Application of powdered activated carbon for the adsorption of cylindrospermopsin and microcystin toxins from drinking water supplies

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Application of powdered activated carbon for the adsorption of cylindrospermopsin and microcystin toxins from drinking water supplies Lionel Ho a,b,*, Paul Lambling c, Heriberto Bustamante d, Phil Duker d, Gayle Newcombe a a

Australian Water Quality Centre, SA Water Corporation, 250 Victoria Square, Adelaide, SA 5000, Australia School of Earth and Environmental Sciences, The University of Adelaide, SA 5005, Australia c ´ Ecole Supe´rieure de Chimie Physique E´lectronique de Lyon, 43, Boulevard du 11 Novembre 1918, BP 2077, 69616 Villeurbanne Cedex, France d Sydney Water, PO Box 399, Parramatta NSW 2124, Australia b

article info

abstract

Article history:

Cylindrospermopsin (CYN) and microcystin are two potent toxins that can be produced by

Received 17 September 2010

cyanobacteria in drinking water supplies. This study investigated the application of

Received in revised form

powdered activated carbon (PAC) for the removal of these toxins under conditions that

8 March 2011

could be experienced in a water treatment plant. Two different PACs were evaluated for

Accepted 9 March 2011

their ability to remove CYN and four microcystin variants from various drinking water

Available online 17 March 2011

supplies. The removal of natural organic material by the PACs was also determined by measuring the levels of dissolved organic carbon and UV absorbance (at 254 nm). The PACs

Keywords:

effectively removed CYN and the microcystins from each of the waters studied, with one of

Adsorption

the PACs shown to be more effective, possibly due to its smaller particle diameter. No

Cylindrospermopsin (CYN)

difference in removal of the toxins was observed using PAC contact times of 30, 45 and

Microcystin

60 min. Furthermore, the effect of water quality on the removal of the toxins was minimal.

Natural organic material (NOM)

The microcystin variants were adsorbed in the order: MCRR > MCYR > MCLR > MCLA. CYN

Powdered activated carbon (PAC)

was found to be adsorbed similarly to MCRR. ª 2011 Elsevier Ltd. All rights reserved.

1.

Introduction

The microcystins and cylindrospermopsin (CYN) (see Fig. 1 for structures) are potent hepatotoxins produced by a number of species of freshwater cyanobacteria, of which Microcystis aeruginosa and Cylindrospermopsis raciborskii are two of the more commonly encountered. Consumption of waters containing these cyanobacterial toxins (cyanotoxins) can lead to serious health risk with events such as diarrhoea, nausea, vomiting and even death occurring (Falconer, 1989). The microcystins have also been implicated as promoters of liver tumours (Nishiwaki-Matsushima et al., 1992), while CYN has been

associated with serious tissue damage and cell necrosis in the liver, kidney and other organs (Falconer, 2005). In addition, studies have also suggested that CYN is carcinogenic, genotoxic and involved in the inhibition of protein synthesis (Froscio et al., 2001, 2003; Falconer, 2005). As a result of the concerns about the effect of microcystins, a guideline value of 1 mg L
1 for microcystin-LR (MCLR) in drinking water has been issued by the World Health Organisation (WHO). Similarly, the Australian Drinking Water Guideline value for microcystin has been set at 1.3 mg L
1 as MCLR toxicity equivalents. While no official guideline value currently exists for CYN, the WHO is in the midst of proposing

* Corresponding author. Australian Water Quality Centre, SA Water Corporation, 250 Victoria Square, Adelaide, SA 5000, Australia. Tel.: þ61 8 7424 2119; fax: þ61 8 7003 2119. E-mail address: [email protected] (L. Ho). 0043-1354/$ e see front matter ª 2011 Elsevier Ltd. All rights reserved. doi:10.1016/j.watres.2011.03.014

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Fig. 1 e Molecular structures of: (a) microcystin and (b) cylindrospermopsin. Note: The generic structure of microcystin-XY is shown with the corresponding variants presented in the accompanying table.

