Electrochemical activity and bacterial diversity of natural marine biofilm in laboratory closed-systems
Faimali, M.; Chelossi, E.; Pavanello, G.; Benedetti, A.; Vandecandelaere, I.; De Vos, P.; Vandamme, P.; Mollica, A. (2010). Electrochemical activity and bacterial diversity of natural marine biofilm in laboratory closed-systems. Bioelectrochemistry 78(1): 30-38. dx.doi.org/10.1016/j.bioelechem.2009.04.012
In: Bioelectrochemistry. Elsevier: Oxford. ISSN 1567-5394; e-ISSN 1878-562X, more
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Keyword |
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Author keywords |
Electrochemically active biofilms; Ennoblement; Cathodic potential;Cathodic depolarization; Bacterial diversity |
Authors | | Top |
- Faimali, M.
- Chelossi, E.
- Pavanello, G.
- Benedetti, A.
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- Vandecandelaere, I., more
- De Vos, P., more
- Vandamme, P., more
- Mollica, A.
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Abstract |
Even if a widely shared mechanism actually does not exist, it is now generally accepted that, in aerobic conditions, marine electrochemically active biofilms (MEABs) induce faster oxygen reduction on stainless steel immersed in seawater. This phenomenon has been widely studied, but nearly all the experiments found in literature have been conducted in open-systems (i.e. experimental environments where seawater is constantly renewed). In this work we tried to obtain, in open circuit and potentiostatic conditions, MEABs in different laboratory closed-systems without water renewal (mesocosms), in order to verify the relationship between electrochemical activity and biofilm composition The diversity of the microbial populations of biofilms obtained by our new kind of approach was examined by the DGGE technique (denaturing gradient gel electrophoresis). MEABs were obtained in all the mesocosms from 2000 to 2 L, showing in some cases electrochemical performances comparable to those of open-systems, and a very high genetic variability Our DGGE results underline the difficulty in finding a correlation between electrochemical activity and composition of microbial populations. |
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