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This study simulated lipid-wrapped nanoparticles (LNP) to understand their structure and transitions. We found a unique order/disorder transition dependent on nanoparticle size and lipid number.

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Area of Science:

  • Computational chemistry and biophysics
  • Materials science
  • Nanotechnology

Background:

  • Lipid-wrapped nanoparticles (LNP) are crucial in drug delivery and biomaterials.
  • Understanding the self-assembly and phase behavior of LNPs is essential for their application.
  • Previous studies have explored LNP structure, but a comprehensive understanding of their phase transitions remains incomplete.

Purpose of the Study:

  • To investigate the equilibrium structure and phase behavior of lipid-wrapped nanoparticles (LNP).
  • To determine the relationship between nanoparticle size, lipid number, and LNP configuration.
  • To characterize a unique order/disorder transition in LNPs.

Main Methods:

  • Hybrid molecular dynamics/Monte Carlo (MD/MC) simulations were employed.
  • A three-bead lipid model was utilized to simulate a wide range of LNP sizes (R ~ 40 nm).
  • Jarzynski free energy calculations were performed to validate the simulation method.

Main Results:

  • The study determined average nanoparticle radius, lipid distribution in layers, and configurational information for various LNP sizes.
  • A novel order/disorder transition was identified, distinct from lamellar bilayers.
  • This transition was found to be weak and continuous for small lipid numbers, sharpening to first-order for N > 10000.

Conclusions:

  • The nanoparticle core influences the inner lipid layer, while curvature introduces disorder.
  • The number of lipids in the inner and outer layers can be accurately predicted based on nanoparticle radius.
  • The findings provide critical insights into LNP self-assembly and stability, informing future design for applications.