SAS Water Solutions focuses on
better water quality for all Australians

Dedicated to cleaner water and and sustainable solutions through our advanced water treatment processes, equipment, infrastructure, operational structure and research.

Water Experts that Aussie Companies
have trusted for over 38 years

Experienced

Over 38 years experienced with water and water treatment

100% Australian Owned

We focus directly on Australian needs and solutions

Technical

Holistic approach to water treatment and engineering services

Research

We continually research and innovate to provide a better product and service

Values that we stand by.
To give you the best service.

Quality

We are committed to the provision of superior products, service and results.

Integrity

We make decisions based on what is right for our community, clients and stakeholders.

Respect

We uphold a working environment based on mutual respect for all members of our community.

Leadership

We value people at every level who lead by example, take pride in what they do and inspire others.

Teamwork

We place a premium on teamwork – collaboration underpins our success.

Our Team

Andy Dowdeswell
Managing Director

Rod Franks
General Manager,
Water Treatment

Peter Trimboli
Engineering Manager

Mick Post
General Manager,
Engineering Services

Tom Boyd
Technical Specialist

Find Out More About
SAS Water Solutions

Stockist List will be updated Shortly

[1] Stanier, R. Y, and Bazine, G, C., Phototrophic prokaryotes: the cyanobacteria. Annual Reviews in Microbiology, 1977.13(1): p. 225-274.

[2] Sergeev, V, N., et al., The proterozoic history and present state of cyanobacteria. Microbiology, 2002. 71(6): p. 623-37.

[3] Iasmina, M., Microcystis aeruginosa from Danube Delta shallow lakes, original OM picture, CyanoRO: Romanian Cyanobacteria, 2014.

[4] MacIntyre, H, L., et al., Photoacclimation of photosynthesis irradiance response curves and photosynthetic pigments in microalgae and cyanobacteria 1. Journal of phycology, 2002. 38(1), p. 17-38.

[5] Malmvärn , A ., et al., Hydroxylated and methoxylated polybrominated diphenyl ethers and polybrominated dibenzo-p-dioxins in red alga and cyanobacteria living in the Baltic Sea. Chemosphere, 2008. 72(6): p. 910-916.

[6] Kock, M, D., et al., Mycobacterium avium-related epizootic in free-ranging lesser flamingos in Kenya. Journal of wildlife diseases, 1999. 35(2) p. 297-300.

[7] MDBA, Blue-green algae on the Murray River, Murray Darling Basin Authority, April 2009, https://www.mdba.gov.au/managing-water/water-quality/blue-green-algae, accessed 10/09/18

[8] Raedle, J., Toxic lake: the untold story of lake Okeechobee, The Weather Channel, December 2016, https://weather.com/news/news/florida-toxic-lake-okeechobee, accessed 11/09/18

[9] Corbel, S, et al., Cyanobacterial toxins: modes of actions, fate in aquatic and soil ecosystems, phytotoxicity and bioaccumulation in agricultural crops. Chemosphere, 2014. 96(1): p. 1-5.

[10] O’neil, J. M., et al. “The rise of harmful cyanobacteria blooms: the potential roles of eutrophication and climate change.” Harmful algae 14 (2012): 313-334

[11] Buratti, F., et al., Cyanotoxins: producing organisms, occurrence, toxicity, mechanism of action and human health toxicological risk evaluation. Archives of Toxicology, 2017. 91: p. 1049 -1130

[12] McElhiney, J, and Lawton, L, A., Detection of the cyanobacterial hepatotoxins microcystins. Toxicology and applied pharmacology, 2005. 203(3): p. 219-30.

[13] Mello, F, D., et al., Mechanisms and effects posed by neurotoxic products of cyanobacteria/microbial eukaryotes/dinoflagellates in algae blooms: a review. Neurotoxicology Research, 2018. 33: p. 153 -167

[14] Kaebernick, M., et al., Ecological and molecular investigations of cyanotoxin production. FEMS Microbiology Ecology, 2001. 35: p. 1-9

[15] Aloysio, S, F., et al., Cyanotoxins: bioaccumulation and effects on aquatic animals. Marine Drugs, 2011. 9: p. 2729-2772

[16] Codd, G, A., et al. Toxic blooms of cyanobacteria in Lake Alexandrina, South Australia—learning from history. Marine and Freshwater Research, 1994. 45(5):p. 731-6

[17] Niamien-Ebrottie, J, E., et al., Cyanobacteria and cyanotoxins in the world: Review. International Journal of Applied Research, 2015. 1(8): p. 563 -569

[18] Rastogi, R, and Sinha, R, R., The cyanotoxin-microcystins: current overview. Review of Environmental Science and Biotechnology, 2014. 13: p. 215-249

[19] Hu, Y., et al., A review of neurotoxicity of microcystins. Environmental Science and Pollution Research, 2016. 23(8): p. 7211-7219.

