Ultra-low power mixed-signal frontend for wearable EEGs

Electronics circuits are ubiquitous in daily life, aided by advancements in the chip design industry, leading to miniaturised solutions for typical day to day problems. One of the critical healthcare areas helped by this advancement in technology is electroencephalography (EEG). EEG is a non-invasive method of tracking a person's brain waves, and a crucial tool in several healthcare contexts, including epilepsy and sleep disorders. Current ambulatory EEG systems still suffer from limitations that affect their usability. Furthermore, many patients admitted to emergency departments (ED) for a neurological disorder like altered mental status or seizures, would remain undiagnosed hours to days after admission, which leads to an elevated rate of death compared to other conditions. Conducting a thorough EEG monitoring in early-stage could prevent further damage to the brain and avoid high mortality. But lack of portability and ease of access results in a long wait time for the prescribed patients. All real signals are analogue in nature, including brainwaves sensed by EEG systems. For converting the EEG signal into digital for further processing, a truly wearable EEG has to have an analogue mixed-signal front-end (AFE). This research aims to define the specifications for building a custom AFE for the EEG recording and use that to review the suitability of the architectures available in the literature. Another critical task is to provide new architectures that can meet the developed specifications for EEG monitoring and can be used in epilepsy diagnosis, sleep monitoring, drowsiness detection and depression study. The thesis starts with a preview on EEG technology and available methods of brainwaves recording. It further expands to design requirements for the AFE, with a discussion about critical issues that need resolving. Three new continuous-time capacitive feedback chopped amplifier designs are proposed. A novel calibration loop for setting the accurate value for a pseudo-resistor, which is a crucial block in the proposed topology, is also discussed. This pseudoresistor calibration loop achieved the resistor variation of under 8.25%. The thesis also presents a new design of a curvature corrected bandgap, as well as a novel DDA based fourth-order Sallen-Key filter. A modified sensor frontend architecture is then proposed, along with a detailed analysis of its implementation. Measurement results of the AFE are finally presented. The AFE consumed a total power of 3.2A (including ADC, amplifier, filter, and current generation circuitry) with the overall integrated input-referred noise of 0.87V-rms in the frequency band of 0.5-50Hz. Measurement results confirmed that only the proposed AFE achieved all defined specifications for the wearable EEG system with the smallest power consumption than state-of-art architectures that meet few but not all specifications. The AFE also achieved a CMRR of 131.62dB, which is higher than any studied architectures.Open Acces

The effect of leads on cognitive load and learning in a conceptually rich hypertext environment

The purpose of this experiment was to determine whether leads affect cognitive load and learning from conceptually rich hypertext. Measures of cognitive load included self-report of mental effort, reading time, and event-related desynchronization percentage of alpha, beta, and theta brain wave rhythms. Conceptual and structural knowledge tests, as well as a recall measure were used to determine learning performance. Measures of learners\u27 reading ability, prior knowledge, and metacognitive awareness were employed to establish the effect of individual differences on cognitive load and learning from traditional and lead-augmented hypertext. Results demonstrated that while leads appeared to reduce brain wave activity associated with split attention, processing of redundant information contained in hypertext nodes may have increased extraneous cognitive load, and decreased germane load that is required for learning to take place. Whereas the benefits of leads relative to cognitive load and learning may have been mediated by the redundancy effect, learners with better developed metacognitive skills tended to use leads as a tool to review information in the linked nodes while revisiting content in the primary text passage. Limitations of the currently available cognitive load measures are discussed as applied to direct assessment of this theoretical construct

Smart Sensor Networks For Sensor-Neural Interface

One in every fifty Americans suffers from paralysis, and approximately 23% of paralysis cases are caused by spinal cord injury. To help the spinal cord injured gain functionality of their paralyzed or lost body parts, a sensor-neural-actuator system is commonly used. The system includes: 1) sensor nodes, 2) a central control unit, 3) the neural-computer interface and 4) actuators. This thesis focuses on a sensor-neural interface and presents the research related to circuits for the sensor-neural interface. In Chapter 2, three sensor designs are discussed, including a compressive sampling image sensor, an optical force sensor and a passive scattering force sensor. Chapter 3 discusses the design of the analog front-end circuit for the wireless sensor network system. A low-noise low-power analog front-end circuit in 0.5μm CMOS technology, a 12-bit 1MS/s successive approximation register (SAR) analog-to-digital converter (ADC) in 0.18μm CMOS process and a 6-bit asynchronous level-crossing ADC realized in 0.18μm CMOS process are presented. Chapter 4 shows the design of a low-power impulse-radio ultra-wide-band (IR-UWB) transceiver (TRx) that operates at a data rate of up to 10Mbps, with a power consumption of 4.9pJ/bit transmitted for the transmitter and 1.12nJ/bit received for the receiver. In Chapter 5, a wireless fully event-driven electrogoniometer is presented. The electrogoniometer is implemented using a pair of ultra-wide band (UWB) wireless smart sensor nodes interfacing with low power 3-axis accelerometers. The two smart sensor nodes are configured into a master node and a slave node, respectively. An experimental scenario data analysis shows higher than 90% reduction of the total data throughput using the proposed fully event-driven electrogoniometer to measure joint angle movements when compared with a synchronous Nyquist-rate sampling system. The main contribution of this thesis includes: 1) the sensor designs that emphasize power efficiency and data throughput efficiency; 2) the fully event-driven wireless sensor network system design that minimizes data throughput and optimizes power consumption

