Recommandations pour la qualité de l’eau potable au Canada – Antimoine : Références, liste des abréviations
- Aperçu
- Considérations relatives à la exposition
- Considérations relatives à la santé, calcul de la valeur
- Considérations relatives à l’analyse et au traitement
- Stratégies de gestion, considérations internationales
- Justification de la concentration maximale acceptable
- Références, liste des abréviations
- Données sur la qualité des eaux au Canada
Sur cette page
Références
ACIA (2016). 2012–2014 Antimoine dans certains aliments. Agence canadienne d'inspection des aliments, Ottawa, Canada. Disponible a https://inspection.canada.ca/food-safety-for-industry/food-chemistry-and-microbiology/food-safety-testing-bulletin-and-reports/antimony-in-selected-foods/eng/1645636000965/1645636001387 (accès en septembre 2022).
Adam, G.K., Abdulla, M.A., Ahmed, A.A. et Adam, I. (2009). Maternal and perinatal outcomes of visceral leishmaniasis (kala-azar) treated with sodium stibogluconate in eastern Sudan. Int. J. Gynaecol. Obstet., 107(3): 208–210.
AGAT Laboratories Ltd. (2019a). Communication personnelle avec A. Sekera. Calgary, AB.
AGAT Laboratories Ltd. (2019b). Communication personnelle avec S. Ortiz. Edmonton, AB.
AGAT Laboratories Ltd. (2019c). Communication personnelle avec M. Kellosalmi. Burnaby, BC.
Alvarez, M., Malecot, C.O., Gannier, F. et Lignon, J.M. (2005). Antimony-induced cardiomyopathy in guineapig and protection by L-carnitine. Br. J. Pharmacol., 144(1): 17–27.
Andersen, E.M., Cruz-Saldarriaga, M., Llanos-Cuentas, A., Luz-Cjuno, M., Echevarria, J., Miranda-Verastegui, C., Colina, O. et Berman, J.D. (2005). Comparison of meglumine antimoniate and pentamidine for peruvian cutaneous leishmaniasis. Am J Trop Med Hyg 72, 133–137.
Anderson, C.G. (2012). The metallurgy of antimony. Antimony. Geochemistry, 72: 3–8.
Andrewes, P. et Cullen, W.R. (2003). Organoantimony compounds in the environment. In: Organometallic compounds in the environment. Craig, P.J. (ed.). 2nd. John Wiley & Sons, Chichester, England. DOI: 10.1002/0470867868, pp. 277–303.
Andrewes, P., Kitchin, K.T. et Wallace, K. (2004). Plasmid DNA damage caused by stibine and trimethylstibine. Toxicol. Appl. Pharmacol., 194(1): 41–48.
APHA, AWWA et WEF (2017). Standard methods for the examination of water and wastewater. 23rd Ed. (Online version). Standard methods for the examination of water and wastewater. American Public Health Association.
Disponible à https://www.standardmethods.org/
ASTM (2016). ASTM D5673–16 Standard test method for elements in water by inductively coupled Plasma—Mass spectrometry. ASTM International, West Conshohocken, Pennsylvania.
ATSDR (2019). Toxicological Profile for Antimony and compounds. Agency for Toxic Substances and Disease Registry. Atlanta (GA): U.S. Department of Health and Human Services, Public Health Service. Disponible à https://www.atsdr.cdc.gov/toxprofiles/tp.asp?id=332&tid=58
AWWA (2017). Internal Corrosion Control in Water Distribution Systems: Manual of Water Supply Practices, M58. Second edition. American Water Works Association, Denver, CO.
Bailly, R., Lauwerys, R., Buchet, J.P., Mahieu, P. et Konings, J. (1991). Experimental and human studies on antimony metabolism: Their relevance for the biological monitoring of workers exposed to inorganic antimony. Br. J. Ind. Med., 48(2): 93–97.
Barloková, D., Ilavsky, J. et Munka, K. (2017). Removal of antimony from water using GEH sorption material at different filter bed volumes. Anonymous Lithuania.
Barrera, C., Lopez, S., Aguilar, L., Mereado, L. et Bravo, M. (2016). Pentavalent antimony uptake pathway through erythrocyte membranes: molecular and atomic florescence approaches. Anal Bioanl Chem 408: 2937–2944.
Belzile, N., Chen, Y. et Filella, M. (2011). Human exposure to antimony: I. sources and intake. Crit. Rev. Environ. Sci. Technol., 41(14): 1309–1373.
Bento, D.B., de Souza, B., Steckert, A.V., Dias, R.O., Leffa, D.D., Moreno, S.E., Petronilho, F., de Andrade, V.M., Dal-Pizzol, F. et Romao, P.R. (2013). Oxidative stress in mice treated with antileishmanial meglumine antimoniate. Res. Vet. Sci., 95(3): 1134–1141.
Borborema, S.E., Osso Jr, J.A., Andrade Jr, H.F. et Nascimento, N. (2013). Biodistribution of meglumine antimoniate in healthy and leishmania (leishmania) infantum chagasi-infected BALB/c mice. Mem. Inst. Oswaldo Cruz, 108(5): 623–630.
British Columbia Ministry of Health (2019). Communication personnelle avec D. Fishwick.
Cai, Y., Li, L. et Zhang, H. (2015). Kinetic modeling of pH-dependent antimony (V) sorption and transport in iron oxide-coated sand. Chemosphere, 138: 758–764.
Carneado, S., Hernandez-Nataren, E., Lopez-Sanchez, J.F. et Sahuquillo, A. (2015). Migration of antimony from polyethylene terephthalate used in mineral water bottles. Food Chem., 166: 544–550.
CCME (2003). Guide concernant l'application propre à un lieu des Recommandations pour la qualité des eaux au Canada : procédures d'établissement d'objectifs numériques de qualité de l'eau, Conseil canadien des ministres de l'environnement, Winnipeg (Manitoba).
CCME (2004). De la source au robinet : guide d'application de l'approche à barrières multiples pour une eau potable saine, Conseil canadien des ministres de l'environnement, Winnipeg (Manitoba).
CCME (2007). Protocole d'élaboration des recommandations pour la qualité des eaux en vue de protéger la vie aquatique, Conseil canadien des ministres de l'environnement, Winnipeg (Manitoba).
