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Phytotoxicity of triclosan in systems of different biological complexityFranz, Stephanie 23 August 2013 (has links) (PDF)
Triclosan (TCS) is a personal care product with many fields of application and is of public interest for several years now. Monitoring studies showed that TCS is a ubiquitous chemical in the aquatic environment. Aquatic organisms are exposed to TCS in a broad range of concentrations, from ng L-1 up to lower μg L-1. TCS has a bactericidal effect for various types of gram-positive and gram negative bacteria. TCS targets a specific bacterial fatty acid biosynthetic enzyme, enoyl-[acyl-carrier protein] reductase (Schweizer, 2001). Therefore the terminal reaction in the fatty acid elongation cycle is inhibited (Levy et al., 1999). Although effects on non-target organisms are reported, the Mode of Action (MoA) of TCS is not well examined for those organisms.
The aim of this PhD thesis was to investigate effects of TCS on non-target autotrophic organisms at different levels of biological complexity in the aquatic environment. In this thesis microalgae have been found to be very sensitive to TCS. In some cases even higher sensitivities than in bacteria were observed, which is in accordance with published effect data (Harada et al., 2008; Orvos et al., 2002). Similarly to bacteria, high species sensitivity differences were observed for algae (Franz et al., 2008). In bacteria these sensitivity differences can be ascribed to several resistance mechanisms reported in Schweizer (2001). These findings lead to the question about the reasons for species sensitivity differences in algae. A mesocosm study was performed to detect effects of TCS across levels of biological organization and to investigate the impact of sensitivity differences on complex aquatic communities. For that purpose, structural and functional effects parameters were observed.
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Phytotoxicity of triclosan in systems of different biological complexity: causal analysis of sensitivity differences of microalgaeFranz, Stephanie 10 July 2013 (has links)
Triclosan (TCS) is a personal care product with many fields of application and is of public interest for several years now. Monitoring studies showed that TCS is a ubiquitous chemical in the aquatic environment. Aquatic organisms are exposed to TCS in a broad range of concentrations, from ng L-1 up to lower μg L-1. TCS has a bactericidal effect for various types of gram-positive and gram negative bacteria. TCS targets a specific bacterial fatty acid biosynthetic enzyme, enoyl-[acyl-carrier protein] reductase (Schweizer, 2001). Therefore the terminal reaction in the fatty acid elongation cycle is inhibited (Levy et al., 1999). Although effects on non-target organisms are reported, the Mode of Action (MoA) of TCS is not well examined for those organisms.
The aim of this PhD thesis was to investigate effects of TCS on non-target autotrophic organisms at different levels of biological complexity in the aquatic environment. In this thesis microalgae have been found to be very sensitive to TCS. In some cases even higher sensitivities than in bacteria were observed, which is in accordance with published effect data (Harada et al., 2008; Orvos et al., 2002). Similarly to bacteria, high species sensitivity differences were observed for algae (Franz et al., 2008). In bacteria these sensitivity differences can be ascribed to several resistance mechanisms reported in Schweizer (2001). These findings lead to the question about the reasons for species sensitivity differences in algae. A mesocosm study was performed to detect effects of TCS across levels of biological organization and to investigate the impact of sensitivity differences on complex aquatic communities. For that purpose, structural and functional effects parameters were observed.
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