Article ID Journal Published Year Pages File Type
1798018 Journal of Magnetism and Magnetic Materials 2016 11 Pages PDF
Abstract

•Molecular dynamics simulation of crossing nano-particles through the BBB membrane at different velocities.•Recording the position of nano-particle and the membrane-NP interaction force profile.•Identification of a frequency domain model for the membrane.•Calculating the diffusion coefficient based on MD simulation and identified model.•Obtaining a relation between continuum medium and discrete medium.

Various physical and biological aspects of the Blood Brain Barrier (BBB) structure still remain unfolded. Therefore, among the several mechanisms of drug delivery, only a few have succeeded in breaching this barrier, one of which is the use of Magnetic Nanoparticles (MNPs). However, a quantitative characterization of the BBB permeability is desirable to find an optimal magnetic force-field. In the present study, a molecular model of the BBB is introduced that precisely represents the interactions between MNPs and the membranes of Endothelial Cells (ECs) that form the BBB. Steered Molecular Dynamics (SMD) simulations of the BBB crossing phenomenon have been carried out. Mathematical modeling of the BBB as an input-output system has been considered from a system dynamics modeling viewpoint, enabling us to analyze the BBB behavior based on a robust model. From this model, the force profile required to overcome the barrier has been extracted for a single NP from the SMD simulations at a range of velocities. Using this data a transfer function model has been obtained and the diffusion coefficient is evaluated. This study is a novel approach to bridge the gap between nanoscale models and microscale models of the BBB. The characteristic diffusion coefficient has the nano-scale molecular effects inherent, furthermore reducing the computational costs of a nano-scale simulation model and enabling much more complex studies to be conducted.

Related Topics
Physical Sciences and Engineering Physics and Astronomy Condensed Matter Physics
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