1 Colloids and Biological Interfaces Group, Self-organizing materials for nanotechnology Section, Department of Micro- and Nanotechnology, Technical University of Denmark2 Self-organizing materials for nanotechnology Section, Department of Micro- and Nanotechnology, Technical University of Denmark3 Department of Micro- and Nanotechnology, Technical University of Denmark4 Department of Chemistry, Technical University of Denmark5 University of Southern Denmark
The classical micro-pipette aspiration technique, applied for measuring the membrane bending elasticity, is in the present work reviewed and extended to span the range of pipette aspiration pressures going through the °accid (low pressures) to tense (high pressures) membrane regime. The quality of the conventional methods for analysing data is evaluated using numerically generated data and a new method for data analysis, based on thermodynamic analysis and detailed statistical mechanical modelling, is introduced. The analysis of the classical method, where the membrane bending modulus is obtained from micro-pipette aspiration data acquired in the low-pressure regime, reveals a signi¯cant correction from membrane stretching elasticity. The new description, which includes the full vesicle geometry and both the membrane bending and stretching elasticity, is used for the interpretation of micro-pipette aspiration experiments conducted on SOPC (stearoyl-oleoyl-phosphatidyl-choline) lipid vesicles in the °uid phase. The data analysis, which is extended by detailed image analysis and a ¯tting procedure based on Monte Carlo integration, gives an estimate of the bending modulus, that agrees with previously published results obtained by the use of shape °uctuation analysis of giant unilamellar vesicles. The obtained estimate of the area expansion modulus, is automatically corrected for contributions from residual thermal undulations and the equilibrium area of the vesicle is resolved.
European Physical Journal E. Soft Matter, 2004, Vol 14, p. 149-167
Membranes; Interfaces; Microscopy of surfaces; Bilayers; Interface and surface thermodynamics