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There is now a CONTENT FREEZE for Mercury while we switch to a new platform. It began on Friday, March 10 at 6pm and will end on Wednesday, March 15 at noon. No new content can be created during this time, but all material in the system as of the beginning of the freeze will be migrated to the new platform, including users and groups. Functionally the new site is identical to the old one. webteam@gatech.edu
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BioE PhD Thesis Defense
Musa Syed Mahmood
November 18th, 2021, 11:00 AM
Location: Pettit 102; Link: https://bluejeans.com/317389848/5418
Advisor:
Woon-Hong Yeo, Ph.D. ME, Georgia Institute of Technology
Committee Members:
Frank L. Hammond III, Ph.D.
ME, Georgia Institute of Technology
Peter J. Hesketh, Ph.D.
ME, Georgia Institute of Technology
Seungwoo Lee, Ph.D.
ME, Georgia Institute of Technology
Audrey Duarte, Ph.D.
Psychology, University of Texas at Austin
Study of soft materials, flexible electronics, and machine learning for fully portable and wireless brain-machine interfaces
Advancing technology has increasingly allowed for individuals suffering from severe disabilities (e.g. locked-in syndrome) to allow for movement or communication. These technologies include low-power wireless protocols, wearable, battery powered devices, flexible electronics, biocompatible skin-interfaced materials, and advanced machine learning techniques. Current non-invasive brain-machine interfaces are limited in scope, have limited functionality, and primarily only used in research environments. The more recent move towards wearable, wireless system has enabled greater mobility. However, issues remain – these systems are bulky, uncomfortable to wear, and often involve the use of messy conductive pastes and gels. In this dissertation, we introduce a flexible electronics platform, SKINTRONICS, with a comprehensive redesign of an EEG-based brain-machine interface with novel implementation of flexible EEG, flexible and stretchable interconnects, replica-molded microneedle electrodes, and advanced machine learning techniques for improved signal to noise ratio and reduced noise and motion artefacts. A set of general improvements and novel advancements are examined and applied in real-world electroencephalography-based brain-machine interfaces. These real-world improvements and applications show potential for restoring function to and improving quality of life of severely disabled subjects. Wireless, wearable electroencephalograms and dry non-invasive electrodes can be utilized to allow recording of brain activity on a mobile subject to allow for unrestricted movement. Additionally, multilayer microfabricated flexible circuits, combined with a soft materials platform, provide imperceptible wearable electronics for wireless, portable, long-term recording of brain signals. This dissertation focuses on sharing the study outcomes in soft materials, flexible electronics, and machine learning for universal brain-machine interfaces that could offer remedies in communication and movement for these individuals.