CCN (2020). Répertoire des organismes de certification accrédités de produits, de processus et de services. Conseil canadien des normes, Ottawa, Ontario. Disponible à https://www.scc.ca/fr/accreditation/certification-de-produits-procedes-et-services/repertoire-des-organismes-de-certification-accredites
CH2M (2016). Judge and Spiro tunnels mining – influenced water treatment evaluation: draft pilot testing report, CH2M Hill Engineering, Inc., Taylorsville, UT.
Chen, R., Chen, J., Cheng, S., Qin, J., Li, W., Zhang, L., Jiao, H., Yu, X., Zhang, X., Lahn, B.T. et Xiang, A.P. (2010). Assessment of embryotoxicity of compounds in cosmetics by the embryonic stem cell test. Toxicol. Mech. Methods, 20(3): 112–118.
Choe, S.Y., Kim, S.J., Kim, H.G., Lee, J.H., Choi, Y., Lee, H. et Kim, Y. (2003). Evaluation of estrogenicity of major heavy metals. Sci. Total Environ., 312(1-3): 15–21.
Clement, B. et Carlson, G. (2004). Contaminant accumulation in the distribution system: Case histories [citée dans U.S. EPA, 2006].
Coelho, D.R., De-Carvalho, R.R., Rocha, R.C.C., Saint'Pierre, T.D. et Paumgartten, F.J.R. (2014b). Effects of in utero and lactational exposure to SbV on rat neurobehavioral development and fertility. Reproductive Toxicology, 50(Supplement C): 98–107.
Coelho, D.R., Miranda, E.S., Saint'Pierre, T.D. et Paumgartten, F.J. (2014a). Tissue distribution of residual antimony in rats treated with multiple doses of meglumine antimoniate. Mem. Inst. Oswaldo Cruz, 109(4): 420–427.
Cooper, R.G. et Harrison, A.P. (2009). The exposure to and health effects of antimony. Indian J. Occup. Environ. Med., 13(1): 3–10.
Cruz, A., Rainey, P.M., Herwaldt, B.L., Stagni, G., Palacios, R., Trujillo, R. et Saravia, N.G. (2007). Pharmacokinetics of antimony in children treated for leishmaniasis with meglumine antimoniate. J. Infect. Dis., 195(4): 602–608.
Cumming, L.J., Chen, A.S.C. et Wang, L. (2009). Arsenic and antimony removal from drinking water by adsorptive media U.S. EPA demonstration project at South Truckee Meadows General Improvement District (STMGID), NV Final performance evaluation report. Water Supply and Water Resources Division. National Risk Management Research Laboratory, EPA/600/R-09/016, Cincinnati, Ohio.
Darbre, P.D. (2006). Metalloestrogens: An emerging class of inorganic xenoestrogens with potential to add to the oestrogenic burden of the human breast. J. Appl. Toxicol., 26(3): 191–197.
Deng, R.-., Jin, C.-., Ren, B.-., Hou, B.-. et Hursthouse, A.S. (2017). The potential for the treatment of antimony-containing wastewater by iron-based adsorbents. Water (Switzerland), 9(10).
Deshommes, E., Laroche, L., Nour, S., Cartier, C. et Prévost, M. (2010). Source and occurrence of particulate lead in tap water. Water Res., 44(12): 3734–3744.
Deshommes, E., Nour, S., Richer, B., Cartier, C. et Prévost, M. (2012). POU devices in large buildings: Lead removal and water quality. J. AWWA: E282-E297.
Développement durable Manitoba (2019). Communication personnelle avec Dr. H.D. Coulibaly.
DFG (2007). Antimony and its inorganic compounds* (inhalable fraction). The MAK-Collection Part I: MAK value documentations, vol. 23. DFG, deutsche forschungsgemeinschaft. ISBN: 978-3-527-31595-6. WILEY-VCH Verlag GmbH & Co., KGaA, Weinheim.
Du, X., Qu, F., Liang, H., Li, K., Yu, H., Bai, L. et Li, G. (2014). Removal of antimony (III) from polluted surface water using a hybrid coagulation-flocculation-ultrafiltration (CF-UF) process. Chem. Eng. J., 254: 293–301.
Dzamitika, S.A., Falcao, C.A., de Oliveira, F.B., Marbeuf, C., Garnier-Suillerot, A., Demicheli, C., Rossi-Bergmann, B. et Frezard, F. (2006). Role of residual Sb(III) in meglumine antimoniate cytotoxicity and MRP1-mediated resistance. Chem. Biol. Interact., 160(3): 217–224.
ECCC (2010). Évaluation préalable pour le Défi concernant Trioxyde de diantimoine (oxyde d'antimoine). Environnement et Changement climatique Canada. Disponible à https://www.ec.gc.ca/ese-ees/9889ABB5-3396-435B-8428-F270074EA2A7/batch9_1309-64-4_fr.pdf
ECCC (2017). Données nationales de monitoring de la qualité de l'eau à long terme. Environnement et Changement climatique Canada. Disponible à https://donnees.ec.gc.ca/data/substances/monitor/national-long-term-water-quality-monitoring-data/?lang=fr.
ECCC et Santé Canada (2020). Évaluation préalable - Substances contenant de l'antimoine. Environnement et Changement climatique Canada et Santé Canada. Gouvernement du Canada, Ottawa, Canada. Disponible à https://www.canada.ca/content/dam/eccc/documents/pdf/pded/antimony-containing-substances/FSAR-Antimony-FR.pdf
ECHA (2014). Sodium hexahydrooxoantimonate. CAS RN 33908-66-6. L'Agence européenne des produits chimiques.[ accès en avril 2019].
Edel, J., Marafante, E., Sabbioni, E. et Manzo, L. (1983). Metabolic behaviour of inorganic forms of antimony in the rat. Heavy Met Environ Int Conf 4th 1: 574–577.
Ettler, V., Mihaljevic, M., Sebek, O. et Nechutny, Z. (2007). Antimony availability in highly polluted soils and sediments - a comparison of single extractions. Chemosphere, 68(3): 455–463.
Felicetti, S.W., Thomas, R.G. et McClellan, R.O. (1974). Metabolism of two valence states of inhaled antimony in hamsters. Am Ind Hyg Assoc J 35: 292–300.
Filella, M., Williams, P.A. et Belzile, N. (2009). Antimony in the environment: Knowns and unknowns. Environmental Chemistry, 6: 95–105.
