A high-pressure size-exclusion chromatography procedure for separation of activated sludge exopolymers was investigated and implemented in order to achieve a documented and faster separation procedure than the conventional low-pressure size-exclusion chromatography methods previously suggested in studies of activated sludge exopolymers. Exopolymers originating from activated sludges from a traditional and an advanced activated sludge treatment plant performing biological nitrogen and phosphorus removal were used. For both types of exopolymers the separation was largely dependent on the mobile-phase. Using NaCl and ortho-phosphate in the molar proportion 10:1 it was shown that for a mobile-phase ionic strength of 0.011 and pH in the range 7.0-10.0 no irreversible column adsorption occurred. For a standard procedure a mobile-phase pH of 7.0 was selected in order to separate the exopolymers into the maximal number of peaks. Alterations in the mobile-phase, i.e. using a pH below 7.0 or a mobile-phase ionic strength above 0.011, changed the separation for both types of exopolymers and caused irreversible column adsorption. Similarly, using deionized water as the mobile-phase irreversible column adsorption was introduced and the separation was strongly affected. The method applicability for qualitative characterization of exopolymers was demonstrated. The method was found to be successful in showing differences and similarities between exopolymers from two different activated sludge treatment plants, showing degradation of exopolymer compounds due to exoenzymes in the exopolymers and showing that snow melting and subsequent high conductivity in the inlet to the waste-water treatment plant had an impact on the chromatographic fingerprint of the extracted exopolymers.