assoc Off Anal Chem 73:451-456 (1990). (9.) An J-S, Carmichael WW. Use of a colorimetric col·or·im·e·ter n. 1. Any of various instruments used to determine or specify colors, as by comparison with spectroscopic or visual standards. 2. protein phosphatase inhibition assay and enzyme-linked immunosorbent assay for the study of microcystins and nodularins. Toxicon 32:1495-1507 (1994). (10.) Hillenkamp F, Karas M. Matrix-assisted laser desorption/ionization Matrix-assisted laser desorption/ionization (MALDI) is a soft ionization technique used in mass spectrometry, allowing the analysis of biomolecules (biopolymers such as proteins, peptides and sugars) and large organic molecules (such as polymers, dendrimers and other mass spectrometry of biopolymers. Anal Chem 63:1193A-1203A (1991). (11.) Vorm O, Roepstorff P, Mann M. Improved resolution and very high sensitivity in MALDI-TOF MALDI-TOF Matrix Assisted Laser Desorption Ionization - Time of Flight of matrix surfaces made by fast evaporation. Anal Chem 66:3281-3287 (1994). (12.) Eaglesham GK, Norris RL, Shaw GR, Smith M J, Chiswell RK, Davis BC, Neville GR, Seawright AA, Moore RR. Use of HPLC-MS/MS to monitor cylindrospermopsin, a blue-green algal algal pertaining to or caused by algae. algal infection is very rare but systemic and udder infections are recorded. See protothecosis. algal mastitis the algae Prototheca trispora and P. toxin, for public health purposes. Environ Toxicol 14:151-154 (1999). (13.) Domingos P, Rubim KT, Molica RJR, Azevedo SMFO SMFO Single Mode Fiber Optics , Carmichael WW. First report of microcystin production by picoplanktonic cyanobacterial isolated from northeast Brazilian drinking water supply. Environ Toxicol 14(1):31-35 (1999). (14.) Azevedo MFO MFO Mixed function oxidase, see there , Evans WR, Carmichael WW, Namikoshi M. First report of microcystins from a Brazilian isolate of the cyanobacterium Microcystis aeruginosa. J Appl Phycol 6:261-265 (1994). (15.) Hirooka EY, Pinotti MHP, Tsutsumi T, Yoshida F, Ueno Y. Survey of microcystins in water between 1995 and 1996 in Parana, Brazil using ELISA. Nat Toxins 7:103-109 (1999). (16.) Bouvy M, Falcao D, Marinho M, Pagano M, Moura A. Occurrence of cylindrospermopsis (cyanobacteria) in 39 Brazilian tropical reservoirs during the 1998 drought. Aquat Microbiol Ecol 23:13-27 (2000). (17.) Lin J-R, Chu FS. Kinetics of distribution of microcystin-LR in serum and liver cytosol cytosol /cy·to·sol/ (sit´ah-sol) the liquid medium of the cytoplasm, i.e., cytoplasm minus organelles and nonmembranous insoluble components.cytosol´ic cy·to·sol n. of mice: an immunochemical im·mu·no·chem·is·try n. The chemistry of immunologic phenomena, as of antigen-antibody reactions. im analysis. Am Chem Soc 94:1035-1040 (1994). (18.) Carmichael WW, An JS. Unpublished data. (19.) Robinson NA, Miura GA, Matson CF, Dinterman RF, Pace JG. Characterization of chemically tritiated Trit´i`at`ed a. 1. (Chem.) containing tritium; - of chemical compounds; as, tritiated thymine s>. microcsytin-LR and its distribution in mice. Toxicon 27:1035-1042 (1989). (20.) Runnegar MTC mtc - A Modula-2 to C translator. ftp://rusmv1.rus.uni-stuttgart.de/soft/Unixtools/compilerbau/mtc.tar.Z. , Falconer IR. Effect of toxin from the cyanobacterium Microcystis aeruginosa on ultrastructure ultrastructure /ul·tra·struc·ture/ (-struk?chur) the structure beyond the resolution power of the light microscope, i.e., visible only under the ultramicroscope and electron microscope. morphology and actin