Location

Cherry Auditorium, Kirk Hall

Start Date

4-3-2008 1:00 PM

Description

Lipid bilayer membranes provide the physical barriers that define the structure, function, and stability of living cells. Specifically, they play a key role in governing molecular and phase toxicity, anesthetic action, the bioaccumulation of hydrophobic or amphiphatic pollutants, and cell-surface interactions. In addition to their ubiquity in nature, vesicles (or liposomes) self-assembled from synthetic lipid bilayers provide a biologically inspired route for the design of, for example, drug delivery systems, nanostructured materials and devices, and biosensors. We currently have two research thrusts in our laboratory related to lipid assemblies: (1) Utilizing synthetic lipid bilayers as model cell membranes to study nanomaterial and biomolecular interactions and (2) designing new multifunctional hybrid lipid assemblies for therapeutic applications. In this seminar, I will describe the techniques we use to design these systems, to evaluate their thermodynamic and transport properties (e.g. within lipid bilayers), which are governed by intermolecular and surface interactions, and to impart function. Specific projects that will be discussed include gauging nanoparticle toxicity, elucidating peptide-membrane interaction mechanisms for drug delivery, and creating inorganic nanoparticle/lipid assemblies.

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Apr 3rd, 1:00 PM

Multifunctional Nanoparticle/Lipid Self-Assemblies

Cherry Auditorium, Kirk Hall

Lipid bilayer membranes provide the physical barriers that define the structure, function, and stability of living cells. Specifically, they play a key role in governing molecular and phase toxicity, anesthetic action, the bioaccumulation of hydrophobic or amphiphatic pollutants, and cell-surface interactions. In addition to their ubiquity in nature, vesicles (or liposomes) self-assembled from synthetic lipid bilayers provide a biologically inspired route for the design of, for example, drug delivery systems, nanostructured materials and devices, and biosensors. We currently have two research thrusts in our laboratory related to lipid assemblies: (1) Utilizing synthetic lipid bilayers as model cell membranes to study nanomaterial and biomolecular interactions and (2) designing new multifunctional hybrid lipid assemblies for therapeutic applications. In this seminar, I will describe the techniques we use to design these systems, to evaluate their thermodynamic and transport properties (e.g. within lipid bilayers), which are governed by intermolecular and surface interactions, and to impart function. Specific projects that will be discussed include gauging nanoparticle toxicity, elucidating peptide-membrane interaction mechanisms for drug delivery, and creating inorganic nanoparticle/lipid assemblies.