Filella, M. et Williams, P.A. (2010). Antimony biomethylation in culture media revisited in the light of solubility and chemical speciation considerations. Environ. Toxicol., 25(5): 431–439.
Forns, J., Fort, M., Casas, M., Caceres, A., Guxens, M., Gascon, M., Garcia-Esteban, R., Julvez, J., Grimalt, J.O. et Sunyer, J. (2014). Exposure to metals during pregnancy and neuropsychological development at the age of 4 years. Neurotoxicology, 40: 16–22.
Franke, E.D., Wignall, F.S., Cruz, M.E., Rosales, E., Tovar, A.A., Lucas, C.M., LlanosCuentas, A. et Berman, J.D. (1990). Efficacy and toxicity of sodium stibogluconate for mucosal leishmaniasis. Ann Inter Med 113, 934–940.
Frezard, F., Demicheli, C., Ferreira, C.S. et Costa, M.A. (2001). Glutathione-induced conversion of penatvalentantimony to trivalent antimony in meglumine antimoniate. Antimicrob. Agents Chemother., 45(3): 913–916.
Frezard, F., Demicheli, C. et Ribeiro, R.R. (2009). Pentavalent antimonials: New perspectives for old drugs. Molecules, 14(7): 2317–2336.
Friedman, M.J., Hill, A.S., Reiber, S.H., Valentine, R.L., Larsen, G., Young, A., Korshin, G.V. et Peng, C.Y. (2010). Assessment of inorganics accumulation in drinking water systems scales and sediments. Water Research Foundation, Denver, Colorado.
Friedman, M.J., Hill, A.S., Booth, S., Hallett, M., McNeill, L., McLean, J., Stevens, D., Sorensen, D., Hammer, T., Kent, W., De Haan, M., MacArthur, K. et Mitchell, K. (2016). Metals accumulation and release within the distribution system: evaluation and mitigation. Report 4509. Water Research Foundation, Denver, Colorado.
Friedrich, K., Vieira, F.A., Porrozzi, R., Marchevsky, R.S., Miekeley, N., Grimaldi, G.,Jr et Paumgartten, F.J. (2012). Disposition of antimony in rhesus monkeys infected with leishmania braziliensis and treated with meglumine antimoniate. J. Toxicol. Environ. Health A, 75(2): 63–75.
Fuge, R., Pearce, N.J.G. et Perkins, W.T. (1992). Unusual sources of aluminium and heavy metals in potable waters. Environ. Geochem. Health, 14(1): 15–18.
Garbarino, J.R. et Struzeski, T.M. (1998). Methods of analysis by the US Geological Survey National Water Quality Laboratory - Determination of elements in whole-water digests using inductively coupled plasma-optical emission spectrometry and inductively coupled plasma-mass spectrometry. United States Geological Survey,
Denver, Colorado (Report No. 98-165). Disponible à http://nwql.usgs.gov/pubs/OFR/OFR-98-165.pdf
Gerhardsson, L., Brune, D., Nordberg, G.F. et Wester, P.O. (1982). Antimony in lung, liver and kidney tissue from deceased smelter workers. Scand. J. Work Environ. Health, 8(3): 201–208.
Gerhardsson, L., Brune, D., Nordberg, G.F. et Wester, P.O. (1988). Multielemental assay of tissues of deceased smelter workers and controls. Sci. Total Environ., 74: 97–110.
Guo, X., Wu, Z. et He, M. (2009). Removal of antimony(V) and antimony(III) from drinking water by coagulation-flocculation-sedimentation (CFS). Water Res., 43(17): 4327–4335.
Guo, X., Wu, Z., He, M., Meng, X., Jin, X., Qiu, N. et Zhang, J. (2014). Adsorption of antimony onto iron oxyhydroxides: Adsorption behavior and surface structure. J. Hazard. Mater., 276: 339–345.
Guo, W., Fu, Z., Wang, H., Liu, S., Wu, F. et Giesy, J.P. (2018). Removal of antimonate (Sb(V)) and antimonite (Sb(III)) from aqueous solutions by coagulation-flocculation-sedimentation (CFS): Dependence on influencing factors and insights into removal mechanisms. Sci. Total Environ., 644: 1277–1285.
Gupta, S., Raychaudhury, B. et Datta, S.C. (2009). Host peroxisomal properties are not restored to normal after treatment of visceral leishmaniasis with sodium antimony gluconate. Exp Parasitol 123, 140–145.
Hammond, C.R. et Lide, D.R. (2019). "The elements," in CRC Handbook of Chemistry and Physics, 100th edition (internet version 2019), John R. Rumble, ed., CRC Press/Taylor & Francis, Boca Raton, FL. pp. 1–7.
Hashemzaei, M.,Pourahmad, J., Safaeinejad, F., Tabrizian, K., Akbari, F., Bagheri, G.,Hosseini, M-J. et,Shahraki, J. (2015). Antimony induces oxidative stress and cell death in normal hepatocytes. Toxicol Environ Chem, 97(2): 256–265.
He, Z., Liu, R., Liu, H. et Qu, J. (2015). Adsorption of Sb(III) and Sb(V) on freshly prepared ferric hydroxide (FeOxHy). Environ. Eng. Sci., 32(2): 95–102.
Hepburn, N.C., Siddique, I., Howie, A.F., Beckett, G.J. et Hayes, P.C. (1993). Hepatotoxicity of sodium stibogluconate in leishmaniasis. Lancet, 342(8865): 238–239.
Hepburn, N.C., Siddique, I., Howie, A.F., Beckett, G.J. et Hayes, P.C. (1994). Hepatotoxicity of sodium stibogluconate therapy for american cutaneous leishmaniasis. Trans. R. Soc. Trop. Med. Hyg., 88(4): 453–455.
Herath, I., Vithanage, M. et Bundschuh, J. (2017). Antimony as a global dilemma: Geochemistry, mobility, fate and transport. Environ. Pollut., 223: 545–559.
Hext, P.M., Pinto, P.J. et Rimmel, B.A. (1999). Subchronic feeding study of antimony trioxide in rats. J. Appl. Toxicol., 19(3): 205–209.
Hjortenkrans, D.S., Bergback, B.G. et Haggerud, A.V. (2007). Metal emissions from brake linings and tires: Case studies of Stockholm, Sweden 1995/1998 and 2005. Environ. Sci. Technol., 41(15): 5224–5230.
