Development of a hyphenated analytical methodology for the fractionation and characterization of environmental colloids

Natural colloids are defined as macromolecules and nanoparticles with sizes ranging between 1 nm and 1 µm. Colloidal pool is complex "ill-defined" mixture of humic substances, exopolymeric substances (EPS), inorganic oxides, clays, etc. Aquatic colloids have been recognized as key mediators in the removal of trace elements, facilitating contaminant transport, organic carbon cycling and micronutrient bioavailability. The residence times of the colloidal pool (and associate contaminants) can be order of magnitude different from those of the particulate fraction, but unlike the "truly" dissolved fraction, can be subjected to different coagulation and sedimentation processes. Colloids may also influence metal bioavailability by affecting free metal ion concentrations, constraining diffusion and affecting the dissociation kinetics of biological processes. The important environmental role of natural colloids is largely influenced by their surface area and closely related colloidal size. Nonetheless, it is currently unclear to what extend colloidal size can influence their behaviour and contaminant (e.g. toxic metals) binding properties. In our view this is partially related to the difficulties in determination of the colloidal size distributions and their impact in metal behaviour, mainly due to the inherent heterogeneity of the environmental colloids and their low concentrations in the environment. Furthermore, in addition to average parameters, there is a lack of appropriate sample collection and processing procedures, as well as analytical techniques to measure simultaneously the size (or related parameter) distributions of the colloid associated metal. The objective of the present work was therefore to develop sensitive analytical procedures for the fractionation of natural colloids and to apply them to improve the current understanding on the fate of the colloids and associated toxic metals in the freshwaters. To achieve these goals, the capabilities of asymmetric flow-field flow fractionation (aFlFFF) coupled to several detectors was explored. aFlFFF is a versatile technique separating colloids according to their diffusion coefficient. The system was hyphenated with multi-angle laser light scattering (MALS), differential refractive index (DRI), UV detector and, when necessary, high resolution inductively coupled plasma mass spectrometry (ICP-MS). Correct interpretation of the experimental results and extrapolation of meaningful molecular parameters by using an analytical tool with such a level of complexity requires improvement of the knowledge of colloids behaviour in the aFlFFF channel and careful optimization of the separation conditions. Given the very complex and dynamic nature of environmental colloids, different experimental procedures was first optimized and validate under lab conditions by using "standardized" colloids (e.g. alginate and EPS isolate from lab bacterial cultures), then applied to characterize colloidal organic matter (COM)