[20] Chen, L., et al., A review of reproductive toxicity of microcystins. Journal of Hazardous Materials, 2016. 301: p. 381-399.

[21] Žegura, B., A. Štraser, and M. Filipič, Genotoxicity and potential carcinogenicity of cyanobacterial toxins – a review. Mutation Research/Reviews in Mutation Research, 2011. 727(1): p. 16-41.

[22] Zegura, B., An Overview of the Mechanisms of Microcystin-LR Genotoxicity and Potential Carcinogenicity. Vol. 16. 2016. 1-1.

[1] Hu, Y., et al., A review of neurotoxicity of Microcystins. Environmental Science Pollution Research, 2016. 23(1): p. 7211-7219

[1] Falconer , I, R., et al., Evidence of liver damage by toxin from a bloom of the blue-green alga, Microcystis aeruginosa. The Medical Journal of Australia.,1983. 11(1): p. 511-4.

[23] Andrew R. Humpage, S.J.H.E.J.M.S.M.F.I.R.F., MICROCYSTINS (CYANOBACTERIAL TOXINS) IN DRINKING WATER ENHANCE THE GROWTH OF ABERRANT CRYPT FOCI IN THE MOUSE COLON. Journal of Toxicology and Environmental Health, Part A, 2000. 61(3): p. 155-165.

[24] Botha, N., et al., The effect of intraperitoneally administered microcystin-LR on the gastrointestinal tract of Balb/c mice. Toxicon, 2004. 43(3): p. 251-254.

[25] Nobre, A.C.L., et al., Effects of microcystin-LR in isolated perfused rat kidney. Brazilian Journal of Medical and Biological Research, 1999. 32: p. 985-988.

[26] Milutinović, A., et al., Renal injuries induced by chronic intoxication with microcystins. Vol. 7. 2002. 139-41.

[27] Ding, X.-S., et al., Toxic effects of Microcystis cell extracts on the reproductive system of male mice. Toxicon, 2006. 48(8): p. 973-979.

[28] Li, H., et al., In vivo study on the effects of microcystin extracts on the expression profiles of proto-oncogenes (c-fos, c-jun and c-myc) in liver, kidney and testis of male Wistar rats injected i.v. with toxins. Toxicon, 2009. 53(1): p. 169-175.

[29] Milutinović, A., et al., Microcystin-LR induces alterations in heart muscle. Vol. 52. 2006. 116-8.

[30] Slatkin, D.N., et al., Atypical Pulmonary Thrombosis Caused by a Toxic Cyanobacterial Peptide. Science, 1983. 220(4604): p. 1383-1385.

[31] Soares, R.M., et al., Effects of microcystin-LR on mouse lungs. Toxicon, 2007. 50(3): p. 330-338.

[32] Falconer, I.R. and T.H. Buckley, Tumour promotion by Microcystis sp., a blue-green alga occurring in water supplies. Med J Aust, 1989. 150(6): p. 351.

[33] Fujiki, H., et al., Codon 61 mutations in the c-Harvey-ras gene in mouse skin tumors induced by 7,12-dimethylbenz[a]anthracene plus okadaic acid class tumor promoters. Mol Carcinog, 1989. 2(4): p. 184-7.

[34] Falconer, I.R., Tumor promotion and liver injury caused by oral consumption of cyanobacteria. Environmental Toxicology and Water Quality, 1991. 6(2): p. 177-184.

[35] Chen, Y., et al., Nodularins in poisoning. Clinica Chimica Acta, 2013. 425(1): p. 18-29

[36] Ufelmann, H., et al., Human and rat hepatocyte toxicity and protein phosphatase 1 and 2A inhibitory activity of naturally occurring desmethyl-microcystins and nodularins. Toxicology. 2012. 293(1): p. 59-67

[37] Towner, A., et al., In vivo assessment of nodularin-induced hepatotoxitity in the rat using magnetic resonance techniques (MRI, MRS and EPR oximetry). Chemico-Biological Interactions, 2002. 139(3): p. 231-250

[38] Mello,F, D., et al., Mechanisms and Effects Posed by Neurotoxic Products of Cyanobacteria/Microbial Eukaryotes/Dinoflagellates in Algae Blooms: a Review. Neurotoxicity Research, 2018. 33: p. 153-167

