Issue 10, 2014

Efficient simulations of the aqueous bio-interface of graphitic nanostructures with a polarisable model

Abstract

To fully harness the enormous potential offered by interfaces between graphitic nanostructures and biomolecules, detailed connections between adsorbed conformations and adsorption behaviour are needed. To elucidate these links, a key approach, in partnership with experimental techniques, is molecular simulation. For this, a force-field (FF) that can appropriately capture the relevant physics and chemistry of these complex bio-interfaces, while allowing extensive conformational sampling, and also supporting inter-operability with known biological FFs, is a pivotal requirement. Here, we present and apply such a force-field, GRAPPA, designed to work with the CHARMM FF. GRAPPA is an efficiently implemented polarisable force-field, informed by extensive plane-wave DFT calculations using the revPBE-vdW-DF functional. GRAPPA adequately recovers the spatial and orientational structuring of the aqueous interface of graphene and carbon nanotubes, compared with more sophisticated approaches. We apply GRAPPA to determine the free energy of adsorption for a range of amino acids, identifying Trp, Tyr and Arg to have the strongest binding affinity and Asp to be a weak binder. The GRAPPA FF can be readily incorporated into mainstream simulation packages, and will enable large-scale polarisable biointerfacial simulations at graphitic interfaces, that will aid the development of biomolecule-mediated, solution-based graphene processing and self-assembly strategies.

Graphical abstract: Efficient simulations of the aqueous bio-interface of graphitic nanostructures with a polarisable model

Supplementary files

Article information

Article type
Paper
Submitted
24 Jan 2014
Accepted
26 Mar 2014
First published
01 Apr 2014

Nanoscale, 2014,6, 5438-5448

Author version available

Efficient simulations of the aqueous bio-interface of graphitic nanostructures with a polarisable model

Z. E. Hughes, S. M. Tomásio and T. R. Walsh, Nanoscale, 2014, 6, 5438 DOI: 10.1039/C4NR00468J

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