Marine microalgal biofilm development and its adhesion propensities on commercial membrane via XDLVO approach

An emerging biofilm immobilization method has enabled effortless biomass harvesting and promoted economic feasibility. The current limitation towards the adaptation of this technology is the inadequate understanding of the biofilm interaction towards microporous membrane. Cell adhesion is recognized as the most important step towards the immobilized cultivation of microalgae. Cell attachment kinetic was studied in a short-term batch culture of three marine diatoms, Amphora coffeaeformis, Cylindrotheca fusiformis and Navicula incerta over 96 h on submerged commercial polyvinylidene fluoride (PVDF) membrane under swirling motion of culture medium. Both the evolution of cell adhesion intensity and compositional changes of the extracellular polymeric substances (EPS) released were quantified throughout the cultivation period. To delve into the cell-substratum interactions, existing thermodynamics and colloidal extended Derjaguin, Landau, Vervey, and Overbeek (XDLVO) theory were employed. As a result, A. coffeaeformis and N. incerta recorded a higher cell colonization percentage than C. fusiformis being the lowest about 2.16±0.17% cell colonization due to their respective species-dependent EPS variation. Polysaccharide contents were at least two times higher than protein contents for both C. fusiformis and N. incerta except for A. coffeaeformis depicting a lower polysaccharide-to-protein ratio whereby the protein contents were maximized at 1.03 × 103 ± 64.14 pg m-2 cell-1 at 6th h. From the surface free energy point of view, both thermodynamics and XDLVO model elucidated that cells adhered reversibly in the secondary energy minimum and ranked C. fusiformis the lowest adhesion tendency among three. These findings establish fundamental knowledge about biofilm formation in porous substrate bioreactors.