Hockmann, K., Tandy, S., Lenz, M., Reiser, R., Conesa, H.M., Keller, M., Studer, B. et Schulin, R. (2015). Antimony retention and release from drained and waterlogged shooting range soil under field conditions. Chemosphere, 134: 536–543.
Hopper, J.F. et Barrie, L.A. (1988). Regional and background aerosol trace elemental composition observed in eastern Canada. Tellus, 40B 446–462.
Howe, C.G., Claus Henn, B., Farzan, S.F., Habre, R., Eckel, S.P., Grubbs, B.H., Chavez, T.A., Faham, D., Al-Marayati, L., Lerner, D., Quimby, A., Twogood, S., Richards, M.J., Meeker, J.D., Bastain, T.M. et Breton, C.V. (2021). Prenatal metal mixtures and fetal size in mid-pregnancy in the MADRES study. Environ Res. 196:110388.
CIRC (1989). Antimony trioxide and antimony trisulfide. vol. 47. International Agency for Research on Cancer (ed.). IPCS. INCHEM, p. 291-.
ICRP (1981). Limits on intakes of radionuclides for workers. ICRP Publication 30, Part 3. International Commission on Radiological Protection. Ann. ICRP 6(2/3).
ICRP (1995). Age-dependent doses to members of the public from intake of radionuclides, Part 3. Ingestion dose coefficients. ICRP Publication 69. International Commission on Radiological Protection. Ann. ICRP 25(1).
ICRP (2017). Occupational intakes of radionuclides: Part3. ICRP publication 137. International Commission on Radiological Protection. Annals of the ICRP, 46(3/4). Disponible à https://journals.sagepub.com/doi/pdf/10.1177/ANIB_46_3-4
Iffland, R. et Bösche, G. (1987). Therapie und klinisch-toxikologische Verlaufskontrolle einer Brechweinstein-Vergiftung durch ein Ameisenvernichtungsmittel bei einem Kind. [Therapy and clinical-toxicological development and control of a child's poisoning with emetic tartar from an anticide.] Monatsschrift für Kinderheilkunde. 135: 227–230.
Ilavský, J., Barloková, D., Hudec, P. et Munka, K. (2014). Iron-based sorption materials for the removal of antimony from water. J. Water Supply Res. Technol. Aqua, 63(6): 518–524.
Ilavský, J., Barloková, D., Hudec, P. et Munka, K. (2015). READ-As and GEH sorption materials for the removal of antimony from water. Water Sci. Technol. Water Supply, 15(3): 525–532.
Ilgen, A.G., Majs, F., Barker, A.J., Douglas, T.A. et Trainor, T.P. (2014). Oxidation and mobilization of metallic antimony in aqueous systems with simulated groundwater. Geochim. Cosmochim. Acta, 132: 16–30.
Imai, K. et Nakamura, M. (2006). In vitro embryotoxicity testing of metals for dental use by differentiation of embryonic stem cell test. Congenit Anom (Kyoto), 46(1): 34–38.
Inam, M.A., Khan, R., Park, D.R., Lee, Y.-. et Yeom, I.T. (2018). Removal of Sb(III) and Sb(V) by ferric chloride coagulation: Implications of Fe solubility. Water (Switzerland), 10(4): 418.
Inam, M.A., Khan, R., Park, D.R., Khan, S., Uddin, A. et Yeom, I.T. (2019). Complexation of antimony with natural organic matter: Performance evaluation during coagulation-flocculation process. Int. J. Environ. Res. Public Health, 16(7): 1–16.
INRP (2017). Antimoine (et ses composés). L'Inventaire national des rejets de polluants. Gouvernement du Canada. Disponible à https://pollution-dechets.canada.ca/inventaire-national-rejets
Kang, M., Kawasaki, M., Tamada, S., Kamei, T. et Magara, Y. (2000). Effect of pH on the removal of arsenic and antimony using reverse osmosis membranes. Desalination, 131(1-3): 293–298.
Kang, M., Kamei, T. et Magara, Y. (2003). Comparing polyaluminum chloride and ferric chloride for antimony removal. Water Res., 37(17): 4171–4179.
Kato, K.C., Morais-Teixeira, E., Reis, P.G., Silva-Barcellos, N.M., Salaun, P., Campos, P.P., Dias Correa-Junior, J., Rabello, A., Demicheli, C. et Frezard, F. (2014). Hepatotoxicity of pentavalent antimonial drug: Possible role of residual Sb(III) and protective effect of ascorbic acid. Antimicrob. Agents Chemother., 58(1): 481–488.
Khosravi, A., Sharifi, I., Tavakkoli, H., Derakhshanfar, A., Keyhani, A.R., Salari, Z., Mosallanejad, S.S. et Bamorovat, M. (2018). Embryonic toxico-pathological effects of meglumine antimoniate using a chick embryo model. PLoS One, 13(5): e0196424.
Kim, E.J. et Herrera, J.E. (2010). Characteristics of lead corrosion scales formed during drinking water distribution and their potential influence on the release of lead and other contaminants. Environ. Sci. Technol., 44(16): 6054–6061.
Kip, A.E., Schellens, J.H.M., Beijnen, J.H. et Dorlo, T.P.C. (2017). Clinical pharmacokinetics of systemically administered antileishmanial drugs. Clin. Pharmacokinet.
Kobayashi, A. et Ogra, Y. (2009). Metabolism of tellurium, antimony and germanium simultaneously administered to rats. J Toxicol Sci 34(3): 295–303.
Krishnan, K. et Carrier, R. (2008). Approaches for evaluating the relevance of multiroute exposures in establishing guideline values for drinking water contaminants. J. Environ. Sci. Health. C. Environ. Carcinog. Ecotoxicol. Rev., 26(3): 300–316.
Lauwers, L.F., Roelants, A., Rosseel, P.M., Heyndrickx, B. et Baute, L. (1990). Oral antimony intoxications in man. Crit. Care Med., 18(3): 324–326.
Lecureur, V., Lagadic-Gossmann, D. et Fardel, O. (2002a). Potassium antimonyl tartrate induces reactive oxygen species-related apoptosis in human myeloid leukemic HL60 cells. Int. J. Oncol., 20(5): 1071–1076.
Lecureur, V., Le Thiec, A., Le Meur, A., Amiot, L., Drenou, B., Bernard, M., Lamy, T., Fauchet, R. et Fardel, O. (2002b). Potassium antimonyl tartrate induces caspase- and reactive oxygen species-dependent apoptosis in lymphoid tumoral cells. Br. J. Haematol., 119(3): 608–615.
