International Conference on Antimicrobial Research (ICAR 2012)
Abstract
Drinking water (DW) distribution systems are known to harbour biofilms even in the presence of disinfectants.
DW biofilms are constituted by microbial communities adapted to low nutrient concentrations and high chlorine
levels. Biofilm formation and resistance to disinfection have been recognized as important factors that contribute
to the survival and persistence of microbial contamination in DW.
The purpose of this work was the comparison of diverse methods to assess the disinfection of biofilms formed by
six DW-isolated opportunistic bacteria (Acinetobacter calcoaceticus, Burkholderia cepacia, Methylobacterium
sp., Mycobacterium mucogenicum, Sphingomonas capsulata and Staphylococcus sp.) by sodium hypochlorite
(SHC). Single and multi-species biofilms (composed of combinations of 6 and 5 bacteria) were developed in 96-
wells microtiter plates for 3 days, afterwards, were exposed to several independent SHC concentrations (0.1, 0.5,
1 and 10 mg/L) during 1 h. The potential of biofilms to recover was assessed 24 h after disinfection. The
disinfection efficacy and recovery were assessed in terms of variation in: biofilm mass (crystal violet staining);
metabolic activity (XTT staining); cultivability (CFUs) and viability (Live/Dead staining).
The results indicated that biomass removal increased with increasing SHC concentration, but total biofilm mass
removal was not achieved. The effects of SHC on the biofilm activity, cultivability and viability were also
concentration dependent. Total biofilm inactivation was achieved only for A. calcoaceticus biofilms and for
multi-species biofilms without A. calcoaceticus, when exposed to high SHC concentrations. Almost all multispecies
biofilms were more resistant to removal and inactivation than the single biofilms. Methylobacterium sp.
and A. calcoaceticus formed the most resistant and the most susceptible biofilms, respectively. On the other
hand, biofilm combination with the six DW bacteria was the most resistant to SHC and combination without A.
calcoaceticus was the least resistant, for all concentration tested. The several methods used to assess of biofilm
activity (metabolic activity, cultivability and viability) provided comparable results. However the viability results
provide the worst case scenario in terms of biofilm control analysis (higher number of viable cells for all the
SHC concentrations tested). The recovery results demonstrated that only biofilms without A.calcoaceticus were
not able to recover their biomass from the SHC treatments. Also, those biofilms had a decreased ability to
recover their metabolic activity, cultivability and viability. Conversely, multi-species biofilms without
Staphylococcus sp. had the highest ability to recover from disinfection. Biofilm mass and activity recovery were
not correlated for all the biofilms tested. However, the data of biofilm recovery in terms of metabolic activity,
cultivability and viability also provided comparable results