Effect of the Mobility of Charged Units on the Microphase Separation in Amphiphilic Polyelectrolyte Hydrogels

Andreeva, A. S.; Philippova, Olga E.; Khokhlov, Alexei R.; Islamov, and Akhmed Kh.; Куклин, А. И.

doi:10.1021/la0478999

Cited by 39 publications

(24 citation statements)

References 28 publications

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“…This stabil ity of aggregates is presumably related to the formation of the well defined core-shell structure in them, in which the majority of associating groups are concen trated in cores, while the majority of hydrophilic groups form the shell. Note that, because not all units are protonated under the experimental conditions, charged groups may move [137,138] from the core of the aggregate to the shell and additionally stabilize the system. In such aggregates, stabilization occurs owing to a small amount of charged groups in shells and to steric hindrances created by hydrophilic chain frag ments (loops, free ends, etc.)…”

Section: Effect Of Phmentioning

confidence: 99%

“…The incorporation of hydrophobic substitu ents into chitosan is a very promising approach. These substituents form hydrophobic domains [22][23][24][25][26][27] that may absorb drugs poorly soluble in water; as a result, the application areas of chitosan as a drug carrier become wider. Moreover, hydrophobic substituents may enhance transfection [28][29][30]; therefore, the effi ciency of chitosan as gene delivery vehicle may be improved.…”

Section: Introductionmentioning

confidence: 99%

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Chitosan and its hydrophobic derivatives: Preparation and aggregation in dilute aqueous solutions

2012

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This review surveys the main methods of preparing chitosan and its hydrophobic derivatives and their influence on the microstructure of polymers. The experimental data on the aggregation of these poly mers in dilute aqueous solutions are summarized. Basic factors affecting aggregation are analyzed, and its general regularities are revealed. It is shown that, in the case of both chitosan and its hydrophobic derivatives, the formation of aggregates is governed by the competition of attraction of associating groups promoting aggregation and their repulsion arising from the presence of charged units and counterions hindering aggre gation. Various aggregate models that were proposed for chitosan derivatives with different main chain lengths and different contents of associating groups are discussed.

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Section: Effect Of Phmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Chitosan and its hydrophobic derivatives: Preparation and aggregation in dilute aqueous solutions

2012

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“…The data were recorded in the range of the scattering vectors q of 0.009 – 0.5 Å −1 . The details of the experiments are described elsewhere 11–14. For fitting the experimental curves by different models, the program “Fitter” was used 11…”

Section: Experimental Partmentioning

confidence: 99%

Polymer‐Surfactant Networks Highly Responsive to Hydrocarbons

Philippova

Молчанов

2010

Macromolecular Symposia

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Hydrocarbon‐sensitive hydrogels were prepared on the basis of networks, in which some subchains are composed of hydrophobically modified polyacrylamide, while others are made of long cylindrical surfactant micelles of potassium oleate. In these hydrogels, the polymer component strengthens the network, especially at elevated temperatures, whereas the surfactant component imparts a high responsiveness to the hydrocarbon medium. The rheological studies demonstrate that added hydrocarbons induce the transformation of the gel‐like system to a fluid with low viscosity. SANS data evidence that the transformation is accompanied by the breaking of the cylindrical surfactant micelles, that leads to the disruption of the whole network.

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“…Indeed, in addition to the similarities of rheological properties mentioned earlier, the collapse of hydrophobic clusters also takes place in HM-polyelectrolyte solutions such as hydrophibically modified polyacrylic acid. 29,36,37 In fact, a decrease to low pH in these systems induced phase separation. At this point, the hydrophobic attractions become dominant and the polymer depleted …”

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confidence: 99%

PFG‐NMR diffusometry: A tool for investigating the structure and dynamics of noncommercial purified pig gastric mucin in a wide range of concentrations

et al. 2007

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For the first time, Pulsed Field Gradient-Nuclear Magnetic Resonance, a powerful noninvasive tool for studying the dynamics and structure of complex gels, has been used to measure diffusion of probe molecules in aqueous solutions/gels of noncommercial purified pig gastric mucin (PGM), in a concentration range up to 5 wt %. Complementary data were obtained from rheology measurements. The combination of techniques revealed a strong pH dependency of the structure of the PGM samples while changes in concentration, ionic strength, and temperature appeared to induce less pronounced alterations. Viscosity was found to vary in a nonmonotonous way with pH, with the more viscous solutions found at intermediate pH. We propose that this finding is due to a reduced charge density at lower pH, which is expected to continuously increase the relative importance of hydrophobic associations. The results suggest a loose network of expanded fully charged PGM molecules with considerable mobility at neutral pH (pH 7.4). At intermediate pH (pH 4), a three-dimensional expanded network is favored. At pH 1, the charge density is low and microphase separation occurs since hydrophobic associations prevail. This leads to the formation of clusters concentrated in PGM molecules separated by regions depleted in PGM. The results obtained increase our knowledge about the gastric mucosal layer, which in vivo contains mucin in the same concentration range as that of the samples investigated here.

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Effect of the Mobility of Charged Units on the Microphase Separation in Amphiphilic Polyelectrolyte Hydrogels

Cited by 39 publications

References 28 publications

Chitosan and its hydrophobic derivatives: Preparation and aggregation in dilute aqueous solutions

Chitosan and its hydrophobic derivatives: Preparation and aggregation in dilute aqueous solutions

Polymer‐Surfactant Networks Highly Responsive to Hydrocarbons

PFG‐NMR diffusometry: A tool for investigating the structure and dynamics of noncommercial purified pig gastric mucin in a wide range of concentrations

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