The association between the initial adhesion and cyanobacterial biofilm development.

Although laboratory assays provide valuable information about the antifouling effectiveness of marine surfaces and the dynamics of biofilm formation, they may be laborious and time-consuming. This study aimed to determine the potential of short-time adhesion assays to estimate how biofilm development may proceed. The initial adhesion and cyanobacterial biofilm formation were evaluated using glass and a polymer epoxy resin surface at two hydrodynamic conditions and compared using linear regression models. For initial adhesion, the polymer epoxy resin surface was significantly associated with a lower number of adhered cells when compared to glass (-1.27×105 cells.cm-2). Likewise, the number of adhered cells was significantly lower (-1.16×105 cells.cm-2) at 185 than at 40 rpm. This tendency was maintained during biofilm development and was supported by the biofilm wet weight, thickness, chlorophyll α content, and structure. Results indicated a significant correlation between the number of adhered and biofilm cells (r = 0.800, p <0.001). Moreover, the number of biofilm cells on day 42 was dependent on the number of adhered cells at the end of the initial adhesion and hydrodynamic conditions (R2 = 0.795, p <0.001). These findings demonstrated the high potential of initial adhesion assays to estimate marine biofilm development.