| AVS 60th International Symposium and Exhibition | |
| Biomaterial Interfaces | Monday Sessions |
| Session BI+AI+BA+IS-MoA |
| Session: | Biofouling |
| Presenter: | S.A. Wade, Swinburne University of Technology, Australia |
| Authors: | M.A. Javed, Swinburne University of Technology, Australia P.R. Stoddart, Swinburne University of Technology, Australia S.M. McArthur, Swinburne University of Technology, Australia S.A. Wade, Swinburne University of Technology, Australia |
| Correspondent: | Click to Email |
Biofouling of surfaces causes numerous problems in a wide range of industries such as shipping, health care, oil and gas production and food production. Of specific interest to the current work is the accelerated corrosion of metals that can arise as a consequence of bacterial biofilm formation, which is commonly known as microbiologically influenced corrosion (MIC).
The initial attachment of bacteria to a surface is one of the first steps in the process of biofouling. The attachment is dependent upon a large number of factors, which are broadly related to the properties of the bacteria, substrate/surface and environment. Changes in these properties can not only influence the initial attachment step, but also the interrelated production of extracellular polymeric substances (EPS) by the bacteria and the subsequent corrosion.
A large amount of the work performed to date on bacterial attachment in relation to MIC has focused on stainless steels, possibly due to reports of rapid failures of these materials such as through thickness pitting of piping welds. These studies have highlighted how a range of material properties (e.g. chemical composition, surface roughness, grain size and boundaries) can influence attachment and biofilm formation on steel surfaces. This range of influences means that a high level of care must be taken when designing and carrying out bacterial attachment tests in order to avoid the situation where a number of material variables affect the outcome of a single test. For example one of the criticisms of some of the previous work in this area is the lack of control of surface roughness of the substrates used in the studies.
In this work we will report results of studies of the initial attachment and EPS production of E. coli bacteria on highly polished carbon steel samples, with a number of different microstructures, for a number of different test media. We have found that the microstructure and test medium can have a significant effect on the rate of bacterial attachment, the distribution of attached bacteria, the onset of EPS production and the corrosion of samples immersed in E. coli inoculated test media.