Disjoining Pressure and Film Tension in Comb−Graft Copolymer-Stabilized Oil Films

Anklam, Mark R.; Saville, D. A.; Prud'homme, Robert Krafft

doi:10.1021/la9901581

Cited by 19 publications

(21 citation statements)

References 37 publications

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“…At equilibrium, the disjoining pressure will match the pressure applied at the membrane surface from within the droplets. This may be approximated as a combination of the pressure from the electric field (equation (3.1)) and the Laplace pressure [49]:…”

Section: Influence Of Cholesterol On Membrane Tension During Electrocompressionmentioning

confidence: 99%

A new approach for investigating the response of lipid membranes to electrocompression by coupling droplet mechanics and membrane biophysics

El-Beyrouthy

Makhoul-Mansour

Taylor

et al. 2019

J. R. Soc. Interface.

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A new method for quantifying lipid–lipid interactions within biomimetic membranes undergoing electrocompression is demonstrated by coupling droplet mechanics and membrane biophysics. The membrane properties are varied by altering the lipid packing through the introduction of cholesterol. Pendant drop tensiometry is used to measure the lipid monolayer tension at an oil–water interface. Next, two lipid-coated aqueous droplets are manipulated into contact to form a bilayer membrane at their adhered interface. The droplet geometries are captured from two angles to provide accurate measurements of both the membrane area and the contact angle between the adhered droplets. Combining the monolayer tension and contact angle measurements enables estimations of the membrane tension with respect to lipid composition. Then, the membrane is electromechanically compressed using a transmembrane voltage. Electrostatic pressure, membrane tension and the work necessary for bilayer thinning are tracked, and a model is proposed to capture the mechanics of membrane compression. The results highlight that a previously unaccounted for energetic term is produced during compression, potentially reflecting changes in the lateral membrane structure. This residual energy is eliminated in cases with cholesterol mole fractions of 0.2 and higher, suggesting that cholesterol diminishes these adjustments.

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Section: Influence Of Cholesterol On Membrane Tension During Electrocompressionmentioning

confidence: 99%

A new approach for investigating the response of lipid membranes to electrocompression by coupling droplet mechanics and membrane biophysics

El-Beyrouthy

Makhoul-Mansour

Taylor

et al. 2019

J. R. Soc. Interface.

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“…This will provide a bridge between the present work and more traditional studies of the interfacial properties RGCs. 28,29 …”

Section: Theorymentioning

confidence: 99%

Micelle formation of randomly grafted copolymers in slightly selective solvents

Kreig¹,

Lefebvre

Hahn

et al. 2001

The Journal of Chemical Physics

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Articles you may be interested inDepletion-induced surface alignment of asymmetric diblock copolymer in selective solvents Amphiphilic surfactants, molecules with chemical moieties that interact differently with the solvating medium, are important for technological applications and ubiquitous in biology. Understanding how to control surfactant properties is, therefore, of wide-ranging importance. Using a combination of light scattering experiments and field theory, we demonstrate that the behavior of polymeric surfactants can be controlled sensitively by manipulating molecular architecture. We find that branched polymeric amphiphiles can be much better surfactants than traditional linear analogs. This is indicated by micelle formation in solvents that are very slightly selective for the backbone of the branched molecule. Our experimental and theoretical findings also suggest that, for a given chemistry and architectural class, surfactant properties of polymeric amphiphiles are very sensitive to subtle changes in architectural features. Specifically, we find that choosing a particular branching density optimizes the propensity for micelle formation. The sensitivity of macromolecular surfactant properties to molecular architecture can perhaps be profitably exploited in applications wherein only certain chemical moieties are allowed. The physical origin of this sensitivity is the importance of conformational entropy penalties associated with the pertinent self-assembly process. This is in contrast to self-assembly of small molecule systems where conformational entropy is not of such significance.

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“…The electric field in the oil film in this case is equal to V /δ [15][16][17]. This electric field gives rise to oppositely directed Maxwell stresses at each of the oil-water interfaces [16].…”

Section: Electric Breakdown Of Filmsmentioning

confidence: 96%

“…While lecithin is a mixture of few relatively small molecules with a molecular weight of about 800 Da (Daltons), tegopren has a substantially larger molecular weight close to 60 kDa. The thickness of a lecithin bilayer is about 4-9 nm whereas in tegopren, the thickness reaches from 40 to 60 nm [17,26]. Thus, the high critical potential for tegopren might be owing to the relatively larger thickness of a tegopren stabilized film.…”

Section: Critical Potentialmentioning

confidence: 99%

A microfluidic electrochemical detection technique for assessing stability of thin films and emulsions

Mostowfi

Czarnecki

Masliyah

et al. 2008

Journal of Colloid and Interface Science

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Disjoining Pressure and Film Tension in Comb−Graft Copolymer-Stabilized Oil Films

Cited by 19 publications

References 37 publications

A new approach for investigating the response of lipid membranes to electrocompression by coupling droplet mechanics and membrane biophysics

A new approach for investigating the response of lipid membranes to electrocompression by coupling droplet mechanics and membrane biophysics

Micelle formation of randomly grafted copolymers in slightly selective solvents

A microfluidic electrochemical detection technique for assessing stability of thin films and emulsions

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