DocumentCode
1765276
Title
Terahertz Spectra of Biotin Based on First Principle, Molecular Mechanical, and Hybrid Simulations
Author
Bykhovski, A. ; Woolard, D.
Author_Institution
North Carolina State Univ., Raleigh, NC, USA
Volume
17
Issue
4
fYear
2013
fDate
41456
Firstpage
768
Lastpage
773
Abstract
Terahertz (THz) absorption of biotin was simulated using the first principle and the density functional theory (DFT) both in the harmonic approximation and with corrections for the anharmonicity. Anharmonicity corrections were calculated using two different approaches. First, the perturbation theory-based first principle calculations were performed to include third- and fourth-order anharmonicity corrections in atomic displacements to harmonic vibrational states. Second, the atom-centered density matrix propagation molecular dynamics model that provides a good energy conservation was used to calculate the atomic trajectories, velocities, and a dipole moment time history of biotin at low and room temperatures. Predicted low-THz lines agree well with the experimental spectra. The influence of the polyethylene (PE) matrix embedment on the THz spectra of biotin at the nanoscale was studied using the developed hybrid DFT/molecular mechanical approach. While PE is almost transparent at THz frequencies, additional low-THz lines are predicted in the biotin/PE system, which reflects a dynamic interaction between biotin and a surrounding PE cavity.
Keywords
ab initio calculations; density functional theory; enzymes; molecular biophysics; molecular dynamics method; nanobiotechnology; perturbation theory; polymers; terahertz wave spectra; vibrational states; DFT; PE cavity; THz frequencies; atom-centered density matrix; atomic displacements; atomic trajectories; biotin; density functional theory; dipole moment; dynamic interaction; energy conservation; fourth-order anharmonicity corrections; harmonic approximation; harmonic vibrational states; hybrid DFT-molecular mechanical approach; hybrid simulations; low-THz lines; molecular dynamics model; perturbation theory-based first principle calculations; polyethylene matrix; temperature 293 K to 298 K; terahertz absorption spectra; third-order anharmonicity corrections; Absorption; Approximation methods; Biological system modeling; Discrete Fourier transforms; Harmonic analysis; Polyethylene; Solid modeling; Biotin; first principle; hybrid; terahertz (THZ);
fLanguage
English
Journal_Title
Biomedical and Health Informatics, IEEE Journal of
Publisher
ieee
ISSN
2168-2194
Type
jour
DOI
10.1109/JBHI.2013.2253786
Filename
6484088
Link To Document