polymerization in isolated hepatocytes. Toxicon 24:109-115 (1986). (21.) Robinson NA, Pace JG, Matson CF, Miura GA, Lawrence WB. Tissue distribution, excretion and hepatic biotransformation biotransformation /bio·trans·for·ma·tion/ (-trans?for-ma´shun) the series of chemical alterations of a compound (e.g., a drug) occurring within the body, as by enzymatic activity. of microcystin-LR in mice. J Pharmacol Exp Ther 256:176-181 (1991). (22.) Williams DE, Craig M, Dawe SC, Kent ML, Anderson RJ, Holmes CFB. 14C-Labeled microcystin-LR administered to Atlantic salmon via intraperitoneal injection provides in vivo evidence for covalent co·va·lent adj. Of or relating to a chemical bond characterized by one or more pairs of shared electrons. binding of microcystin-LR in salmon livers. Toxicon 35:985-989 (1997). (23.) WHO. Guidelines for Drinking Water Quality. 2nd ed. Addendum to Volume 1. Recommendations. Geneva Geneva, canton and city, Switzerland Geneva (jənē`və), Fr. Genève, canton (1990 pop. 373,019), 109 sq mi (282 sq km), SW Switzerland, surrounding the southwest tip of the Lake of Geneva. :World Health Organization, 1996. (24.) Runnegar MTC, Andrews J, Gerdes RG, Falconer IR. Injury to hepatocytes induced by a peptide toxin from the cyanobacterium Microcystis aeruginosa. Toxicon 25:1235-1239 (1987). (25.) Theiss WC, Carmichael WW, Wyman J, Bruner R. Blood pressure and hepatocellular effects of the cyclic heptapeptide toxin produced by Microcystis aeruginosa strain PCC-7820. Toxicon 26:603-613 (1988). (26.) Dabholkar AS, Carmichael VWV. Ultrastructural changes in the mouse liver induced by hepatotoxin from the freshwater cyanobacterium Microcystis aeruginosa strain 7820. Toxicon 25:285-292 (1987). (27.) Matsushima R, Yoshizawa S, Watanabe MF, Harada K-I, Furusawa M, Carmichael WW, Fujiki H. In vitro and in vive effects of protein phosphatase inhibitors, microcystin and nodularin, on mouse skin and fibroblasts Fibroblasts A type of cell found in connective tissue; produces collagen. Mentioned in: Skin Grafting . Biochem Biophys Res Comm 171:867-874 (1990). (28.) Mackintosh C, Beattie KA, Klumpp S, Cohen cohen or kohen (Hebrew: “priest”) Jewish priest descended from Zadok (a descendant of Aaron), priest at the First Temple of Jerusalem. The biblical priesthood was hereditary and male. P, Codd GA. Cyanobacterial microcystin-LR is a potent and specific inhibitor of protein phosphatases 1 and 2A from both mammals and higher plants. FEBS FEBS Federation of European Biochemical Societies Lett 264:189-192 (1990). (29.) Nishiwaki-Matsushima R, Ohta T, Nishiwaki S, Suganuma M, Kohyama K, Ishiwaki T, Carmichael W, Fujiki H. Liver tumor promotion by the cyanobacterial cyclic peptide toxin microcystin-LR. J Cancer Res Clin Oncol 118:420-424 (1992). (30.) Fujiki H, Sueoka E, Suganuma M. Carcinogenesis of microcystins. In: Toxic Microcystis (Watanabe MF, Harada K-I, Carmichael WW, Fujiki H, eds). Boca Raton, FL:CRC (Cyclical Redundancy Checking) An error checking technique used to ensure the accuracy of transmitting digital data. The transmitted messages are divided into predetermined lengths which, used as dividends, are divided by a fixed divisor. Press, 1996;203-232. (31.) Bourke ATC, Hawes RB, Neilson A, Stallman ND. An outbreak of hepato-enteritis (the Palm Island mystery disease) possibly caused by algal intoxication. Toxicon (suppl) 3:45-48 (1983). (32.) Ismail N, Becker BN, Hakim RM. Water treatment for hemodialysis. Am J Nephrol 16:60-72 (1996). (33.) Ronco C, Brendolan