Leuz, A.-K., Mönch, H. et Johnson, C.A. (2006). Sorption of Sb(III) and Sb(V) to goethite: Influence on Sb(III) oxidation and mobilization. Environ. Sci. Technol., 40(23): 7277–7282.
Lewis, R.J. (2012). Sax's Dangerous Properties of Industrial Materials. 12th Edition. Wiley-Interscience, Wiley & Sons, Inc. Hoboken, NJ. p. V2: 338.
Li, A., Zhuang, T., Shi, J., Liang, Y. et Song, M. (2019). Heavy metals in maternal and cord blood in beijing and their efficiency of placental transfer. J. Environ. Sci. (China), 80: 99–106.
Lippincott, S.W., Ellerbrook, L.D., Rhees, M., et Mason, P. (1947). A study of the distribution and fate of antimony when used as tartar emetic and fuadin in the treatment of American soldiers with Schistosomiasis japonica. J Clin Invest 26(3): 370–378.
López, S., Aguilar, L., Mercado, L., Bravo, M. et Quiroz, W. (2015). Sb(V) Reactivity with Human Blood Components: Redox Effects. PLoS ONE 10(1). 1–12.
Ma, B., Wang, X., Liu, R., Jefferson, W.A., Lan, H., Liu, H. et Qu, J. (2017a). Synergistic process using Fe hydrolytic flocs and ultrafiltration membrane for enhanced antimony(V) removal. J. Membr. Sci., 537: 93–100.
Ma, B., Wang, X., Liu, R., Qi, Z., Jefferson, W.A., Lan, H., Liu, H. et Qu, J. (2017b). Enhanced antimony(V) removal using synergistic effects of Fe hydrolytic flocs and ultrafiltration membrane with sludge discharge evaluation. Water Res., 121: 171–177.
McCallum, R.I. (2005). Occupational exposure to antimony compounds. J. Environ. Monit., 7(12): 1245–1250.
McKee, J.E. et Wolf, H.W. (1963). Water quality criteria. 2nd edition. Resources Agency of California, State Water Quality Control Board. pp. 138–139.
Miao, Y., Han, F., Pan, B., Niu, Y., Nie, G. et Lv, L. (2014). Antimony(V) removal from water by hydrated ferric oxides supported by calcite sand and polymeric anion exchanger. J. Environ. Sci., 26(2): 307–314.
Miekeley, N., Mortari, S.R. et Schubach, A.O. (2002). Monitoring of total antimony and its species by ICP-MS and onl-line ion chromatography in biological samples from patients treated for leishmaniasis. Anal. Bioanal. Chem. 372: 495–502.
Ministère des Communautés, des Terres et de l'Environnement de l'Île-du-Prince-Édouard (2019). Communication personnelle avec G. Somers.
Ministère du Développement durable, de l'Environnement, de la Faune et des Parcs (2019). Communication personnelle avec P. Cantin.
Ministère de l'Environnement et des Gouvernements locaux du Nouveau-Brunswick (2019). Communication personnelle avec K. Gould.
Ministère de l'Environnement, de la Protection de la nature et des Parcs de l'Ontario (2019). Communication personnelle avec S. Deshpande.
Miranda, E.S., Miekeley, N., De-Carvalho, R.R. et Paumgartten, F.J. (2006). Developmental toxicity of meglumine antimoniate and transplacental transfer of antimony in the rat. Reprod. Toxicol., 21(3): 292–300.
Mitrakas, M., Mantha, Z., Tzollas, N., Stylianou, S., Katsoyiannis, I. et Zouboulis, A. (2018). Removal of antimony species, Sb(III)/Sb(V), from water by using iron coagulants. Water (Switzerland), 10(10).
Mlika, R.B., Hamida, M.B., Hammami, H., Jannet, S.B., Badri, T., Fenniche, S. et Mokhtar, I. (2012). Should we continue to indicate meglumine antimoniate as first-line treatment for cutaneous leishmaniasis in Tunisia. Dermat. Ther. 25: 615–618.
Mueller, M., Balasegaram, M., Koummuki, Y., Ritmeijer, K., Santana, M.R. et Davidson, R. (2006). A comparison of liposomal amphotericin B with sodium stibogluconate for the treatment of visceral leishmaniasis in pregnancy in sudan. J. Antimicrob. Chemother., 58(4): 811–815.
Multani, R.S., Feldmann, T. et Demopoulos, G.P. (2016). Antimony in the metallurgical industry: A review of its chemistry and environmental stabilization options. Hydrometallurgy, 164(Supplement C): 141–153.
Najm, I., Clark, T. et Hanson, K. (2010). Performance & cost of a full-scale antimony removal plant. AWWA WQTC & Exposition, Savannah, GA.
Najm, I., Romero, O., Gallagher, B., DeHaan, M., Busch, C., Swaim, P. et Emerson, B. (2017). Heavy metals removal to ultra-low levels – a bench-scale study. AWWA ACE, Philadelphia, PA.
Newfoundland and Labrador Department of Municipal Affairs and Environment (2019). Communication personnelle avec H. Khan.
Newton, P.E., Bolte, H. F., Daly, I.W., Pillsbury, B.D., Terrill, J.B., Drew, R.T., Ben-Dyke, R., Sheldon, A.W. et Rubin, L.F. (1994). Subchronic and chronic inhalation toxicity of antimony trioxide in the rat. Fundam. Appl. Toxicol. 22(4): 561–576.
NHMRC and NRMMC (2011). Australian drinking water guidelines - paper 6, version 3.5 updated August 2018. National Water Quality Management Strategy. National Health and Medical Research Council, National Resource Management Ministerial Council. Commonwealth of Australia, Canberra.
Nova Scotia Environment (2019). Communication personnelle avec A. Polegato.
NSF International (2021a). NSF/ANSI Standard 58: Reverse osmosis drinking water treatment systems. NSF International/American National Standards Institute. NSF International, Ann Arbor, Michigan.
NSF International (2021b). NSF/ANSI Standard 62: Drinking water distillation systems. NSF International/American National Standards Institute. NSF International, Ann Arbor, Michigan.
