clarify forces that control pH-dependent aggregation of nonionic glycolipid
vesicles, we have measured forces between layers of a nonionic glycolipid,
1,3 -di- O-phytanyl-2-O-(beta-(D)-maltotriosyl)glycerol, Mal(3)(Phyt)(2),
in two different pH conditions, pH 4 and pH,9.8. Mal(3)(Phyt)(2) vesicles r
apidly aggregate at pH4, but the vesicle dispersion is stable at pH 9.8 (se
e: J. Colloid Interface Sci. 2000, 223, 235.). At pH 4, the lipid layers we
re attracted by van der Waals forces at long distances, whereas at short di
stances they were repelled by "hydration" forces. Practically no double-lay
er force was observed at pH 4. At pH 9.8, on the other hand, the double-lay
er force associated mainly with "adsorption" of OH- ions at the lipid surfa
ce was superposed on the core,interactions, the van der Waals forces, and t
he hydration forces. The force data indicate that the changes in pH, althou
gh affecting the double-layer force, have a negligible influence on the ran
ge of the hydration forces and the magnitude of the adhesion forces between
the Mal(3)(Phyt)(2) layers. It is therefore the double-layer force that co
ntrols the pH-dependent stability of the Mal(3)(Phyt)(2) vesicle dispersion
. Commonly assumed hydration-based mechanisms such as an ion-induced interf
acial dehydration and/or an ion-induced decrease in hydration forces do not
appear relevant to the present case.