Abstract

Because of its governing role in implant biocompatibility, the understanding and control of protein adsorption to implant surfaces continues to be one of the major areas of research in the field of biomaterials. Although greatly desired, a detailed molecular-level understanding of how protein adsorption occurs, and how to control it, are still lacking. Molecular simulation offers great potential to help address these limitations by providing a tool to accurately predict and visualize molecular-level behavior. However, before this potential can be realized, methods must be specifically developed for this application. The overall objective of the proposed R01 research program is therefore to develop molecular simulation capabilities to accurately simulate protein adsorption on surfaces, initially with polymer-like functionality . This will be accomplished by first modifying the well-established CHARMM molecular simulation program to enable two different force fields (either Class I or II type) to be used in the same simulation to separately represent the solution phase and the solid phase. This will enable both phases of an adsorption system to be accurately modeled by a force field that has been specifically developed and validated for that particular material system (e.g., protein in aqueous solution vs. a crystalline polymer). The interface between the two phases, however, must be separately tuned and validated. To accomplish this, experimental adsorption studies using surface plasmon resonance spectroscopy will be conducted using a designed host-guest peptide system to generate experimental adsorption data that will be used to evaluate, tune, and validate a CHARMM interfacial force field for the accurate simulation of protein adsorption behavior at the solid-solution interface. Once validated, the hybrid force field system will be applied to simulate the adsorption behavior for a biomedically relevant protein on functionalized surfaces and the results will be quantitatively compared with a matched set of experimental studies to demonstrate the developed capabilities to accurately simulate protein adsorption behavior. The successful development of these simulation capabilities will provide the foundations for the establishment of molecular simulation as a valuable tool for the biomaterials community for surface design to study and control protein adsorption behavior at the molecular level, with direct applications for medical device design to enhance implant biocompatibility for improved patient care. ? ? ?

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Type
Research Project (R01)
Project #
5R01EB006163-03
Application #
7383812
Study Section
Biomaterials and Biointerfaces Study Section (BMBI)
Program Officer
Henderson, Lori
Project Start
2006-06-01
Project End
2010-03-31
Budget Start
2008-04-01
Budget End
2009-03-31
Support Year
3
Fiscal Year
2008
Total Cost
$350,749
Indirect Cost

  Institution

Name
Clemson University
Department
Biomedical Engineering
Type
Schools of Engineering
DUNS #
042629816
City
Clemson
State
SC
Country
United States
Zip Code
29634

  Publications

Li, Xianfeng; Snyder, James A; Stuart, Steven J et al. (2015) TIGER2 with solvent energy averaging (TIGER2A): An accelerated sampling method for large molecular systems with explicit representation of solvent. J Chem Phys 143:144105
Latour, Robert A (2014) Perspectives on the simulation of protein-surface interactions using empirical force field methods. Colloids Surf B Biointerfaces 124:25-37
Brison, Jeremy; Robinson, Michael A; Benoit, Danielle S W et al. (2013) TOF-SIMS 3D imaging of native and non-native species within HeLa cells. Anal Chem 85:10869-77
Snyder, James A; Abramyan, Tigran; Yancey, Jeremy A et al. (2012) Development of a tuned interfacial force field parameter set for the simulation of protein adsorption to silica glass. Biointerphases 7:56
Collier, Galen; Vellore, Nadeem A; Yancey, Jeremy A et al. (2012) Comparison between empirical protein force fields for the simulation of the adsorption behavior of structured LK peptides on functionalized surfaces. Biointerphases 7:24
Sivaraman, Balakrishnan; Latour, Robert A (2011) Delineating the roles of the GPIIb/IIIa and GP-Ib-IX-V platelet receptors in mediating platelet adhesion to adsorbed fibrinogen and albumin. Biomaterials 32:5365-70
Li, Xianfeng; Latour, Robert A (2011) The temperature intervals with global exchange of replicas empirical accelerated sampling method: parameter sensitivity and extension to a complex molecular system. J Comput Chem 32:1091-100
Brison, Jeremy; Benoit, Danielle S W; Muramoto, Shin et al. (2011) ToF-SIMS imaging and depth profiling of HeLa cells treated with bromodeoxyuridine. Surf Interface Anal 43:354-357
McAliley, James H; Bruce, David A (2011) Development of force field parameters for molecular simulation of polylactide. J Chem Theory Comput 7:3756-3767
Wei, Yang; Latour, Robert A (2010) Correlation between desorption force measured by atomic force microscopy and adsorption free energy measured by surface plasmon resonance spectroscopy for peptide-surface interactions. Langmuir 26:18852-61

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