Unique Contributions of iDQC MR Contrast to Stimuli-Sensitive Liposomal Chemotherapy and Imaging

Howell, Darya Elizabeth Reza

January 2012

<p>Liposomes are excellent chemotherapy drug delivery agents, on the cutting edge of cancer treatment technology. Since liposomes are already used to deploy cancer drugs in patients, imaging capacity would make them dual-purpose "theranostic" vesicles. Intermolecular double quantum coherence (iDQC) MRI is uniquely suited to this application, as its contrast does not require any additional chemicals. Adding contrast agents to liposomes can be time-consuming, add to toxicity, interfere with membrane function, or adversely affect drug loading. Furthermore, iDQC contrast measures diffusion and thus directly depends on membrane permeability and related properties. In this set of experiments, it has been shown that iDQC signal from intra-liposomal water can be distinguished from that of bulk water, and that the T2 dynamics of intra-liposomal water are predictable and dependent on the percent of water encapsulated. These techniques to distinguish between water molecules based on their current physical circumstances lead to many novel possibilities in MRI, as nearly all the signal in conventional MRI is from water protons. Based on the signal to noise ratio in the aforementioned iDQC experiments, we predict that iDQC contrast from liposomes will be visible in vivo, and propose to prove this in a murine model. By examining intra-liposomal water, iDQC can be used to improve chemotherapy delivery via real time monitoring of liposome location and drug release.</p> / Thesis

Chemistry

intermolecular Double Quantum Coherence

Liposomes

MRI

Solid-State NMR Studies of Solvent-Accessible Fragments of a Seven-Helical Transmembrane Protein Proteorhodopsin

Ward, Meaghan

12 September 2011

High–resolution multidimensional proton-detected NMR was used to study the solvent-exposed regions of a seven-helical integral membrane proton pump proteorhodopsin (PR). Fully deuterated PR samples with protons reintroduced to solvent-accessible sites through back exchange were prepared and found to produce NMR spectra with acceptable proton resolution (~0.2 ppm). Novel three-dimensional proton-detected chemical shift correlation spectroscopy was used for the identification and resonance assignment of the solvent–exposed regions of PR. Though most of the observed residues were located at the membrane interface there were notable exceptions, particularly in helix G. This helix contains the Schiff base-forming Lys231 and many conserved polar residues in the extracellular half. Solvent accessibility of helix G supports the hypothesis that high mobility of the F-G loop could transiently expose a hydrophilic cavity in the extracellular half of PR, and implies that such a cavity may be part of the protein’s proton-conduction pathway. / Natural Sciences and Engineering Research Council, Ontario Ministry of Training, Colleges, and Universities, Canadian Foundation for Innovation, Ontario Ministry of Research and Innovation, University of Guelph

Proteorhodopsin

solid-state NMR

magic angle spinning

Double Quantum Coherence

membrane proteins

protein-water interaction