NSF Internationa (2021c). NSF/ANSI/CAN Standard 61: Drinking water system components—health effects. NSF International/American National Standards Institute/Standards Council of Canada, Ann Arbor, Michigan
NSF Internation (2021d). NSF/ANSI/CAN Standard 60: Drinking water treatment chemicals – health effects. NSF International/American National Standards Institute/Standards Council of Canada, Ann Arbor, Michigan
NTP (1992). NTP report on the toxicity studies of antimony potassium tartratein F344/N rats and B6C3F1 mice (drinking water and intraperitoneal injection studies). NTP TOX 11. National Toxicological Program. National Institutes of Health (NIH), No 92-3130, Research Triangle Park, NC.
NTP (2018). Report on carcinogens. National Toxicology Program. National Institute of Environmental Health Sciences. U.S. Department of Health and Human Services, Monograph on Antimony Trioxide.
OEHHA (2016). Public Health Goal for Antimony in drinking water. Office of Environmental Health Hazard Assessment. California Environmental Protection Agency, U.S.A. Disponible à https://oehha.ca.gov/media/downloads/water/chemicals/phg/antimonyphg092316_0.pdf
Okkenhaug, G., Zhu, Y.G., He, J., Li, X., Luo, L. et Mulder, J. (2012). Antimony (Sb) and arsenic (As) in Sb mining impacted paddy soil from xikuangshan, china: Differences in mechanisms controlling soil sequestration and uptake in rice. Environ. Sci. Technol., 46(6): 3155–3162.
Oliveira, A.L., Brustoloni, Y.M., Fernandes, T.D., Dorval, M.E., Cunha, R.V. et Bóia, M.N. (2009). Severe adverse reactions to meglumine antimoniate in the treatment of visceral leishmaniasis: a report of 13 cases in the southwestern region of Brazil. Trop. Doct. 39: 180–182.
Oliveira, L.F., Schubach, A.O., Martins, M.M., Passos, S.L., Oliveira, R.V., Marzochi, M.C. et Andrade, C.A. (2011). Systematic review of the adverse effects of cutaneous leishmaniasis treatment in the NewWorld. Acta Trop. 118: 87–96.
OMS (2003). Antimony in drinking-water. Background document for development of WHO guidelines for drinking-water quality (en anglais seulement). Organisation mondiale de la Santé. WHO/SDE/WSH/03.04/74.
OMS (2011). Guidelines for drinking-water quality, 4th edition (en anglais seulement). Organisation mondiale de la Santé, Genève, Suisse. Disponible à https://www.who.int/publications/i/item/9789241548151
OMS (2017). Planifier la gestion de la sécurité sanitaire de l'eau pour l'approvisionnement en eau des petites communautés : recommandations pour la gestion par étapes des risques liés à l'approvisionnement en eau potable des petites communautés. Organisation mondiale de la Santé, Genève, Suisse. Disponible à https://apps.who.int/iris/handle/10665/258755
Omura, M., Tanaka, A., Hirata, M. et Inoue, N. (2002). Testicular toxicity evaluation of two antimony compounds, antimony trioxide and antimony potassium tartrate, in rats and mice. Environ. Health. Prev. Med., 7(1): 15–18.
Oorts, K., Smolders, E., Degryse, F., Buekers, J., Gasco, G., Cornelis, G. et Mertens, J. (2008). Solubility and toxicity of antimony trioxide (Sb2O3) in soil. Environ. Sci. Technol., 42(12): 4378-4383.
Paracel Laboratories Ltd. (2019). Communication personnelle avec D. Robertson. Ottawa, ON.
Paumgartten, F.J. et Chahoud, I. (2001). Embryotoxicity of meglumine antimoniate in the rat. Reprod. Toxicol., 15(3): 327–331.
Pieper, K. (2021). Dept. Civil & Environmental Engineering, Northeastern University. Personal communication.
Poon, R., Chu, I., Lecavalier, P., Valli, V.E., Foster, W., Gupta, S. et Thomas, B. (1998). Effects of antimony on rats following 90-day exposure via drinking water. Food Chem. Toxicol., 36(1): 21–35.
Porquet, A. et Filella, M. (2007). Structural evidence of the similarity of Sb(OH)3 and As(OH)3 with glycerol: Implications for their uptake. Chem. Res. Toxicol., 20(9): 1269–1276.
Qi, P. et Pichler, T. (2016). Sequential and simultaneous adsorption of Sb(III) and Sb(V) on ferrihydrite: Implications for oxidation and competition. Chemosphere, 145: 55–60.
Qi, P. et Pichler, T. (2017). Competitive adsorption of As(III), As(V), Sb(III) and Sb(V) onto ferrihydrite in multi-component systems: Implications for mobility and distribution. J. Hazard. Mater., 330: 142–148.
Quiroz, W., Aguilar, L., Barría, M., Veneciano, J., Martínez, D., Bravo, M., Lobos, M.G. et Mercado, L. (2013). Sb(V) and Sb(III) distribution in human erythrocytes: Speciation methodology and the influence of temperature, time and anticoagulants. Talanta 115: 902–910.
Reimann, C., Matschullat, J., Birke, M. et Salminen, R. (2010). Antimony in the environment: Lessons from geochemical mapping. Applied Geochemistry, 25(2): 175–198.
Ribeiro, R.R., Ferreira, W.A., Martins, P.S., Neto, R.L.M., Rocha, O.G.F., Le Moyec, L., Demicheli, C. et Frézard, F. (2010). Prolonged absorption of antimony(V) by the oral route from non-inclusion meglumine antimoniate-beta-cyclodextrin conjugates. Biopharm Drug Dispos 31(2-3): 109–119.
Roper, S.C. et Stupart, L. (2006). The in vitro percutaneous absorption of antimony trioxide through human skin. Charles River Laboratories Rep No. 25985. 2006; pp 1–112. Charles River Laboratories, Edinburgh. As cited in EU (2008).
Saenz, R.E., de Rodriguez, C.G., Johnson, C.M. et Berman, J.D. (1991). Efficacy and toxicity of pentostam against Panamanian mucosal leishmaniasis. Am. J. Tro. Med. Hyg. 44: 394–398.
Sandvig, A., Boyd, G., Kirmeyer, G., Edwards, M., Triantafyllidou, S. et Murphy, B.M. (2007). Performance and Metal Release of Non-Leaded Brass Meters, Components, and Fittings. AWWA Research Foundation (Denver, Colorado) and EPA (Washington D.C.).
