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This book describes the tools, developed by the author, for perturbing endogenous mechano-sensitive ion channels for magneto-mechanical neuro-modulation. He explores the ways in which these tools compare against existing ones such as electricity, chemicals, optogenetics, and techniques like thermos/magneto-genetics. The author also reports on two platforms—magnetic ratcheting and magnetic microfluidics for directed evolution and high throughput culture of magnetotactic bacteria—that produce high quality magnetic nanoparticles for biomedical applications like neural stimulations. This thesis was submitted to and approved by the University of California, Los Angeles. Introduces technology for non-invasive control of neural activities that offer deep tissue penetration and controllable dosage; Examines the effects of biomechanical forces on cellular functions; Explores how to improve the reproducibility and uptake of magnetic tools for non-invasive neural modulation.
Engineering. --- Nanoscale science. --- Nanoscience. --- Nanostructures. --- Biomedical engineering. --- Nanotechnology. --- Biomedical Engineering. --- Nanoscale Science and Technology. --- Neural stimulation. --- Magnetic nanoparticle hyperthermia. --- Hyperthermia, Magnetic fluid --- Hyperthermia, Magnetic nanoparticle --- Hyperthermia, Magnetic nanoparticle-based --- Magnetic fluid hyperthermia --- Magnetic nanoparticle-based hyperthermia --- MNH (Magnetic nanoparticle hyperthermia) --- Thermotherapy --- Nerve stimulation --- Stimulation, Neural --- Electric stimulation --- Electrodiagnosis --- Electrophysiology --- Electrotherapeutics --- Biomedical Engineering and Bioengineering. --- Molecular technology --- Nanoscale technology --- High technology --- Clinical engineering --- Medical engineering --- Bioengineering --- Biophysics --- Engineering --- Medicine --- Nanoscience --- Physics --- Nano science --- Nanoscale science --- Nanosciences --- Science
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