Adsorption of Weak Polyelectrolytes on Charged Nanoparticles. Impact of Salt Valency, pH, and Nanoparticle Charge Density. Monte Carlo Simulations

Carnal, Fabrice; Stoll, Serge

doi:10.1021/jp205616e

Cited by 79 publications

(70 citation statements)

References 67 publications

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“…The authors reported that at pH ≤ 6.4 all of the DNA content was bound into the complexes. Similar "shifts" in the degree of ionization were observed at DNA-weak polybase interactions [58] and predicted theoretically by Monte Carlo simulations [59]. It was found that the drug apparent pK changes in the presence of lipid membranes [60,61].…”

Section: Resultssupporting

confidence: 76%

Stimuli responsive polymorphism of C12NO/DOPE/DNA complexes: Effect of pH, temperature and composition

Hubčík

Funari²,

Pullmannová

et al. 2015

Biochimica et Biophysica Acta (BBA) - Biomembranes

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N,N-dimethyldodecylamine-N-oxide (C12NO) is a surfactant that may exist either in a neutral or cationic protonated form depending on the pH of aqueous solutions. Using small angle X-ray diffraction (SAXD) we observe the rich structural polymorphism of pH responsive complexes prepared due to DNA interaction with C12NO/dioleoylphosphatidylethanolamine (DOPE) vesicles and discuss it in view of utilizing the surfactant for the gene delivery vector of a pH sensitive system. In neutral solutions, the DNA uptake is low, and a lamellar Lα phase formed by C12NO/DOPE is prevailing in the complexes at 0.2≤C12NO/DOPE<0.6 mol/mol. A maximum of ~30% of the total DNA volume in the sample is bound in a condensed lamellar phase LαC at C12NO/DOPE=1 mol/mol and pH7.2. In acidic conditions, a condensed inverted hexagonal phase HIIC was observed at C12NO/DOPE=0.2 mol/mol. Commensurate lattice parameters, aHC≈dLC, were detected at 0.3≤C12NO/DOPE≤0.4 mol/mol and pH=4.9-6.4 suggesting that LαC and HIIC phases were epitaxially related. While at the same composition but pH~7, the mixture forms a cubic phase (Pn3m) when the complexes were heated to 80°C and cooled down to 20°C. Finally, a large portion of the surfactant (C12NO/DOPE>0.5) stabilizes the LαC phase in C12NO/DOPE/DNA complexes and the distance between DNA strands (dDNA) is modulated by the pH value. Both the composition and pH affect the DNA binding in the complexes reaching up to ~95% of the DNA total amount at acidic conditions.

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Section: Resultssupporting

confidence: 76%

Stimuli responsive polymorphism of C12NO/DOPE/DNA complexes: Effect of pH, temperature and composition

Hubčík

Funari²,

Pullmannová

et al. 2015

Biochimica et Biophysica Acta (BBA) - Biomembranes

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“…Here, we were particularly interested in the radial distribution functions between charged solutes in the suspension, with the solvent treated as a continuum. The MC technique is particularly adapted to the simulation of solutions of charged nanoparticles in the presence of small ions [43][44][45][46]. If one focuses on the pair distribution function g Cj (r) between nanoparticles and ions of type j, the number N Cj of ions j situated at a distance r from the centre of a nanoparticle can be easily determined Downloaded by [University of Chicago Library] at 12:43 26 December 2014 using the following equation:…”

Section: Monte Carlo Simulationsmentioning

confidence: 99%

Influence of the volume fraction on the electrokinetic properties of maghemite nanoparticles in suspension

et al. 2014

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Special issue in Honour of Pierre TURQInternational audienceWe used several complementary experimental and theoretical tools to characterise the charge properties of well-definedmaghemite nanoparticles in solution as a function of the volume fraction. The radius of the nanoparticles is equal to 6 nm.The structural charge was measured from chemical titration and was found high enough to expect some counterions tobe electrostatically attracted to the surface, decreasing the apparent charge of the nanoparticle. Direct-current conductivitymeasurements were interpreted by an analytical transport theory to deduce the value of this apparent charge, denoted here by‘dynamic effective charge’. This dynamic effective charge is found to decrease strongly with the volume fraction. In contrast,the ‘static’ effective charge, defined thanks to the Bjerrum criterion and computed from Monte Carlo simulations turns outto be almost independent of the volume fraction. In the range of Debye screening length and volume fraction investigatedhere, double layers around nanoparticles actually interact with each other. This strong interaction between nanocolloidalmaghemite particles is probably responsible for the experimental dependence of the electrokinetic properties with the volumefraction

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“…The stability and transformation of released NPs with regards to aggregate formation or propensity to form complexes (Carnal and Stoll 2011;Ferretti et al 2003;Liang and Morgan 1990;Tipping and Higgins 1982) with water components is then a key aspect in investigating the fate of these materials. Several studies have shown that dissolved organic matter, ionic strength, pH, solution properties have important impacts on the stability of nanoparticles in aquatic systems.…”

Section: Introductionmentioning

confidence: 99%

Fulvic acids concentration and pH influence on the stability of hematite nanoparticles in aquatic systems

Palomino

Stoll

2013

J Nanopart Res

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In aquatic systems, fulvic acids (FAs) are expected to play key roles on the stability and aggregation behavior of manufactured nanoparticles (NPs). The exact conditions under which aggregation or dispersion occurs will depend on the nanoparticle surface charge properties, FAs concentration as well as solution conditions, such as pH and ionic strength. The systematic calculation of stability (aggregation versus disaggregation) diagrams is therefore a key aspect in the prediction of the environmental fate and behavior of manufactured nanoparticles in aquatic systems. In this study, the responses to changes in pH and FAs concentrations on the resulting surface charge of purified iron oxide nanoparticles (53 nm nominal diameter) is investigated. By adjusting the pH, different nanoparticle surface charge electrostatic regions are found, corresponding to positively, neutral, and negatively charged nanoparticle solutions. For each situation, the adsorption of negatively charged FAs at variable concentrations is considered by analyzing surface charge modifications and calculating experimental kinetics aggregation rates. Results show that, under the conditions used, and range of FAs environmental relevant conditions, the nanoparticle aggregation process is promoted only when the nanoparticle positive surface charge (solution pH less than the charge neutralization point) is compensated by the adsorption of FAs. In all the other cases, FAs adsorption and increase of FAs concentration are expected to promote not only the NPs stabilization but also the disaggregation of NPs aggregates. In addition, our study suggest that very low concentrations of FAs [0.1 mg/l are sufficient to rapidly stabilize iron hydroxide NPs solutions at concentration \5 mg/l.

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Adsorption of Weak Polyelectrolytes on Charged Nanoparticles. Impact of Salt Valency, pH, and Nanoparticle Charge Density. Monte Carlo Simulations

Cited by 79 publications

References 67 publications

Stimuli responsive polymorphism of C12NO/DOPE/DNA complexes: Effect of pH, temperature and composition

Stimuli responsive polymorphism of C12NO/DOPE/DNA complexes: Effect of pH, temperature and composition

Influence of the volume fraction on the electrokinetic properties of maghemite nanoparticles in suspension

Fulvic acids concentration and pH influence on the stability of hematite nanoparticles in aquatic systems

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