a 1 mg L
1 level, due to concerns regarding the effect of CYN (Rodriguez et al., 2007). In Australia, CYN has predominantly been detected in more tropical and subtropical areas, in particular Queensland. A survey of 47 water sources by McGreggor and Fabbro (2000) detected CYN in 14 of those sources at an average concentration of 3.4 mg L
1 with a maximum concentration of 20 mg L
1 in subsurface samples. In contrast, considerably higher concentrations of microcystin have been detected in Australian water bodies, in the g L
1 concentration range in some cases (Falconer, 2005; Kemp and John, 2006); however, unlike CYN a majority of the microcystins would be contained within the cell (Falconer, 2005). Conventional water treatment methods such as coagulation, flocculation, sedimentation and filtration are ineffective at removing dissolved (extracellular) cyanotoxins (Himberg et al., 1989; Mouchet and Bonne´lye, 1998; Chow et al., 1999; Newcombe and Nicholson, 2004). Treatment options which have had success in removing extracellular cyanotoxins include activated carbon (both powdered and granular), nanofiltration, ozonation and chlorination (provided a specific chlorination exposure level is applied, typically w30 mg min L
1) (Mouchet and Bonne´lye, 1998; Newcombe and Nicholson, 2004; Dixon et al., 2010). Powdered activated carbon (PAC) is one of the major treatment barriers for the removal of extracellular

cyanotoxin in most Australian water treatment plants (WTPs) as it can be applied when required, which is generally advantageous for cyanotoxin control since cyanobacterial problems are of a transient, intermittent nature. PAC adsorption has been shown to be effective in many studies if the application is optimised (Donati et al., 1994; Cook and Newcombe, 2002, 2008; Newcombe and Nicholson, 2004; Ho et al., 2008; Campinas and Rosa, 2010a,b). While PAC is a widely used and accepted method of water treatment, there have been few studies undertaken into its effective use in removing cyanotoxins such as CYN and the microcystins under conditions that could be experienced in a WTP. Consequently, more in depth systematic studies are required to ascertain the effectiveness of PAC for the removal of these cyanotoxins under such conditions. Most of studies relating to the PAC adsorption of cyanotoxins have been conducted on the microcystins, in particular, MCLR (Falconer et al., 1989; Donati et al., 1994; Pendleton et al., 2001; Cook and Newcombe, 2002, 2008; Campinas and Rosa, 2010a,b). Many of these studies have suggested that coal- and wood-based carbons are the best for microcystin adsorption due to their large mesopore volume. Cook and Newcombe (2002) conducted PAC adsorption experiments on four variants of microcystin and showed differences in the adsorption of each variant with the ease of removal following the order: MCRR > MCYR > MCLR > MCLA. These results were confirmed

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using a range of PACs with different starting materials and activation methods. Cook and Newcombe (2002) attributed the differences to a combination of factors including the hydrophobicity of the variants and electrostatic interactions. Previous studies have also suggested that the PAC adsorption of cyanobacterial metabolites, such as the microcystins, may be significantly influenced by the size and conformation of the adsorbate (Donati et al., 1994; Pendleton et al., 2001; Cook and Newcombe, 2002; Sathishkumar et al., 2010). Moreover, Donati et al. (1994) and Pendleton et al. (2001) suggest that the size and conformation of the microcystin molecules, along with the pore volume characteristics of the carbon, appear to be the dominant mechanism for microcystin adsorption, with minimal influences from electrostatic interactions due to the hydrophobic nature of the microcystin molecule and low number of ionisable functional groups. Another factor which can influence the adsorption of cyanobacterial metabolites is the presence of natural organic material (NOM), in particular, the concentration and character of NOM (Donati et al., 1994; Newcombe et al., 1997, 2002; Cook and Newcombe, 2008). These studies have shown that NOM can simultaneously compete with the cyanobacterial metabolites for adsorption sites on the surface of the activated carbon, thereby reducing the adsorption efficiency of the cyanobacterial metabolites. To date, only one study has been published in the peerreviewed literature with respect to the evaluation of PAC for the removal of CYN (Ho et al., 2008). However, no studies have been conducted relating the PAC adsorption of a combination of cyanotoxins, such as the microcystins and CYN. This is important since the onset of climate change is predicted to increase both the occurrence and intensity of cyanobacterial blooms (Paerl and Huisman, 2008). Coupled with warmer water temperatures and invading blooms of CYN-producing cyanobacteria (Chapman and Schelske, 1997; Padisa´k, 1997; Stirling and Quilliam, 2001), there is a greater likelihood that multiple cyanotoxins will be present in drinking water supplies. Consequently, knowledge pertaining to the parallel removal of a range of cyanotoxins by PAC will enable water authorities to have plans to mitigate issues caused by these cyanotoxins, including selection of the most appropriate PAC. The major aim of this study was to investigate the PAC adsorption of extracellular cyanotoxins, in particular, CYN and four microcystin variants, MCLR, MCLA, MCYR and MCRR. Two different PACs were evaluated in various Australian drinking water supplies under conditions that would be experienced in a WTP. The adsorption of NOM was also examined, with respect to its impact on the adsorption of the cyanotoxins. A final aim was to relate the adsorption of CYN with that of the microcystins under equivalent conditions.

