462 SECTION | V Metals and Micronutrients




  VetBooks.ir  Mitsumori, K., Hirano, M., Ueda, H., et al., 1990. Chronic toxicity and  Sokolowski,  K.,  Falluel-Morel,  A.,  Zhou,  at  low  al.,  2011.
                                                                                                 X.,
                                                                                                     et
                                                                  Methylmercury (MeHg) elicits mitochondrial-dependent apoptosis
                carcinogenicity of methylmercury chloride in B6C3F1 mice. Fund.
                                                                              hippocampus
                                                                  in
                                                                     developing
                Appl. Toxicol. 14, 179 190.
                                                                                         and
                                                                                                        exposures.
                                                                                             acts
                                                                  NeuroToxicology. 32, 535 544.
             Mitsumori, K., Maita, K., Saito, T., et al., 1981. Carcinogenicity of
                methylmercury chloride in ICR mice: preliminary note on renal car-  Solecki, R., Hothorn, L., Holzweissig, M., et al., 1991. Computerized
                cinogenesis. Cancer Lett. 12, 305 310.            analysis of pathological findings in long-term trials with phenylmer-
             Miyakawa, T., Murayama, E., Sumiyoshi, S., et al., 1976. Late changes  curic acetate in rats. Arch. Toxicol. 14 (Suppl.), 100 103.
                in human sural nerves in Minamata disease and in nerves of rats  Taber, K.H., Hurley, R.A., 2008. Mercury exposure: effects across the
                with experimental organic mercury poisoning. Acta Neuropathol.  lifespan. J. Neuropsychiatr. Clin. Neurosci. 20, 384 389.
                Berlin. 35, 131 138.                            Takemoto, T., Ishihara, Y., Ishida, A., et al., 2015. Neuroprotection eli-
             Ni, M., Li, X., dos Santos, A.P.M., et al., 2017. Mercury. In: Gupta, R.  cited by nerve growth factor and brain-derived neurotrophic factor
                C. (Ed.), Reproductive and Developmental Toxicology. Academic  released from astrocytes in response to methylmercury. Environ.
                Press/Elsevier, Amsterdam, pp. 583 594.           Toxicol. Pharmacol. 40, 199 205.
             NTP, 1993. Toxicology and Carcinogenesis Studies of Mercuric  Tan, S.W., Meiller, J.C., Mahaffey, K.R., 2009. The endocrine effects of
                Chloride (CAS No. 7487-94-7) in F344/N Rats and B6C3F1 Mice  mercury in humans and wildlife. Crit. Rev. Toxicol. 39, 228 269.
                (Gavage Studies). National Toxicology Program, U.S. Department  Thuvander, A., Sundberg, J., Oskarsson, A., 1996. Immunomodulating
                of Health and Human Service, National Institutes of Health,  effects after perinatal exposure to methylmercury in mice.
                Research Triangle Park, NC. NTP TR 408. NIH Publication No. 91-  Toxicology. 114, 163 175.
                3139.                                           Tsubaki, T., Krukuyama, K., 1977. Minamata Disease. Elsevier
             Pletz, J., Sa ´nchez-Bayo, F., Tennekes, H.A., 2016. Dose-response analy-  Scientific Publ. Co, Amsterdam.
                sis indicating time-dependent neurotoxicity caused by organic and  Tsubaki, T., Takahashi, H., 1986. Recent Advances in Minamata Disease
                inorganic mercury- Implications for toxic effects in the developing  Studies. Kodansha, Tokyo.
                brain. Toxicology. 347, 1 5.                    Vahter, M., Mottet, N.K., Friberg, L., et al., 1994. Speciation of mercury
             Puls, R., 1994. Mineral Levels in Animal Health: Diagnostic Data. sec-  in the primate blood and brain following long-term exposure to
                ond ed. Sherpa International, Clearbrook, BC, pp. 184 191.  methylmercury. Toxicol. Appl. Pharmacol. 124, 221 229.
             Ray, P.D., Yoshim, A., Fry, R.C., 2014. Incorporating epigenetic data  Verschuuren, H.G., Kroes, R., Den Tonkelaar, E.M., et al., 1976.
                into the risk assessment process for the toxic metals arsenic, cad-  Toxicity of methylmercury chloride in rats. III. Long-term toxicity
                mium, chromium, lead, and mercury: strategies and challenges.  study. Toxicology. 6, 107 123.
                Front. Genet. 5, 201.                           Vitalone, A., Catalani, A., Cinque, C., et al., 2010. Long-term effects of
             Sager, P.R., Doherty, R.A., Olmsted, J.B., 1983. Interaction of methyl-  developmental exposure to low doses of PCB 126 and methylmer-
                mercury with microtubules in cultured cells and in vitro. Exp. Cell  cury. Toxicol. Lett. 197, 38 45.
                Res. 146, 127 137.                              Wakita, Y., 1987. Hypertension induced by methylmercury in rats.
             Schuh, J.C.L., Ross, C., Meschter, C., 1988. Concurrent mercuric blister  Toxicol. Appl. Pharmacol. 89, 144 147.
                and dimethyl sulfoxide (DMSO) application as a cause of mercury  Willes, R.F., Truelove, J.F., Nera, E.A., 1978. Neurotoxic response of
                toxicity in two horses. Equine Vet. J. 20, 68 71.  infant monkeys to methylmercury. Toxicology. 9, 125 135.
             Sharma, B., Singh, S., Siddiqi, N.J., 2014. Biomedical implications of  Yilmaz, F.M., Yilmaz, H., Tutkun, E., et al., 2014. Serum biochemical
                heavy metals induced imbalances in redox systems. Biomed. Res.  markers of central nervous system damage in children with acute
                Int. 640754.                                      elemental mercury intoxication. Clin. Toxicol. 52, 32 38.