The Structure of Dendrimers with Charged Terminal Groups: Monte Carlo Simulations

Majtyka, M.; Kłos, J. S.

doi:10.12693/aphyspola.110.833

Cited by 8 publications

(11 citation statements)

References 46 publications

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“…In the following we assume that an ion is condensed when its distance from at least one charged unit is less than √6, a distance comparable with the average bond length in the BFM. This approach is widely used in studies on polyelectrolyte systems and has proved reasonable both for lattice and off-lattice simulations. − , A comparison of various methods has been given by Grass and Holm . We note that the peak-position of the correlation functions in Figure is nearly constant.…”

Section: Resultsmentioning

confidence: 82%

“…This approach is widely used in studies on polyelectrolyte systems and has proved reasonable both for lattice and off-lattice simulations. [20][21][22][23]59 A comparison of various methods has been given by Grass and Holm. 59 We note that the peak-position of the correlation functions in Figure 2 is nearly constant.…”

Section: Resultsmentioning

confidence: 99%

“…17,18 Actually, as the strength of electrostatic interactions increases both under neutral and low pH conditions counterions penetrate not only the molecule periphery but, in the first place, its interior. 15,[19][20][21][22][23][24][25][26] This leads to the reduction of the dendrimer effective charge, screening of electrostatic repulsion between charged monomers and nonmonotonous behavior of dendrimer size. Last but not least ions also play a crucial role in the formation of complexes comprised of charged dendrimers and linear polyanions and in self-organization in solutions of charged dendrimers, [27][28][29][30][31][32][33] though many important aspects of complexation such as dendrimer overcharging by linear polyelectrolytes have been revealed within the Debye-H€ uckel approach as well.…”

Section: Introductionmentioning

confidence: 99%

“…It is therefore apparent from previous studies that the degrees of freedom of counterions have to be taken into account explicitly for dendritic polyelectrolytes due to the importance of ion valence and trapping in the dendrimer volume, ion condensation and their effect on conformational changes of dendrimers. , Actually, as the strength of electrostatic interactions increases both under neutral and low pH conditions counterions penetrate not only the molecule periphery but, in the first place, its interior. ,− This leads to the reduction of the dendrimer effective charge, screening of electrostatic repulsion between charged monomers and nonmonotonous behavior of dendrimer size. Last but not least ions also play a crucial role in the formation of complexes comprised of charged dendrimers and linear polyanions and in self-organization in solutions of charged dendrimers, − though many important aspects of complexation such as dendrimer overcharging by linear polyelectrolytes have been revealed within the Debye−Hückel approach as well. − Obviously, it is dendrimer−DNA binding − in the first place, which being of immense interest in biosciences inspires theoretical investigations.…”

Section: Introductionmentioning

confidence: 99%

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Simulations of Dendrimers with Flexible Spacer Chains and Explicit Counterions under Low and Neutral pH Conditions

Kłos

Sommer

2010

Macromolecules

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We study the properties of weak dendritic polyelectrolytes of generation G = 5 with flexible spacers of various lengths and explicit counterions in an athermal solvent using Monte Carlo simulations based on the bond fluctuation model. The calculations are performed for molecules under neutral and low pH conditions. At neutral pH we assume that only the terminal groups of the dendrimers bear positive charges, while at low pH both the terminal groups and the branching units are charged. In our study, the full Coulomb potential and the excluded volume interactions are taken into account explicitly with the reduced temperature τ as the main simulation parameter. We observe an interplay of condensation of counterions, trapping of counterions inside the dendrimer’s volume and evaporation of counterions into the surrounding solution giving rise to a nonmonotonous electrostatic swelling of the dendrimer with temperature. Decreasing pH leads to higher swelling and stronger spacer-length dependence. At low pH spacer length-scaling cannot be applied and longer spacers shift the maximum of the swelling to lower temperature. To explain the swelling effect we apply a Flory-type argument where both trapped but noncondensed counterions and uncompensated charges due to evaporation of counterions are taken into account. This model properly reflects the swelling behavior with respect to temperature, pH and spacer-length variation, but quantitatively underestimates the swelling effect. We further investigate the pH-effects on density and charge profiles of the dendrimer.

