Abstract
Liposomes are small artificial vesicles spherical shaped of 50–1000 nm in diameter. They are created from natural non-toxic phospholipids membranes. Externally, they are decorated with biocompatible polymers. Chitosan, a natural polymer, demonstrates exceptional advantages in drug delivery, in particular, as liposome cover. In this paper, Molecular Dynamics simulations (MD) are performed in the coupled NPT-NPH and NVT-NVE statistical ensembles to study the static and dynamic properties of DPPC membrane-bilayer with grafted cationic chitosan chains, with added Cl− anions to neutralize the environment, using the Martini coarse-grained force-field. From the NPT-NPH MD simulations we found a chitosan layer LDM ranging from 3.2 to 6.6 nm for graft chains of a degree of polymerization np = 45 and different grafting molar fractions Xp = 0.005, Xp = 0.014 and Xp = 0.1. Also, the chitosan chains showed three essential grafting regimes: mushroom, critic, and brush depending on Xp. The DPPC bilayer thickness DB and the area per lipid Al increased proportionally to Xp. From the NVT-NVE MD simulations, the analysis of the radial distribution function showed that the increase of Xp gives a more close-packed and rigid liposome. The analysis of the mean square displacement revealed that the diffusion of lipids is anomalous. In contrast, the diffusion of chitosan chains showed a normal diffusion, just after 100 ps. The diffusion regime of ions is found to be normal and independent of time. For the three identified regimes, the chitosan showed a tendency to adhere to the membrane surface and therefore affect the properties of the liposomal membrane.
Highlights
Liposomes have aroused scienti c interest in many disciplines encompassing theoretical physics, biophysical chemistry, and colloidal science
The aim of this study is to examine the structural and dynamic properties of DPPC membranes covered by the chitosan chains using a coarse-grained Molecular Dynamics simulations (MD) simulation method, with particular emphasis on the application of this system in drug delivery
Chitosan chain conformations are characterized in the NPTNPH conditions, as a function of the gra ing molar fraction Xp, through calculating the length of the chitosan layer
Summary
Liposomes have aroused scienti c interest in many disciplines encompassing theoretical physics, biophysical chemistry, and colloidal science They demonstrate an excellent ability to increase the localization of drugs in diseased cells.[1] liposomes represent promising systems for drug delivery to target the drug to the site of action or improve the circulation time of the drug in vivo, aiming at side effect reduction as well as the optimization of treatments.[2,3] liposomes have been known for their huge potential as drug carriers for a variety of compounds like low molecular weight drugs, therapeutic proteins and peptides, vaccines and diagnostic agents, toxins, enzymes, antigens and antibodies, and nucleotides.[4,5,6,7,8,9,10,11,12,13] The liposomes have been introduced in the market as efficient spherical nanovesicles,[6,7,8,9,10,11,12,13,14] they are formed by a self-closed phospholipidic bilayer carrying the drug in its aqueous core suspended in water. For prolonging retention in the gastrointestinal tract and promoting penetration into the mucus layer.[22]
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