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Details of Grant 

EPSRC Reference: EP/J004170/1
Title: G8 Multilateral Research Funding INGENIOUS
Principal Investigator: Nerukh, Dr D
Other Investigators:
Researcher Co-Investigators:
Project Partners:
Department: Sch of Engineering and Applied Science
Organisation: Aston University
Scheme: Standard Research
Starts: 13 July 2011 Ends: 12 January 2015 Value (£): 355,236
EPSRC Research Topic Classifications:
High Performance Computing
EPSRC Industrial Sector Classifications:
No relevance to Underpinning Sectors
Related Grants:
EP/J004308/1
Panel History:  
Summary on Grant Application Form
The kinetics of biomolecular processes define many biomedical technologies and for this reason represent the fundamental basis for a large segment of pharmaceutical industries. Because of the problem complexity, computer simulations are the only available tool that can capture the mechanisms of binding at the required resolution level. Indeed, in many cases the processes are very short lived which makes them hardly detectable by experiment. Intermediate complexes that may be rate limiting can change the rates by orders of magnitudes rendering potential drug candidates inactive (or vice versa). Currently this can be checked only by expensive and time consuming experimental tests. Thus, the possibility of calculating the rates using computer simulation can make very significant impact on drug design studies.

Attempts of incorporating a group of classical atoms into a continuum solvent (implicit solvent) are known for a long time. However, the most consistent approach describing a structured continuum, the hydrodynamics, is a direction that becomes active only very recently. Conceptually, modelling the MD particles in the 'transfer' region where the MD and CH domains overlap (the 'runaway' MD particles) remains the most pressing problem of essentially all approaches of this type.

We propose a fundamentally new hybrid model that aims at solving this problem. It is based on a generalised description of the MD and CH components within the flux coupling approach. The proposed framework will ensure that the transition between the CH and MD representations is smooth and characterised by (i) the absence of numerical "fixes" such as artificial repulsive barriers between the atomistic and continuum parts or adding new particles, (ii) unified treatment of the solution parts using the same equations throughout the system's volume, (iii) the full control by a single empirical function that can be of arbitrary form both in space and time. The new method will lead to a large reduction of the simulation cost due to a large truncation of the MD domain, achieved without loosing either the detailed atomistic simulation in the MD zone or the macroscopic conservation laws for both mass and momentum.

The project is a well balanced combination of state of the art computer hardware development, advanced numerical modelling (the triad of molecular dynamics, continuum fluid mechanics, and numerical methods) and cutting edge investigation of biomedically important molecular system.

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Organisation Website: http://www.aston.ac.uk