The capability of precisely controlling the kinetics of therapeutic delivery at the optimal location and rate for a given patient would have great potential to improve health and well-being in a range of current drug therapies (insulin, chemotherapeutics, vaccines, etc.). Indeed, if successfully developed, locally administered injectable drug delivery vehicles capable of remotely-triggered release would be the gold standard for many treatments.
Multiple injectable nanocomposites have been investigated for this purpose that are generally comprised of a thermosensitive polymeric material and superparamagnetic iron oxide nanoparticles (SPIONs). SPIONs generate heat when exposed remote alternating magnetic fields (AMFs), and the transfer of this heat to thermosensitive polymers can be used to control the release of therapeutics. Ideally, these systems would be capable of returning to their original state and basal release rate when the external AMF trigger is removed.
Several novel injectable nanocomposite materials that explore interactions between SPIONs and thermosensitive polymers to mediate drug release, from the macroscale to the nanoscale, were developed and demonstrated to be capable of remotely-triggered, AMF-mediated enhanced release. The macroscale magnetic nanocomposites have thermosensitive hydrogel and/or microgel components that regulate release based on the heat produced from SPIONs in response to an external AMF. On the millimeter-scale, a microinjection system capable of producing thermosensitive hydrogel beads that could potentially incorporate SPIONs is described. On the nanoscale, nanoparticles with a glass transition temperature and thermosensitive microgels are combined with SPIONs and investigated for their remote, AMF-mediated release characteristics. The engineered macroscale and nanoscale systems are capable of up to ~4:1 and ~7:1 enhancements in release due to an AMF application, respectively, compared to the basal release rate.
Collectively, these nanocomposites represent a promising stride towards improved remote-actuation of drug release and a stepping stone for future attempts at precisely controlling the site and kinetics of drug release. / Thesis / Doctor of Philosophy (PhD) / This thesis focuses on the development of nanocomposite materials that can be injected into a specific location in the body and deliver therapeutic drugs by a remote-controlled process. These nanocomposites are composed of magnetic particles and polymers that respond to changes in temperature. The combination of these materials results in nanocomposites that can change their properties in response to specific magnetic fields to switch from releasing drug slowly (or not at all) to releasing drug quickly on demand. The changes are fully reversible and solely depend on whether the external magnetic field is switched on or off. These novel systems offer an alternative to therapies that require frequent injections, such as insulin for diabetes, or therapies that need the drug to be released in very precise locations, such as cancer treatments, and could improve the safety, reduce the risk of side effects, and lower the cost of many medical treatments.
Identifer | oai:union.ndltd.org:mcmaster.ca/oai:macsphere.mcmaster.ca:11375/20953 |
Date | January 2017 |
Creators | Campbell, Scott Brice |
Contributors | Hoare, Todd, Chemical Engineering |
Source Sets | McMaster University |
Language | English |
Detected Language | English |
Type | Thesis |
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