Open Source EEG Platform with Reconfigurable Features for Multiple-Scenarios

Electroencephalogram (EEG) acquisition systems are widely used as diagnostic and research tools. This document shows the implementation of a reconfigurable family of three affordable 8-channels, 24 bits of resolution, EEG acquisition systems intended for a wide variety of research purposes. The three devices offer a modular design and upgradability, permitting changes in the firmware and software. Due to the nature of the Analog Front-End (AFE) used, no high-pass analog filters were implemented, allowing the capture of very low frequency components. Two systems of the family, called “RF-Brain” and “Bluetooth-Brain”, were designed to be light and wireless, planned for experimentation where movement of the subject cannot be restricted. The sample rate in these systems can be configured up to 2000 samples per second (SPS) for the RF-Brain and 250 SPS for the Bluetooth-Brain when the 8 channels are used. If fewer channels are required, the sampling frequency can be higher (up to 4 kSPS or 2 kSPS for 1 channel for RF-Brain and Bluetooth-Brain respectively). The third system, named “USB-Brain”, is a wired device designed for purposes requiring high sampling frequency acquisition and general purpose ports, with sampling rates up to 4 kSPS

Multimodal functional neuroimaging of epilepsy and Pain

University of Minnesota Ph.D. dissertation.June 2015. Major: Biomedical Engineering. Advisor: Bin He. 1 computer file (PDF); vi, 139 pages.The overall goal of this thesis work is to use advanced noninvasive neuroimaging modalities and techniques to study the underlying neurological mechanism of both diseased and healthy brains. The two main applications of this work are for the diagnosis of epilepsy and management of pain. Epilepsy is one of the most prevalent neurological disorders. It affects an estimated 2.7 million Americans. There are two broad types of epilepsies: partial and generalized epilepsy. For patients with drug resistant focal epilepsy, which account for one third of the patient population, surgical resection may provide the opportunity of seizure control. Existing presurgical planning methods are not only invasive in nature; they may also fail to provide additional information needed for surgery due to the relatively limited spatial coverage. On the other hand, idiopathic generalized epilepsy (IGE), unlike focal or partial epilepsy, often affects the whole or a larger portion of the brain without obvious, known cause. Treatment options are more restricted as resection is not a choice. Therefore, it is important to understand the underlying network which generates epileptic activity and through which epileptic activity propagates. The aim of the present study in the epilepsy portion was to use noninvasive imaging techniques including fMRI and EEG to localize epileptic areas for the purpose of assisting surgical planning in the focal epilepsy cases; and to improve our understanding the underlying mechanism of generalized epilepsy, thalamocortical relationship in the IGE cases. Chronic Pain is one of the biggest medical burdens in developed countries, affecting 20% of adult population with estimated economic cost in the United States alone over $150 billion. Functional imaging of brain networks associated with pain processing is of vital importance to aid developing new pain-relief therapies and to better understand the mechanisms of pain perception. The long-term goal of this project is to study the neurological mechanism of subjective perception of pain using non-invasive neuroimaging methods. In the present work of the pain portion, changes brain activities in healthy subjects experiencing sustained external painful stimuli were first studied. Neural activities in patient with sickle cell disease, who often surfer spontaneous acute or chronic pain as one of the comorbidities of the disease, were contrasted with healthy controls to study changes in neural network as a result of prolonged exposure to internal In summary, the present dissertation research developed and evaluated the spatiotemporal imaging approaches for the non-invasive mapping of network activities in the diseased and normal brain. Evaluations were conducted in patient and healthy control groups in order to test the clinical applicability of such a pre-surgical noninvasive imaging tool. An investigation has been conducted to study the widespread GSWDs of generalized epilepsy patients. The spatial resolution has been further improved by adding the component of fMRI through an EEG-fMRI integrated imaging framework. For the application in pain study, two investigations were conducted to study changes in network level activity due to external pain in healthy subjects and spontaneous pain in patients with SCD. All of the results that were obtained suggest the importance of noninvasive spatiotemporal neuroimaging approaches for solving clinical problems and for investigating neuroscience questions. Furthermore, an improved understanding of neurological diseases and their mechanisms would help us to develop and deliver curative treatments of neurological diseases

Tracking the temporal dynamics of cultural perceptual diversity in visual information processing

Human perception and cognition processing are not universal. Culture and experience markedly modulate visual information sampling in humans. Cross-cultural studies comparing between Western Caucasians (WCs) and East Asians (EAs) have shown cultural differences in behaviour and neural activities in regarding to perception and cognition. Particularly, a number of studies suggest a local perceptual bias for Westerners (WCs) and a global bias for Easterners (EAs): WCs perceive most efficiently the salient information in the focal object; as a contrast EAs are biased toward the information in the background. Such visual processing bias has been observed in a wide range of tasks and stimuli. However, the underlying neural mechanisms of such perceptual tunings, especially the temporal dynamic of different information coding, have yet to be clarified. Here, in the first two experiments I focus on the perceptual function of the diverse eye movement strategies between WCs and EAs. Human observers engage in different eye movement strategies to gather facial information: WCs preferentially fixate on the eyes and mouth, whereas EAs allocate their gaze relatively more on the center of the face. By employing a fixational eye movement paradigm in Study 1 and electroencephalographic (EEG) recording in study 2, the results confirm the cultural differences in spatial-frequency information tuning and suggest the different perceptual functions of preferred eye movement pattern as a function of culture. The third study makes use of EEG adaptation and hierarchical visual stimulus to access the cultural tuning in global/local processing. Culture diversity driven by selective attention is revealed in the early sensory stage. The results here together showed the temporal dynamic of cultural perceptual diversity. Cultural distinctions in the early time course are driven by selective attention to global information in EAs, whereas late effects are modulated by detail processing of local information in WC observers

Digitally-assisted, ultra-low power circuits and systems for medical applications

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2010.Cataloged from PDF version of thesis.Includes bibliographical references (p. 219-225).In recent years, trends in the medical industry have created a growing demand for a variety of implantable medical devices. At the same time, advances in integrated circuits techniques, particularly in CMOS, have opened possibilities for advanced implantable systems that are very small and consume minimal energy. Minimizing the volume of medical implants is important as it allows for less invasive procedures and greater comfort to patients. Minimizing energy consumption is imperative as batteries must last at least a decade without replacement. Two primary functions that consume energy in medical implants are sensor interfaces that collect information from biomedical signals, and radios that allow the implant to communicate with a base-station outside of the body. The general focus of this work was the development of circuits and systems that minimize the size and energy required to carry out these two functions. The first part of this work focuses on laying down the theoretical framework for an ultra-low power radio, including advances to the literature in the area of super-regeneration. The second part includes the design of a transceiver optimized for medical implants, and its implementation in a CMOS process. The final part describes the design of a sensor interface that leverages novel analog and digital techniques to reduce the system's size and improve its functionality. This final part was developed in conjunction with Marcus Yip.by Jose L. Bohorquez.Ph.D