Nuclear Magnetic Resonance Investigation of the Effect of pH on Micelle Formation by the Amino Acid‐Based Surfactant Undecyl l‐Phenylalaninate
Abstract
Micelle formation by the anionic amino acid‐based surfactant undecyl l‐phenylalaninate (und‐Phe) was investigated as a function of pH in solutions containing either Na+, l‐arginine, l‐lysine, or l‐ornithine counterions. In each mixture, the surfactant's critical micelle concentration (CMC) was the lowest at low pH and increased as solutions became more basic. Below pH 9, surfactant solutions containing l‐arginine and l‐lysine had lower CMC than the corresponding solutions with Na+ counterions. Nuclear magnetic resonance (NMR) diffusometry and dynamic light scattering studies revealed that und‐Phe micelles with Na+ counterions had hydrodynamic radii of approximately 15 Å throughout the investigated pH range. Furthermore, l‐arginine, l‐lysine, and l‐ornithine were found to bind most strongly to the micelles below pH 9 when the counterions were cationic. Above pH 9, the counterions became zwitterionic and dissociated from the micelle surface. In und‐Phe/l‐arginine solution, counterion dissociation was accompanied by a decrease in the hydrodynamic radius of the micelle. However, in experiments with l‐lysine and l‐ornithine, micelle radii remained the same at low pH when counterions were bound and at high pH when they were not. This result suggested that l‐arginine is attached perpendicular to the micelle surface through its guanidinium functional group with the remainder of the molecule extending into solution. Contrastingly, l‐lysine and l‐ornithine likely bind parallel to the micelle surface with their two amine functional groups interacting with different surfactant monomers. This model was consistent with the results from two‐dimensional ROESY (rotating frame Overhauser enhancement spectroscopy) NMR experiments. Two‐dimensional NMR also showed that in und‐Phe micelles, the aromatic rings on the phenylalanine headgroups were rotated toward the hydrocarbon core of micelle.
Document Details
- Document Type
- Pub Defense Publication
- Publication Date
- Jan 01, 2018
- Source ID
- 10.1002/jsde.12015
Entities
People
- Chelsea Reuter‐seng
- Elisabeth A. Rutter
- Eugene J. Billiot
- Fereshteh H. Billiot
- Gabriel A. Rothbauer
- Kevin F. Morris
- Simon Vera
- Yayin Fang
Organizations
- Carthage College
- Howard University
- Office of Naval Research