A, Crepaldi C. Hemodialysis: high efficiency treatments. In: Contemporary Issues in Nephrology, Vol 27 (Bosch JP, ed). New York:Churchill Livingston, 1993;11-61. (34.) Namikoshi M, Sun F, Choi BW, Rinehart KL, Carmichael WW, Evans WR, Beasley VR. Seven more microcystins from Homer Lake cells: application of the general method for structure assignment of peptides containing [Alpha], [Beta]-dehydroamino acid unit(s). J Org Chem 60:3671-3679. (35.) Rinehart KL, Namikoshi M, Choi BW. Structure and biosynthesis Biosynthesis The synthesis of more complex molecules from simpler ones in cells by a series of reactions mediated by enzymes. The overall economy and survival of the cell is governed by the interplay between the energy gained from the breakdown of compounds of toxins from blue-green algae (cyanobacteria). J Appl Phycol 6:159-176 (1994). Address correspondence to W.W. Carmichael, Department of Biological Sciences, Wright State University, 3640 Colonel Glen Highway, Wright State University, Dayton, OH 45435 USA. Telephone: (937) 775-3173. Fax: (937) 775-3320. E-mail: wayne.carmichael@wright.edu We thank F.S. Chu for helping to confirm ELISA analysis of serum. We also thank C. Holmes, D.M. Cardo, L.A. Carmichael, S.T. Cookson, W.R. Jarvis, M.B. de C. Antunes, D.A. de M. Filho, and T.M. Lyra for assistance with epidemiology, database management, specimen collection, and shipment. Partial support for specimen analysis was provided to W.W.C. by the Centers for Disease Control and Prevention Centers for Disease Control and Prevention (CDC), agency of the U.S. Public Health Service since 1973, with headquarters in Atlanta; it was established in 1946 as the Communicable Disease Center. . MALDI mass spectra were obtained on instruments supported by grants from the National Institute of General Medical Sciences The U.S. National Institute of General Medical Sciences is one of the National Institutes of Health (NIH), the principal biomedical research agency of the Federal Government. (GM 27029), the National Institutes of Health (RR 01575), and the National Science Foundation (PCM 8121494) to K.L.R. Received 16 August 2000; accepted 30 January 2001. Wayne W. Carmichael,(1) Sandra M.F.O. Azevedo,(2) Ji Si An,(1) Renato J. R. Molica,(3) Elise M. Jochimsen,(4) Sharon Lau,(5) Kenneth L. Rinehart,(5) Glen R. Shaw,(6) and Geoff K. Eaglesham(7) (1) Department of Biological Sciences, Wright State University, Dayton, Ohio, USA; (2) Instituto de Biofisica Carlos Chagas Filho Carlos Chagas Filho (b. September 19, 1910; d. February 16, 2000, Rio de Janeiro, Brazil) was a Brazilian physician, biologist and scientist active in the field of neuroscience. , Universidade do Brasil Universidade do Brasil was created on September 7, 1920, by President Epitácio Pessoa, in the city of Rio de Janeiro, the former capital district of Brazil. Initially it was named Universidade do Rio de Janeiro, then it was renamed Universidade do Brasil, on July 5, 1937. , Rio de Janeiro Rio de Janeiro, city, Brazil Rio de Janeiro (rē`ō də zhänā`rō, Port. rē` thĭ zhənĕē`r , Brasil; (3) Instituto
Technologico de Pernambuco, Recife, Brasil; (4) Hospital Infections
Program, National Center for Infectious Diseases, Centers for Disease
Control and Prevention, Atlanta, Georgia, USA; (5) Roger Adams
Laboratory, School of Chemical Sciences, University of Illinois University of Illinois may refer to:
Coopers Plains is named after Dr Henry Cowper. External links
|
|
Printer friendly
Cite/link
Email
Feedback
Reader Opinion