2.

Experimental procedures

2.1.

Materials and reagents

Experiments were conducted using purified CYN (95% pure) isolated from a laboratory culture of C. raciborskii (Palm Island, Queensland, CYP020). The toxin was dissolved in ultrapure water (Millipore Pty Ltd, USA) and stored at
20  C prior to use.

Purified (95% pure) microcystin variants, MCLA, MCYR, MCRR and MCLR were purchased from a commercial supplier (Sapphire Bioscience, Australia). Stock solutions of each of the microcystin variants were prepared in 50% methanol and stored at
20  C prior to use. Aliquots were taken from the dissolved stock solution and dosed into experiments at specified concentrations. Table 1 lists some of the characteristics of the cyanotoxins. Unfiltered raw water obtained from the inlet of three WTPs was stored at 4  C until used. Warragamba Dam water (dissolved organic carbon (DOC) ¼ 5.0 mg L
1, UV absorbance at 254 nm (UV254) ¼ 0.093 cm
1, pH ¼ 7.5) was supplied by Sydney Water in New South Wales. Waikerie (DOC ¼ 4.3 mg L
1, UV254 ¼ 0.076 cm
1, pH ¼ 7.7) and Swan Reach (DOC ¼ 3.9 mg L
1, UV254 ¼ 0.072 cm
1, pH ¼ 7.6) waters were supplied by United Utilities Australia in South Australia. Waikerie and Swan Reach WTPs are situated along the River Murray in South Australia with Swan Reach WTP (coordinates 34 340 0400 S 139 350 5900 E) downstream of Waikerie WTP (coordinates 34 100 6000 S 139 580 6000 E). Warragamba Dam (coordinates 33 530 0000 S 150 350 4400 E) is located approximately 65 km west of Sydney in New South Wales. Historically, only very low concentrations of CYN and the microcystins have been detected in the three water sources, in most cases the toxins have been undetectable in these waters; however, high concentrations of cyanobacterial species known to produce these toxins have been detected in these waters. Two commercially available PACs were used in this study. PAC-A was obtained from the Waikerie WTP where it is used to mitigate cyanobacterial metabolites; this PAC is also routinely used at the Swan Reach WTP. PAC-B was supplied from Sydney Water and used at WTPs which source water from Warragamba Dam. Some general characteristics of the PACs are listed in Table S1 of the Supporting Information. The PACs were dried in an oven at 110  C for 24 h, then cooled and stored in a desiccator prior to use. For adsorption experiments, PAC slurries were prepared by mixing the required carbon dose with 5 mL of ultrapure water.

2.2.

PAC adsorption experiments

All PAC jar tests were conducted at room temperature (25  C). An FMS6V (SEM, Australia) variable speed, six paddle gang stirrer with 7.6 cm diameter flat paddle impellers and B-Ker2 gator jars (Phipps and Bird, USA) containing 1 L of sample waters was used. PAC doses of 5, 10, 25, 50 and 100 mg L
1

Table 1 e Characteristics of the cyanotoxins used in this study. Cyanotoxin

Cylindrospermopsin Microcystin RR YR LR LA

Molecular LD50 (ug kg
1 Charge at body weight) pH 6.0e8.5 weight (g mol
1) 415.43 1038.20 1045.19 995.17 910.06

2100 600 70 50 50

0 (þ &
) 0 (

& þþ)
1 (

& þ)
1 (

& þ)
2 (

)