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Section: Resultsmentioning

confidence: 82%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Simulations of Dendrimers with Flexible Spacer Chains and Explicit Counterions under Low and Neutral pH Conditions

Kłos

Sommer

2010

Macromolecules

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“…It indeed can reduce the computational load and easily handle the ion strength effect via tuning the value of k. However, it should be stressed that the Debye screening approximation has an important limitation when dealing with charged polymers in salt solution because it cannot capture the important nonlinear features, such as counterion condensation. [86][87][88][89][90][91][92] It is valid in situations where the separation between charges exceeds the Bjerrum length, but the condition breaks down easily in the case of dendrimer structures and multivalent salt ions. To overcome this limitation, Gurtovenko et al 93 employed MD simulations of charged dendrimers under neutral pH conditions with explicit counterions and solvent molecules under the penalty of computational cost.…”

Section: Monomer-resolved Modelsmentioning

confidence: 99%

Theoretical and computational studies of dendrimers as delivery vectors

2013

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It is a great challenge for nanomedicine to develop novel dendrimers with maximum therapeutic potential and minimum side-effects for drug and gene delivery. As delivery vectors, dendrimers must overcome lots of barriers before delivering the bio-agents to the target in the cell. Extensive experimental investigations have been carried out to elucidate the physical and chemical properties of dendrimers and explore their behaviors when interacting with biomolecules, such as gene materials, proteins, and lipid membranes. As a supplement of the experimental techniques, it has been proved that computer simulations could facilitate the progress in understanding the delivery process of bioactive molecules. The structures of dendrimers in dilute solutions have been intensively investigated by monomer-resolved simulations, coarse-grained simulations, and atom-resolved simulations. Atomistic simulations have manifested that the hydrophobic interactions, hydrogen-bond interactions, and electrostatic attraction play critical roles in the formation of dendrimer-drug complexes. Multiscale simulations and statistical field theories have uncovered some physical mechanisms involved in the dendrimer-based gene delivery systems. This review will focus on the current status and perspective of theoretical and computational contributions in this field in recent years. (275 references).

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Simulations of Terminally Charged Dendrimers with Flexible Spacer Chains and Explicit Counterions

Kłos

Sommer

2010

Macromolecules

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We study the properties of terminally charged dendrimers under systematic variation of the length of flexible spacers, accompanied by explicit counterions in an athermal solvent using Monte Carlo simulations based on the bond fluctuation model. In our study, both the full Coulomb potential and the excluded volume interactions are taken into account explicitly with the reduced temperature, τ, as the main control parameter. Our calculations confirm that counterions get localized in the molecules’ interior and, in particular, condense on the terminal groups as τ is lowered. This, in turn, affects the conformational properties of the molecules that swell at intermediate τ due to dominating repulsion between the terminal groups and shrink in the limit of high and low τ, respectively. Like for neutral dendrimers, we find a substantial decrease in monomer densities with the radial distance from the dendrimers’ center of mass and backfolding of the terminal groups toward the molecules’ interior. By means of the radius of gyration tensor, we conclude that the mean instantaneous shape of dendrimers is spherical for all τ inspected.

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The Structure of Dendrimers with Charged Terminal Groups: Monte Carlo Simulations

Cited by 8 publications

References 46 publications

Simulations of Dendrimers with Flexible Spacer Chains and Explicit Counterions under Low and Neutral pH Conditions

Simulations of Dendrimers with Flexible Spacer Chains and Explicit Counterions under Low and Neutral pH Conditions

Theoretical and computational studies of dendrimers as delivery vectors

Simulations of Terminally Charged Dendrimers with Flexible Spacer Chains and Explicit Counterions

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