Sandvig, A., Martel, K., Beggs, K., Jaffe Murray, A., Greiner, P., Kneen, K., McLellan, C., Bennet, D. et Terrell, J. (2012). Is NSF 61 Relevant for Chloraminating Utilities? Water Research Foundation, 4243, Denver, Colorado.
Santé Canada (2013). Deuxième rapport sur la biosurveillance humaine des substances chimiques de l'environnement au Canada : Résultats de l'Enquête canadienne sur les mesures de la santé Cycle 2 (2009 à 2011). SC Pub. : 130020.
Santé Canada (2015). Recommandations pour la qualité de l'eau potable au Canada : Document technique — Le pH, Bureau de la qualité de l'eau et de l'air, Direction générale de la santé environnementale et de la sécurité des consommateurs, Santé Canada, Ottawa (Ontario), (Numéro de catalogue H144-28/2016F-PDF).
Santé Canada (2017). Communication personnelle avec Anca-Maria Tugulea, Bureau de la science et de la recherche en santé environnementale.
Santé Canada (2020). L'Étude Canadienne sur l'alimentation totale - micro éléments 1993-2018. Disponible à https://open.canada.ca/data/fr/dataset/83934503-cfae-4773-b258-e336896c2c53
Saskatchewan Water Security Agency (2019). Communication personnelle avec S. Ferris.
Sazakli, E., Zouvelou, S.V., Kalavrouziotis, I. et Leotsinidis, M. (2015). Arsenic and antimony removal from drinking water by adsorption on granular ferric oxide. Water Sci. Technol., 71(4): 622-629.
Scanlan, L. (2003). Distribution system water quality changes: A challenge. Proc. 2003 AWWA ann. conf. [citée dans U.S. EPA, 2006].
Schock, M.R. (2005). Distribution systems as reservoirs and reactors for inorganic contaminants. In: Distribution system water quality challenges in the 21st century: A strategic guide. MacPhee, M.J. (ed.). AWWA, pp. 105.
Schock, M. et Lytle, D. (2011). Chapter 20: Internal corrosion and deposition control. In: Water quality and treatment: a handbook on drinking water, 6th edition. J.K. Edzwald (ed.). McGraw Hill and American Water Works Association, Denver, Colorado.
Schroeder, H.A., Mitchener, M. et Nason, A.P. (1970). Zirconium, niobium, antimony, vanadium and lead in rats: Life term studies. J. Nutr., 100(1): 59–68.
Scinicariello, F. et Buser, M.C. (2016). Urinary antimony and leukocyte telomere length: An analysis of NHANES 1999-2002. Environ. Res., 150: 513–518.
Services aux Autochtones Canada (2019). Communication personnelle avec X. Redhead.
Shotyk, W., Krachler, M. et Chen, B. (2006). Contamination of Canadian and European bottled waters with antimony from PET containers. J. Environ. Monit., 8(2): 288–292.
Skeaff, J.M., Beaudoin, R., Wang, R. et Joyce, B. (2013). Transformation/dissolution examination of antimony and antimony compounds with speciation of the transformation/dissolution solutions. Integr. Environ. Assess. Manag., 9(1): 98–113.
Smeets, P.W.M.H., Medema, G.J. et van Dijk, J.C. (2009). The Dutch secret: how to provide safe drinking water without chlorine in the Netherlands. Drink. Water Eng. Sci., 2: 1–14.
Subramanian, K.S., Connor, J.W. et Meranger, J.C. (1991). Leaching of antimony, cadmium, copper, lead, silver, tin and zinc from copper piping with non-lead-based soldered joints. J. Environ. Sci. Health Part A Environ. Sci. Eng. Toxic Hazard. Subst. Control, 26(6): 911–929.
Subramanian, K.S., Connor, J.W. et Sastri, V.S. (1994). Drinking water quality: Impact of non-lead-based plumbing solders. Toxicol. Environ. Chem., 44(1-2): 11–20.
Sunagawa, S. (1981). Experimental studies on antimony poisoning [author's translation]. Igaku Kenkyu 3:129–142. [citée dans ECCC et Santé Canada, 2020].
Sundar, S. et Chakravarty, J. (2010). Antimony toxicity. Int. J. Environ. Res. Public. Health., 7(12): 4267–4277.
Swaim, P., Busch, C. et DeHaan, M. (2017). Removal of heavy metals to ultra-low levels with conventional treatment technologies: pilot-scale demonstration. AWWA, ACE 2017 Philadelphia, PA.
Sztajnkrycer, M.D. (2017). Antimony and Nickel. In: Critical care toxicology. chap. 79. Brent, J.e.a. (ed.). AG 2017. Springer International Publishing. DOI 10.1007/978-3-319-17900-1_46, pp. 1619–1637.
Tirmenstein, M.A., Plews, P.I., Walker, C.V., Woolery, M.D., Wey, H.E. et Toraason, M.A. (1995). Antimony-induced oxidative stress and toxicity in cultured cardiac myocytes. Toxicol. Appl. Pharmacol., 130(1): 41–47.
Turković, R., Werner, W. et Klinger, J. (2014). The Performance of nonleaded brass materials. Water Research Foundation, Denver, Colorado.
Tylenda, C.A., Sullivan, D.W. et Fowler, B.A. (2015). Antimony. In: Handbook on the toxicology of metals - chapter 27. Nordberg, G.F., Fowler, B.A. and Nordberg, M. (eds.). 4th. Academic Press, San Diego, pp. 565–579.
UE (2008). European Union Risk Assessment Report: Diantimony Trioxide. Disponible à https://echa.europa.eu/documents/10162/553c71a9-5b5c-488b-9666-adc3af5cdf5f
UE (2020). Directive (UE) 2020/2184 du Parlement européen et du Conseil du 16 décembre 2020 relative à la qualité des eaux destinées à la consommation humaine (refonte) (Texte présentant de l'intérêt pour l'EEE). Disponible à https://eur-lex.europa.eu/legal-content/FR/TXT/PDF/?uri=CELEX:32020L2184&from=FR
U.S. EPA (1992). Drinking water criteria document for antimony (final report). United States Environmental Protection Agency, Washington, DC. January 1992. Disponible à https://nepis.epa.gov/Exe/ZyPDF.cgi/901H0800.PDF?Dockey=901H0800.PDF
U.S. EPA (1994a). Method 200.8 revision 5.4 Determination of trace elements in waters and wastes by inductively coupled plasma - mass spectrometry. Environmental Monitoring Systems Laboratory. Office of Research and Development, Cincinnati, Ohio.