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were employed as this range represents low to high doses that can be applied at the respective WTPs (Ho et al., 2009). The cyanotoxins were spiked into the waters (20 mg L
1 of CYN and 4 mg L
1 each of MCRR, MCYR and MCLA, and 10 mg L
1 of MCLR) and constantly stirred at 100 rpm throughout the experiment to ensure PAC remained suspended in solution. PAC slurries were added at time zero and experimental samples were taken at three time intervals; 30, 45 and 60 min. Samples were collected and immediately filtered through prerinsed 0.45 mm cellulose nitrate filters (Schleicher and Schuell, Germany) prior to analysis. Any losses of the cyanotoxins other than PAC adsorption were accounted for by jar test experiments performed in the absence of PAC. Microcystin adsorption experiments were conducted where all variants were spiked into the same experiments, while CYN adsorption experiments were conducted separately. Cook and Newcombe (2008) previously showed no competitive adsorption between the microcystin variants.

2.3.

Analyses

Prior to high performance liquid chromatographic (HPLC) analysis, the cyanotoxins were concentrated from the sample waters by solid phase extraction using methods described previously by Metcalf et al. (2002) and Nicholson et al. (1994) for CYN and the microcystins, respectively. An Agilent 1100 series HPLC system comprising of a quaternary pump, autosampler and photodiode array detector (Agilent Technologies, Australia) was employed for the analysis of the cyanotoxins. For CYN analysis, sample volumes of 25 mL were injected into a 150  4.6 mm Apollo C8 column (Alltech, Australia) at a flow rate of 0.6 mL min
1 (column temperature 30  C). Two mobile phases (mobile phase A: 0.5% formic acid and mobile phase B: 100% acetonitrile) were used during the gradient run (0 min, 100% A; 25 min, 90% A, 10% B; 25.01 min, 70% A, 30% B, 30.01 min, 100% A, 55 min, 100% A). CYN concentrations were determined by calibrating the peak areas with that of a certified reference standard (Institute of Marine Biosciences, National Research Council, Canada). The method has a detection limit of 0.5 mg L
1. For microcystin analysis the volume of sample injected into the 150  4.6 mm Luna C18 column (Phenomenex, Australia) was 25 mL at a flow rate of 1.0 mL min
1 (column temperature 30  C). Two mobile phases (mobile phase A: 30% acetonitrile and mobile phase B: 55% acetonitrile) were used during the gradient run (0 min, 100% A; 12.5 min, 50% A, 50% B; 15 min, 100% B; 23 min 100% A; 32 min, 100% A). Microcystin concentrations were determined by calibrating the peak areas with that of certified reference standards (Sapphire Bioscience Pty Ltd, Australia). The method has a detection limit of 0.1 mg L
1. DOC measurements were made on an 820 Total Organic Carbon Analyser (Sievers Instruments Inc, USA). UV254 measurements were carried out on a UV-1201 UV/VIS Spectrophotometer (Shimadzu Corporation, Japan). Molecular weight distributions of the waters were determined using high performance size exclusion chromatography (HPSEC) according to the method of Chow et al. (2008). Briefly, the HPSEC method utilised a 2690 separation module and 996 photodiode array detector operating at 260 nm (Waters Pty Ltd, Australia). Separation was performed with a Shodex KW 802.5 column

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(Shoko Co. Ltd, Japan) and a 0.1 M phosphate buffer solution (pH 6.8, ionic strength adjusted to 1.0 M with sodium chloride). An injection volume of 100 mL was used at a flow rate of 1 mL min
1. The column had an effective resolving range of 50e50,000 Da and the retention time was calibrated for apparent molecular weight using polystyrene sulphonate standards (Polysciences Inc, USA) of molecular weights 35,000, 18,000, 8000, and 4600 Da.

3.

Results and discussion

3.1.

