Self-assembly of model short triblock amphiphiles in dilute solution

Zaldívar, Gervasio; Samad, Mehdi Bin; Conda‐Sheridan, Martin; Tagliazucchi, Mario

doi:10.1039/c8sm00096d

Cited by 13 publications

(21 citation statements)

References 45 publications

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“…The possibility of molecular reorganization depends also on the strength of the β -sheet hydrogen bonds of the peptides. Only by a large structural transition, which involves enthalpic and entropic penalties, from a cylindrical nanofiber to a spherical micelle can the electrostatic penalty be reduced ( Israelachvili, 2011 ; Zaldivar et al, 2018 ; Zaldivar et al, 2019 ). This occurs experimentally for pH above 8.…”

Section: Resultsmentioning

confidence: 99%

“…Very noteworthy are the recent theoretical investigations by Zaldivar et al, who applied the same Molecular Theory approach to self-assemble of peptide amphiphiles and demonstrated the structural transitions between bilayer, cylindrical, and spherical structured nanofibers can occur as a function of pH ( Zaldivar et al, 2018 ; Zaldivar et al, 2019 ). Observe they opted to represent the peptide amphiphiles with much more coarse-graining.…”

Section: Summary and Concluding Remarksmentioning

confidence: 99%

“…Likewise, a similar approach was used to investigate the effect of solution conditions on the charge regulation of bacteriophage capsids ( Nap et al, 2014a ) and the absorption of acidic ligands to quantum dots ( Westmoreland et al, 2019 ). Also noteworthy is a recent study by Tagliazucchi et al in which the molecular theory was used to study the self-assembly of neutral and chargeable peptide amphiphiles ( Zaldivar et al, 2018 ; Zaldivar et al, 2019 ). However, ion-condensation and effects related to the electrostatic solvation free energy were not considered.…”

Section: Introductionmentioning

confidence: 99%

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Acid-Base Equilibrium and Dielectric Environment Regulate Charge in Supramolecular Nanofibers

et al. 2022

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Peptide amphiphiles are a class of molecules that can self-assemble into a variety of supramolecular structures, including high-aspect-ratio nanofibers. It is challenging to model and predict the charges in these supramolecular nanofibers because the ionization state of the peptides are not fixed but liable to change due to the acid-base equilibrium that is coupled to the structural organization of the peptide amphiphile molecules. Here, we have developed a theoretical model to describe and predict the amount of charge found on self-assembled peptide amphiphiles as a function of pH and ion concentration. In particular, we computed the amount of charge of peptide amphiphiles nanofibers with the sequence C16 − V2A2E2. In our theoretical formulation, we consider charge regulation of the carboxylic acid groups, which involves the acid-base chemical equilibrium of the glutamic acid residues and the possibility of ion condensation. The charge regulation is coupled with the local dielectric environment by allowing for a varying dielectric constant that also includes a position-dependent electrostatic solvation energy for the charged species. We find that the charges on the glutamic acid residues of the peptide amphiphile nanofiber are much lower than the same functional group in aqueous solution. There is a strong coupling between the charging via the acid-base equilibrium and the local dielectric environment. Our model predicts a much lower degree of deprotonation for a position-dependent relative dielectric constant compared to a constant dielectric background. Furthermore, the shape and size of the electrostatic potential as well as the counterion distribution are quantitatively and qualitatively different. These results indicate that an accurate model of peptide amphiphile self-assembly must take into account charge regulation of acidic groups through acid–base equilibria and ion condensation, as well as coupling to the local dielectric environment.

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Section: Resultsmentioning

confidence: 99%

Section: Summary and Concluding Remarksmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Acid-Base Equilibrium and Dielectric Environment Regulate Charge in Supramolecular Nanofibers

et al. 2022

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“…10,11,14,15,18 ■ THEORETICAL METHODS General Model. Our theory is based on our previous studies on the self-assembly of neutral triblock surfactants 37 and lysineterminated peptide amphiphiles. 38 It is derived from a MOLT previously developed by Szleifer and co-workers.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Morphology of the Aggregates and Thermodynamic Stability. As in our previous studies, 37,38 we assessed the morphology of the aggregates by considering three possible ideal shapes: spheres, infinitely long cylinders (wormlike micelles), and infinitely extended planar lamellas. These three ideal morphologies can be described using only one spatial coordinate, r, which represents the radial distance for spheres and cylinders and the distance to the central plane for lamellas.…”

Section: ■ Introductionmentioning

confidence: 99%

Molecular Basis for the Morphological Transitions of Surfactant Wormlike Micelles Triggered by Encapsulated Nonpolar Molecules

2021

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Surfactant wormlike micelles are prone to experience morphological changes, including the transition to spherical micelles, upon the addition of nonpolar additives. These morphological transitions have profound implications in diverse technological areas, such as the oil and personal-care industries. In this work, additive-induced morphological transitions in wormlike micelles were studied using a molecular theory that predicts the equilibrium morphology and internal molecular organization of the micelles as a function of their composition and the molecular properties of their components. The model successfully captures the transition from wormlike to spherical micelles upon the addition of a nonpolar molecule. Moreover, the predicted effects of the concentration, molecular structure, and degree of hydrophobicity of the nonpolar additive on the wormlike-to-sphere transition are shown to be in good agreement with experimental trends in the literature. The theory predicts that the location of the additive in the micelle (core or hydrophobic–hydrophilic interface) depends on the additive hydrophobicity and content, and the morphology of the micelles. Based on the results of our model, simple molecular mechanisms were proposed to explain the morphological transitions of wormlike micelles upon the addition of nonpolar molecules of different polarities.

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