Molecular Study of Capsaicin in Aqueous and Hydrophobic Environments

Type of Document Master's Thesis
Author Lambert, Joseph Walter
Author's Email Address lamberjw@vt.edu
URN etd-06092006-132651
Title Molecular Study of Capsaicin in Aqueous and Hydrophobic Environments
Degree Master of Science
Department Chemical Engineering
Advisory Committee
Advisor Name Title
Amadeu K. Sum Committee Chair
David R. Bevan Committee Member
Eva Marand Committee Member
Keywords

* Octanol-water
* Lipid Bilayer
* Simulations
* Molecular Dynamics
* Capsaicin

Date of Defense 2006-06-08
Availability unrestricted
Abstract

Anyone who has eaten spicy foods has experienced the adverse effects of capsaicin, the pungent chemical found in hot chili that causes a burning sensation. The specific action of capsaicin occurs by the activation of receptors in sensory neurons. This thesis investigates the interaction of capsaicin with model cell membranes representing the structure of neurons. In particular, we are interested in the changes induced by capsaicin to the structure and dynamics of membranes. Molecular dynamics simulations are used to study the molecular interactions. The first part of this study evaluates different molecular representations for capsaicin in an 1-octanol/water system. This inhomogeneous system is commonly used to determine the partition of compounds between hydrophilic and hydrophobic environments, as that found in biological membranes. The results of these simulations validate the OPLS united-atom force field as a reasonable molecular representation of capsaicin, as it describes the behavior of capsaicin both quantitatively and qualitatively in 1-octanol/water mixtures. In the second part, simulations are performed for capsaicin and model cell membranes consisting of dipalmitoylphosphatidylcholine and dipalmitoylphosphatidylethanolamine, two of the most commonly found lipids. Simulations investigated capsaicin in the aqueous and lipid phases. The results provide insight into the changes to the bilayers caused by capsaicin. Bilayers containing dipalmitoylphosphatidylethanolamine showed lower permeabilities to capsaicin than those composed of pure dipalmitoylphosphatidylcholine. Temperature is found to be an important factor in the permeability of capsaicin in the bilayer. Capsaicin in the bilayer concentrated in a region beneath the lipid/water interface, in which favorable hydrophilic and lipophilic interactions occur. The structure of the bilayer is not significantly changed at the concentrations of capsaicin considered. One important result from the simulations indicates that the interfacial density decreases with increasing capsaicin concentration in the bilayer, supporting the experimental observations of increased permeability in bilayers exposed to capsaicin.

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