[39] Park, T, J., et al., Marked inhibition of testosterone biosynthesis by the hepatotoxin nodularin due to apoptosis of Leydig cells. Molecular Carcinogenesis, 2002. 34(3), p. 151-163

[40] Oziol, L., et al., First evidence of estrogenic potential of the cyanobacterial heptotoxins the nodularin-R and the microcystin-LR in cultured mammalian cells. Journal of Hazardous Materials, 2010. 174(1), p. 610-615

[41] Lankoff, A., et al., Nodularin-induced genotoxicity following oxidative DNA damage and aneuploidy in HepG2 cells. Toxicology Letters, 2006. 164(3), p. 239-248

[42] Lankoff, A., et al., Nucleotide excision repair impairment by nodularin in CHO cell lines due to ERCC1/XPF inactivation. Toxicology Letters, 2008. 179(2), p. 101-107

[43] Ohta, T.,et al., Significance of the cyanobacterial cyclic peptide toxins, the Microcystins and nodularin in liver cancer. Mutation Research/Environmental Mutagenesis and Related Subjects, 1993. 292(3): p. 286-287

[44] Ohta, T., et al., Nodularin, a potent inhibitor of protein phosphatases 1 and 2A, is a new environmental carcinogen in male F344 rat liver, 1994. 54(24): p. 6402-6406

[45] Protist Information Server, Cyanophyceae: Nostocales : Nostocaeceae: Nodularia spumigena, Digital Specimen Archives, Japan Science and Technology Corporation, 2018, http://protist.i.hosei.ac.jp/PDB/Images/Prokaryotes/Nostocaceae/sp_02b.html, accessed 11/09/18

[46] Mowe MAD, Mitrovic SM, Lim RP, Furey A, Yeo DCJ. Tropical cyanobacterial blooms: a review of prevalence, problem taxa, toxins and influencing environmental factors, 2014. DOI:10.4081/jlimnol.2014.1005

[47] Wilson, Kim; Mark A. Schembri; Peter D. Baker; Christopher P. Saint (2000). “Molecular Characterization of the Toxic Cyanobacterium Cylindrospermopsis Raciborskii and Design of a Species-Specific PCR”. Applied and Environmental Microbiology66 (1): 332–338

[48] Weller, M, G. Immunoassays and biosensors for the detection of cyanobacterial toxins in water. Sensors, 2013. 13: p. 15085 – 15112

[49] Moore, C, E., et al., Comparison of protein phosphatase inhibition assay with LC-MS/MS for diagnosis of microcystin toxicosis in veterinary cases. Marine Drugs, 2016. 14(54): p. 1 -16

[50] Gaget, V., et al., Cyanotoxins: which detection technique for an optimum risk assessment? Water Research, 2017. 118: p. 227 – 238

[51] Welker, M., et al., HPLC-PDA detection of cylindrospermopsin—opportunities and limits. Water Research. 2002. 18(1): p. 4659-4663

[52] Weller, M, G. Immunoassays and biosensors for the detection of cyanobacterial toxins in water. Sensors, 2013. 13: p. 15085 – 15112

[53] Metcalf, J,S, and Codd, G, A., Immunoassays and Other Antibody Applications. Handbook of Cyanobacterial Monitoring and Cyanotoxin Analysis, 2016. 18:p. 263-266.

[54] Dodeign, C., et al., Chemiluminescence as diagnostic tool. A review. Talanta, 2000. 51(3): p. 415-39

[55] Hennion, M, C, and Barcelo, D. Strengths and limitations of immunoassays for effective and efficient use for pesticide analysis in water samples: A review. Analytica Chimica Acta, 1998. 362(1): p. 3-4

[56] Akter, S., et al., Broad-spectrum noncompetitive immunocomplex immunoassay for cyanobacterial peptide hepatotoxins (Microcystins and Nodularins). Analytical Chemistry, 2016. 88: p. 10080 -10087

[57] Metcalf, J, S, and Codd, G, A., Cyanobacterial Toxins (Cyanotoxins) in Water: A review of current knowledge. Foundation for Water Research, 2004.

[58]Neumann, A, C., et al., Determination of microcystin-LR in surface water by a magnetic bead-based colorimetric immunoassay using antibody-conjugated gold nanoparticles. Analytical Methods, 2015. 8: p. 57-62

59 Bownik, A., Harmful algae: Effects of cyanobacterial cyclic peptides on aquatic invertebrates- a short review. Toxicon, 2016. 124: p. 25 -51