Adsorption of NOM

The concentration and character of NOM can affect the adsorption of cyanobacterial metabolites through competitive adsorption mechanisms (Donati et al., 1994; Newcombe et al., 1997, 2002; Cook and Newcombe, 2008). In particular, it is believed that the greatest adsorption competition would exist between compounds of similar size and shape (Newcombe et al., 1997, 2002). However, competitive adsorption is not only dependent upon the size of the competing compound, but also highly dependent upon the pore volume distribution of the adsorbent (Pelekani and Snoeyink, 1999; Ebie et al., 2001; Li et al., 2003; Ho et al., 2009). In addition, previous studies have shown that solution and surface chemistry (eg. pH and PAC surface charge) have minimal influence on the adsorption of cyanobacterial metabolites (Pendleton et al., 2001; Cook and Newcombe, 2002, 2008). The initial DOC and UV254 values of Swan Reach and Waikerie WTP inlet waters were similar, attributed to the fact that both WTPs source water from the River Murray in South Australia. In contrast, Warragamba Dam water, which is sourced from New South Wales, contained NOM of higher DOC and UV254 values. Fig. 2 shows the removal of DOC and UV254 by the PACs after a contact time of 60 min. Negligible difference was observed for the removals of DOC in each of the waters (Fig. 2a), while some differences were observed for the removal of UV254 (Fig. 2b). PAC-B in Warragamba water removed more UV absorbing compounds than PAC-A in the South Australian waters, with the differences increasing with PAC dose. For example, at a PAC dose of 10 mg L
1 the difference was 5%, while for a dose of 100 mg L
1 the difference was 14%. It is unclear as to whether these differences were attributed to differences between the PACs or the waters, although it is likely to be a combination of both. The higher PAC doses employed (50 and 100 mg L
1) are generally not achievable at most conventional WTPs due to PAC carryover affecting downstream processes, including filtration. Such high PAC doses would dramatically reduce the filter run times in direct/contact filtration causing reductions in water production. However, at the Swan Reach and Waikerie WTPs, these high PAC doses can be applied due to the construction of large contact tanks prior to coagulation to facilitate removal of cyanobacterial metabolites. These high doses resulted in excellent removal of DOC and UV254 of between 60 and 74%. Fig. 3a shows the molecular weight distributions (using HPSEC with UV absorbance as the detection method) of the organics in the three waters. The waters exhibited similar

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100 90

Percent DOC remaining

80 70 60 50 40 30 -1

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PAC-A, Swan Reach (DOC=3.9mgL ) -1 PAC-A, Waikerie (DOC=4.3mgL ) -1 PAC-B, Warragamba (DOC=5.0mgL )

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PAC dose (mg L ) Fig. 2 e Removal of: (a) dissolved organic carbon (DOC) and (b) UV absorbance at 254 nm (UV254) by the PACs in the waters evaluated after a contact time of 60 min. Error bars represent 95% confidence intervals from duplicate analyses.

profiles although Warragamba water displayed higher UV absorbance than Swan Reach and Waikerie waters across the wavelengths, in particular between 800 and 1200 Da, consistent with Warragamba water’s higher UV254. Previous studies have suggested that the NOM within this region is humic in nature and contains compounds which are highly aromatic and/or contain a higher degree of conjugation (Westerhoff et al., 1999; Newcombe et al., 2002; Chow et al., 2008). Furthermore, Chow et al. (2008) have indicated that NOM in this molecular weight region are hydrophobic and more easily removed by conventional water treatment processes.

The PACs removed a wide range of molecular weight compounds with removal increasing with PAC dose (Fig. 3bed). It is presumed that the removal of the wide range of molecular weight compounds by PAC is attributed to the pore structure of the PACs (Newcombe, 2002). More importantly, the removal of the wide range of molecular weights, suggest that the character of NOM may not have a significant influence in the adsorption of the cyanotoxins when using these PACs, which may be attributed to the PACs containing a broad pore size distribution (Pelekani and Snoeyink, 1999; Ebie et al., 2001; Li et al., 2003; Ho et al., 2009). This will be discussed further in subsequent sections of this manuscript.

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Fig. 3 e Molecular weight distributions of: (a) Swan Reach, Waikerie and Warragamba waters; (b) Swan Reach water after treatment with sequential doses of PAC-A; (c) Waikerie water after treatment with sequential doses of PAC-A; (d) Warragamba water after treatment with sequential doses of PAC-B. In each case, PAC contact time was 60 min.

3.2.

