Nanoparticles' (NPs) permeation through cell membranes, whether it happens via passive or active transport, is an essential initial step for their cellular internalization. The NPs' surface coating impacts the way they translocate through the lipid bilayer and the spontaneity of the process. Understanding the molecular details of NPs' interaction with cell membranes allows the design of nanosystems with optimal characteristics for crossing the lipid bilayer: computer simulations are a powerful tool for this purpose. In this work, we have performed coarse-grained molecular dynamics simulations and free energy calculations on spherical titanium dioxide NPs conjugated with polymer chains of different chemical compositions. We have demonstrated that the hydrophobic/hydrophilic character of the chains, more than the nature of their terminal group, plays a crucial role in determining the NPs' interaction with the lipid bilayer and the thermodynamic spontaneity of NPs' translocation from water to the membrane. We envision that this computational work will be helpful to the experimental community in terms of the rational design of NPs for efficient cell membrane permeation.By coarse-grained molecular dynamics simulations, we have unveiled that nanoparticles coated with mixed hydrophobic/hydrophilic polymer chains spontaneously penetrate lipid membranes, unlike those covered with chains of hydrophilic character only.

Donadoni, E., Siani, P., Frigerio, G., Milani, C., Cui, Q., Di Valentin, C. (2024). The effect of polymer coating on nanoparticles’ interaction with lipid membranes studied by coarse-grained molecular dynamics simulations. NANOSCALE, 16(18), 9108-9122 [10.1039/d4nr00495g].

The effect of polymer coating on nanoparticles’ interaction with lipid membranes studied by coarse-grained molecular dynamics simulations

Donadoni, Edoardo
Primo
;
Siani, Paulo
Secondo
;
Frigerio, Giulia;Di Valentin, Cristiana
Ultimo
2024

Abstract

Nanoparticles' (NPs) permeation through cell membranes, whether it happens via passive or active transport, is an essential initial step for their cellular internalization. The NPs' surface coating impacts the way they translocate through the lipid bilayer and the spontaneity of the process. Understanding the molecular details of NPs' interaction with cell membranes allows the design of nanosystems with optimal characteristics for crossing the lipid bilayer: computer simulations are a powerful tool for this purpose. In this work, we have performed coarse-grained molecular dynamics simulations and free energy calculations on spherical titanium dioxide NPs conjugated with polymer chains of different chemical compositions. We have demonstrated that the hydrophobic/hydrophilic character of the chains, more than the nature of their terminal group, plays a crucial role in determining the NPs' interaction with the lipid bilayer and the thermodynamic spontaneity of NPs' translocation from water to the membrane. We envision that this computational work will be helpful to the experimental community in terms of the rational design of NPs for efficient cell membrane permeation.By coarse-grained molecular dynamics simulations, we have unveiled that nanoparticles coated with mixed hydrophobic/hydrophilic polymer chains spontaneously penetrate lipid membranes, unlike those covered with chains of hydrophilic character only.
Articolo in rivista - Articolo scientifico
Nanoparticles; Polymer coating; Lipid membranes; Coarse-grained modeling; Molecular dynamics; Nanomedicine
English
8-apr-2024
2024
16
18
9108
9122
none
Donadoni, E., Siani, P., Frigerio, G., Milani, C., Cui, Q., Di Valentin, C. (2024). The effect of polymer coating on nanoparticles’ interaction with lipid membranes studied by coarse-grained molecular dynamics simulations. NANOSCALE, 16(18), 9108-9122 [10.1039/d4nr00495g].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10281/475799
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