U.S. EPA (1994b). Method 200.9 revision 2.2 Determination of trace elements by stabilized temperature graphite furnace atomic absorption. Environmental Monitoring Systems Laboratory. Office of Research and Development. EPA, Cincinnati, Ohio.
U.S. EPA (1998). Small system compliance technology list for the non-microbial contaminants regulated before 1996. Office of Water. EPA 815-R-98-002.
U.S. EPA (2003). Method 200.5 revision 4.2 Determination of trace elements in drinking water by axially viewed inductively coupled plasma - atomic emission spectrometry. National Exposure Research Laboratory. Office of Research and Development. EPA 600-R-06-115, Cincinnati, Ohio.
U.S. EPA (2006). Inorganic contaminant accumulation in potable water distribution systems. Office of Water. Office of Ground Water and Drinking Water. Washington, DC.
U.S. EPA (2014). Method 6020B revision 2. Inductively coupled plasma - mass spectrometry. SW-846 Online: Test Methods Update V available online at: https://www.epa.gov/hw-sw846/sw-846-compendium#6000series.
U.S. EPA (2012). Radionuclides in Drinking Water, Compliance Options: Treatment Technology Descriptions. Disponible à http://cfpub.epa.gov/safewater/radionuclides/radionuclides.cfm
U.S. EPA (2018). 2018 edition of the drinking water standards and health advisories. Office of Water. U.S. Environmental Protection Agency, EPA 822-F-18-001, Washington, DC.
U.S. GS (2016). 2016 Minerals yearbook. Antimony. [advance release]. U.S. Geological Survey and U.S. Department of the Interior. Disponible à https://prd-wret.s3-us-west-2.amazonaws.com/assets/palladium/production/atoms/files/myb1-2016-antim.pdf
U.S. GS (2020). Mineral commodity summaries. U.S. Geological Survey and U.S. Department of the Interior. Disponible à https://pubs.usgs.gov/periodicals/mcs2021/mcs2021.pdf
Valli, V.E., Poon, R., Chu, I., Gupta, S. et Thomas, B.H. (2000). Comment: Subchronic/Chronic Toxicity of Antimony Potassium Tartrate. Reg Toxicol and Pharm 32, 337–338.
Vigeh, M., Yunesian, M., Matsukawa, T., Shamsipour, M., Jeddi, M.Z., Rastkari, N., Hassanvand, M.S., Shariat, M., Kashani, H., Pirjani, R., Effatpanah, M., Shirazi, M., Shariatpanahi, G., Ohtani, K. et Yokoyama, K. (2021). Prenatal blood levels of some toxic metals and the risk of spontaneous abortion. J Environ Health Sci Eng. 2021 Feb 26;19(1): 357–363.
Wang, L., Lewis, G.M. et Chen, A.S.C. (2011). Arsenic and antimony removal from drinking water by point-of-entry reverse osmosis coupled with dual plumbing distribution U.S. EPA Demonstration Project at Carmel Elementary School in Carmel, ME Final performance evaluation report. Water Supply and Water Resources Division. National Risk Management Research Laboratory EPA/600/R-11/026, Cincinnati, Ohio.
Westerhoff, P., Prapaipong, P., Shock, E. et Hillaireau, A. (2008). Antimony leaching from polyethylene terephthalate (PET) plastic used for bottled drinking water. Water Res., 42(3): 551–556.
Wise, E.S., Armstrong, M.S., Watson, J. et Lockwood, D.N. (2012). Monitoring toxicity associated with parenteral sodium stibogluconate in the day-case management of returned travelers with New World cutaneous leishmaniasis. PLoS Negl. Trop. Dis. 6:e1688.
Wu, Z., He, M., Guo, X. et Zhou, R. (2010). Removal of antimony (III) and antimony (V) from drinking water by ferric chloride coagulation: Competing ion effect and the mechanism analysis. Sep. Purif. Technol., 76(2): 184–190.
Xi, J., He, M., Wang, K. et Zhang, G. (2013). Adsorption of antimony(III) on goethite in the presence of competitive anions. J. Geochem. Explor., 132: 201–208.
Zietz, B.P., Richter, K., Laß, J., Suchenwirth, R. et Huppmann, R. (2015). Release of metals from different sections of domestic drinking water installations. Water Qual. Expos. Health, 7(2): 193–204.
Liste des abréviations
AH : acide humique
ANSI : American National Standards Institute
AQA : Apport quotidien acceptable
As : arsenic
ATSDR : Agency for Toxic Substances and Disease Registry
CCN : Conseil canadien des normes
CF : chlorure de fer(III)relargage
CIRC : Centre international de recherche sur le cancer
CMA : concentration maximale acceptable
DL50 : dose létale médiane relargage
DRO : dérivé réactif de l'oxygène
ECCC : Environnement et Changement climatique Canada
Fe : fer
Fe(OH)3 : hydroxyde de fer (III)
GI : gastro-intestinal
ICP-MS : spectrométrie de masse à plasma inductif
LD : limite de détection
LDM : limite de détection de la méthode
LOAEL : dose minimale avec effet nocif observé
LOEL : dose minimale avec effet observé
Mn : manganèse
MON : matière organique naturelle
N : taille de l'échantillon
n.d. : non disponible
no du CAS : numéro de registre du Chemical Abstract Service
NOAEL : dose sans effet nocif observé
NSF : NSF International
OEHHA : Office of Environmental Health Hazard Assessment (U.S. EPA – Californie)
OI : osmose inverse
OMS : Organisation mondiale de la Santé
p.c. : poids corporel
Pb : plomb
PD : point de départ
PET : polyéthylène de téréphtalate
PTM : pression transmembranaire
Sb : antimoine
Sb(III) : antimoine trivalent
Sb(V) : antimoine pentavalent
SDM : seuil de déclaration de la méthode
TAP : tartrate d'antimoine et de potassium
TiO2 : dioxyde de titane
TOA : trioxyde d'antimoine
U.S. EPA : United States Environmental Protection Agency (États-Unis)
uTN : unité de turbidité néphélémétrique
VBS : valeur basée sur la santé
VL : volume du lit
Détails de la page
- Date de modification :