Adsorption of microcystin

Four microcystin variants were studied for the PAC adsorption experiments, MCLR, MCYR, MCRR and MCLA. Whilst a majority of studies have focused on MCLR, as it is one of the most toxic variants, it is important to study other variants as most microcystin-producing blooms generally yield others, and in many cases MCLR is not always the most abundant. The water was spiked with 22 mg L
1 total microcystin; consisting 4 mg L
1 each of MCRR, MCYR and MCLA, and 10 mg L
1 MCLR. These concentrations were chosen as they represent an upper limit or worst case scenario of what could be expected to enter a WTP (Falconer, 2005). Fig. 4a and b show the removal of total microcystins by the PACs in Waikerie and Warragamba waters, respectively. The removal trends for Swan Reach (results not shown) were identical to Waikerie water. The increased contact times did not appear to enhance microcystin adsorption using both PACs in their respective waters as negligible difference was observed using contact times of 30, 45 and 60 min. This suggests that the kinetics of adsorption for both PACs were rapid. The addition of PAC-B in Warragamba water yielded the

highest removal of the microcystins where a PAC dose of 50 mg L
1 resulted in removals to below the WHO guideline level of 1 mg L
1. In contrast, Waikerie and Swan Reach waters required a PAC-A dose of 100 mg L
1 to achieve the same level of microcystin removal. Realistically, a WTP may expect to treat total microcystin concentrations of between 2 and 5 mg L
1 and possibly up to 10 mg L
1. In these scenarios the predicted PAC doses required to achieve the WHO guideline level in Warragamba water would be 5, 11 and 23 mg L
1, respectively. In Waikerie and Swan Reach waters, the corresponding predicted PAC doses would be 9, 23 and 45 mg L
1. These predictions were made using the homogenous surface diffusion model (HSDM) and are based on the assumption that the amount of microcystin adsorbed is directly proportional to its initial concentration. Previous studies have shown that the percent removal of microcystin at equilibrium for a given carbon dose in natural water is independent of the cyanotoxin’s initial concentration (Cook and Newcombe, 2002; Ho and Newcombe, 2007). The more favourable adsorption of the microcystins in Warragamba water compared with Waikerie and Swan Reach waters is consistent with the UV254 results where greater

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Fig. 4 e Removal of total microcystins (22 mg LL1) by PAC in: (a) Waikerie water; and (b) Warragamba water. Differences in the PAC adsorption of the microcystin variants after a contact time of 30 min in: (c) Waikerie water; and (d) Warragamba water.

removal was also observed in this PAC-water combination (Fig. 2b). The reasons for this will be discussed later. The trends for removal of each of the four microcystin variants in Waikerie and Warragamba waters after a PAC contact time of 30 min are shown in Fig. 4 c and d In both waters using the respective PACs, the order of the ease of removal of the microcystin variants followed the trend: MCRR > MCYR > MCLR > MCLA, which is consistent with previous studies (Cook and Newcombe, 2002, 2008). The overall charges for the four variants are shown in Table 1. The negative groups are attributed to the dissociated carboxyl groups of D-glutamic acid and D-erythro-b-methyl aspartic acid and the positive charges to the amino group on arginine. It is these differences that may result in the different adsorption characteristic being observed. Attractive or repulsive forces between the cyanotoxin molecule and the activated carbon surface could either enhance or hinder adsorption. Molecular size and conformation of the microcystin molecules may also affect the interaction that the cyanotoxin has with the PAC surface, with smaller conformations favouring adsorption. The observed trend shows that MCRR has the greatest affinity with both PACs and MCLA, the least. Therefore, for effective PAC use in removing microcystins, it is important that all

microcystin variants present are identified due to the differences in their adsorption behaviour.

3.3.

Adsorption of CYN

The adsorption of CYN was also evaluated where CYN was spiked into the waters at a concentration of 20 mg L
1; a concentration thought to represent a worst case scenario for a WTP (Falconer, 2005). Swan Reach showed identical trends to Waikerie as observed with the microcystin adsorption experiments (results not shown). Warragamba water, dosed with PAC-B, had higher CYN removal than Waikerie and Swan Reach waters with PAC-A, similar to the microcystin results (see Fig. S1 of the Supporting Information). PAC contact time again did not appear to have significant impact on the removal. The results show that PAC doses required for CYN removal to below the proposed WHO guideline value of 1 mg L
1 are 25 mg L
1 for Warragamba water and 50 mg L
1 for Waikerie and Swan Reach waters. To date, limited studies have been undertaken with respect to the PAC adsorption of CYN under WTP conditions. Ho et al. (2008) used the HSDM to predict the adsorption of CYN using

