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Title page for ETD etd-11232015-151447

Type of Document Dissertation
Author Bell, Charleson Sherard
URN etd-11232015-151447
Title Novel Multilayered Magnetoplasmonic Nanoparticles for Theranostic Applications
Degree PhD
Department Biomedical Engineering
Advisory Committee
Advisor Name Title
Todd D. Giorgio, Ph.D. Committee Chair
Eric P. Skaar, Ph.D., M.P.H. Committee Member
Frederick R. Haselton, Ph.D. Committee Member
Melissa C. Skala, Ph.D. Committee Member
Richard F. Haglund, Ph.D. Committee Member
  • Core/shell
  • Magnetic Capture
  • Acinetobacter baumannii
  • Biomedical Engineering
  • Nanoparticle
  • Nanotechnology
Date of Defense 2015-11-13
Availability unrestricted
With the advent of bionanotechnology, bioengineers utilize nanoscale tools to better characterize and modify biological processes in an effort to enhance medical applications. Most of these applications are single-purpose and utilize only a single property of the biofunctionalized nanomaterial. This work is focused on improvements in nanomaterial design, through variation in fabrication technique, that allow multiple characteristics and properties to be combined into a single, theranostic, nanoscale entity. Acinetobacter baumannii has emerged as a bacterial species of interest due to its significant virulence and enhanced persistence in combat and healthcare environments. Acinetobacter species cause a multitude of ailments which contribute to the incidence of bloodstream infections. The mortality rate associated with A. baumannii bacteremia is 52%. Treatment options are increasingly limited due to the rapid acquisition of multi-drug resistance to the few antibiotics readily available. Due to this, the development of a nanotechnology-mediated adjuvant treatment strategy for A. baumannii is paramount. As outlined in the chapters of this dissertation, novel, multilayered, magneto-metallodielectric multistrata nanoparticles which possess theranostic characteristics were developed (Chapter II). Thereafter, a synthesis strategy was implemented in order to enhance the magnetic properties of the composite material while decreasing the synthesis duration such that freshly synthesized materials could be rapidly utilized in a biological application (Chapter III). The central hypothesis of this dissertation was confirmed using superparamagnetic FeOx/Au core/shell nanoparticles that were used to magnetically capture, visualize and separate Acinetobacter baumannii using an antibiotic, polymyxin E, as the microbial targeting ligand (Chapter IV). Further development of core/shell nanotechnology will bolster the technological impact of biomedical applications thus improving the way we deliver medical care to patients across the globe and beyond.
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