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two PACs in Hope Valley reservoir water. They determined that PAC could be effective for the removal of CYN, although relatively high doses would be required. For example, at an initial CYN concentration of 5 mg L
1, the PAC dose required to remove CYN to below 1 mg L
1 would be 25 mg L
1 (using a contact time of 60 min). However, in that study the DOC and UV254 of Hope Valley water was appreciably higher at 10.2 mg L
1 and 0.325 cm
1, respectively. These NOM characteristics have been shown to influence the adsorption of cyanobacterial metabolites through competitive adsorption processes and/or pore blockage mechanisms (Cook et al., 2001; Newcombe et al., 1997).

3.4.

Fig. 5a and b show results of the removal of total microcystins and CYN in Waikerie water using both PACs (after a contact time of 30 min), while Fig. 5c and d show the same but in Warragamba water. In all cases, PAC-B was the superior carbon for the adsorption of all the cyanotoxins with large differences observed between both PACs. In contrast, Fig. 6aed directly compare the removals of microcystin and CYN between the waters using both PACs after a contact time of 30 min. The differences between the waters in Fig. 6 were not as pronounced as those observed between the PACs in Fig. 5aed, suggesting that the PACs used had a wide range of pores which could offset the influence of water quality, in particular the presence of NOM (Pelekani and Snoeyink, 1999; Ebie et al., 2001; Newcombe et al., 2002; Li et al., 2003). This finding also strongly suggests that the PAC type was the major factor influencing cyanotoxin adsorption. The most disparate characteristic between the PACs was the effective particle size, 20e25 mm for PAC-A, and 10 mm for PAC-B. Previous studies have shown that the equilibrium adsorption of a microcontaminant is not affected by particle size (Matsu et al., 2009; Ando et al., 2010); however, the particle size can influence the adsorption kinetics, with more rapid adsorption with smaller

Differences in PAC and water quality characteristics

Further investigations were warranted to determine why the combination of PAC-B and Warragamba water was superior for the adsorption of the cyanotoxins (see Fig. 4 and Fig. S1 of the Supporting Information). It was unclear whether this was due to the differences between the PACs or the waters or a combination of both. Experiments were conducted where PAC-B was evaluated in Waikerie water and PAC-A in Warragamba water, and then compared with the original PAC-water combinations.

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Fig. 5 e Comparison in the removal of: (a) total microcystins; and (b) cylindrospermopsin (CYN) in Waikerie water by PAC-A and PAC-B after a contact time of 30 min. Comparison in the removal of: (c) total microcystins; and (d) CYN in Warragamba water by PAC-A and PAC-B after a contact time of 30 min.

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b

100

PAC-A Waikerie Warragamba

80

60

40

20

Percent MCtotal remaining

Percent MCtotal remaining

100

0

80

PAC-B Waikerie Warragamba

60

40

20

0 0

20

40

60

80

100

0

20

-1

PAC-A Waikerie Warragamba

Percent CYN remaining

Percent CYN remaining

80

100

d

100

80

60

PAC-B dose (mg L )

c

100

40

-1

PAC-A dose (mg L )

60

40

20

80

PAC-B Waikerie Warragamba

60

40

20

0

0 0

20

40

60

80

100

-1

PAC-A dose (mg L )

0

20

40

60

80

100

-1

PAC-B dose (mg L )

Fig. 6 e Comparison in the removal of total microcystins in Waikerie and Warragamba water using: (a) PAC-A; and (b) PAC-B after a contact time of 30 min. Comparison in the removal of cylindrospermopsin (CYN) in Waikerie and Warragamba water using: (c) PAC-A; and (d) PAC-B after a contact time of 30 min.

particle size (Sontheimer et al., 1988; Najm et al., 1990; Traegner et al., 1996). The results in this study confirm this contention as although PAC-B was the superior carbon at 30 min contact time (Fig. 5), the removals of all cyanotoxins by both PACs was similar at equilibrium (contact time of 3 d, results not shown). Furthermore, negligible difference in the removal of the cyanotoxins was observed between the PACs when PAC-A was ground down to the same particle size as PAC-B, providing additional evidence that particle size influenced the adsorption kinetics (results not shown).

3.5.

Comparison of microcystin and CYN adsorption

The similar adsorption trends for the microcystins and CYN by both PACs prompted an investigation in comparing the adsorption of both cyanotoxin classes. Prior to this study, no known attempt has been made to relate the PAC adsorption of the microcystins with that of CYN. This is partly due to a lack of studies investigating the PAC adsorption of CYN. Fig. 7 shows the percent removal of each of the cyanotoxins as a function of PAC-B dose for the 60 min contact time in Warragamba water. The results for Waikerie and Swan Reach

waters (using PAC-A) were similar (results not shown). CYN was shown to be removed similarly to MCRR. Coincidentally, both compounds have a net neutral charge between pH 6.0e8.5, compared with the other microcystin variants which have net negative charges (see Table 1). Furthermore, CYN is considered a hydrophilic compound (Froscio et al., 2009); likewise, MCRR is considered more hydrophilic than the other microcystins (Fastner et al., 1998). It is likely that there are other factors which contribute to the similarities in their adsorption, including, but not limited to, the molecular size and structural conformations of the compounds in solution. Studies have shown that some molecules may become smaller in solution due to electrostatic forces between neighbouring charged sites (Huang et al., 2007; Sathishkumar et al., 2010). This can reduce the overall molecular dimension which could favour adsorption. In addition, intramolecular hydrogen bonds may be formed during the reduction in molecular size, which could enhance adsorption. The presence of counterions and associated water molecules may also influence the size of molecules in solution and their subsequent adsorption (Wang and Morgner, 2010). Van der Bruggen et al. (1999) showed that the Stokes diameter was a parameter

w a t e r r e s e a r c h 4 5 ( 2 0 1 1 ) 2 9 5 4 e2 9 6 4

crucial in achieving optimum cyanotoxin removal with differences observed between the two PACs tested for the removal of the cyanotoxins.

100 90

Warragamba CYN MCRR MCYR MCLR MCLA

80

Percent remaining

2963

70 60 50

Acknowledgements This project was financially supported by Sydney Water and United Utilities Australia. The assistance of Debra Owers is duly acknowledged.

40 30 20 10 0 0

20

40

60

80

100

Appendix. Supporting information

-1

PAC-B dose (mg L )

Fig. 7 e Comparison of the removal of cylindrospermopsin (CYN) and the microcystin variants MCRR, MCYR, MCLR and MCLA in Warragamba water using PAC-B at a contact time of 60 min.

which could be used to estimate the size of a molecule in solution. This is due to the Stokes diameter taking into account the water jacket surrounding the molecule which other size parameters preclude. According to the Stokes equation, the Stokes diameter is inversely proportional to the surface diffusion coefficient (Ds). The Ds for CYN and MCLR has been estimated to be w10
9 cm2 s
1 and w10
11 cm2 s
1, respectively, from previous studies (Cook and Newcombe, 2008; Ho et al., 2008). Based on these values and the molecular weight of the toxins, CYN would be the smaller molecule in solution, lending support to its more favourable adsorption than MCLR. To date, no studies have determined the Ds for MCRR and hence a direct comparison could not be made with CYN. Nevertheless, the similar removal of CYN and MCRR is an interesting finding which has not been previously reported and suggests that there is potential in using MCRR as a surrogate for CYN adsorption, particularly when only microcystin analyses are being conducted on water samples.

4.

Summary and conclusions

With increasing global detection of CYN and microcystins in water supplies, it is imperative that effective treatment options are employed for the removal of such harmful cyanotoxins. This study provided insights into the effectiveness of PAC for the removal of CYN and microcystin variants, MCLR, MCRR, MCYR and MCLA. The results demonstrated that PAC could be an effective treatment option for the removal of the cyanotoxins from the studied waters under WTP conditions. No difference was observed in the removal of the cyanotoxins using contact times of 30, 45 and 60 min. Differences were observed in the PAC adsorption of the four microcystin variants which were consistent with previous findings. CYN was shown to adsorb to a similar extent to MCRR, a finding which has not been previously reported. Furthermore, this study suggested that selection of the most appropriate PAC is

Supplementary information associated with this article can be found, in the online version, at doi:10.1016/j.watres.2011.03.014.

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