VLSI Circuits for Bidirectional Neural Interfaces

Medical devices that deliver electrical stimulation to neural tissue are important clinical tools that can augment or replace pharmacological therapies. The success of such devices has led to an explosion of interest in the field, termed neuromodulation, with a diverse set of disorders being targeted for device-based treatment. Nevertheless, a large degree of uncertainty surrounds how and why these devices are effective. This uncertainty limits the ability to optimize therapy and gives rise to deleterious side effects. An emerging approach to improve neuromodulation efficacy and to better understand its mechanisms is to record bioelectric activity during stimulation. Understanding how stimulation affects electrophysiology can provide insights into disease, and also provides a feedback signal to autonomously tune stimulation parameters to improve efficacy or decrease side-effects. The aims of this work were taken up to advance the state-of-the-art in neuro-interface technology to enable closed-loop neuromodulation therapies. Long term monitoring of neuronal activity in awake and behaving subjects can provide critical insights into brain dynamics that can inform system-level design of closed-loop neuromodulation systems. Thus, first we designed a system that wirelessly telemetered electrocorticography signals from awake-behaving rats. We hypothesized that such a system could be useful for detecting sporadic but clinically relevant electrophysiological events. In an 18-hour, overnight recording, seizure activity was detected in a pre-clinical rodent model of global ischemic brain injury. We subsequently turned to the design of neurostimulation circuits. Three critical features of neurostimulation devices are safety, programmability, and specificity. We conceived and implemented a neurostimulator architecture that utilizes a compact on-chip circuit for charge balancing (safety), digital-to-analog converter calibration (programmability) and current steering (specificity). Charge balancing accuracy was measured at better than 0.3%, the digital-to-analog converters achieved 8-bit resolution, and physiological effects of current steering stimulation were demonstrated in an anesthetized rat. Lastly, to implement a bidirectional neural interface, both the recording and stimulation circuits were fabricated on a single chip. In doing so, we implemented a low noise, ultra-low power recording front end with a high dynamic range. The recording circuits achieved a signal-to-noise ratio of 58 dB and a spurious-free dynamic range of better than 70 dB, while consuming 5.5 μW per channel. We demonstrated bidirectional operation of the chip by recording cardiac modulation induced through vagus nerve stimulation, and demonstrated closed-loop control of cardiac rhythm

Analog Compressive Sensing for Multi-Channel Neural Recording: Modeling and Circuit Level Implementation

RÉSUMÉ Dans cette thèse, nous présentons la conception d’un implant d’enregistrement neuronal multicanaux avec un échantillonnage compressé mis en oeuvre avec un procédé de fabrication CMOS à 65 nm. La réduction de la technologie a˙ecte à la baisse les paramètres des amplificateurs neuronaux couplés en AC, comme la fréquence de coupure basse, en raison de l’e˙et de canal court des transistors MOS. Nous analysons la fréquence de coupure basse et nous constatons que l’origine de ce problème, dans les technologies avancées, est la diminution de l’impédance d’entrée de l’amplificateur opérationnel de transconductance (OTA) en raison de la fuite d’oxyde de grille à l’entrée des OTA. Nous proposons deux solutions pour réduire la fréquence de coupure basse sans augmenter la valeur des condensateurs de rétroaction de l’étage d’entrée. La première solution est appelée rétroaction positive croisée et la deuxième solution utilise des PMOS à oxyde épais dans la paire de l’entrée di˙érentielle de l’OTA. Il est à noter que pour compresser le signal neuronal, nous utilisons le CS dans le domaine analogique. Pour la réalisation, un intégrateur à capacité commutée est requis. Les paramètres non idéaux de l’OTA utilisé dans cet intégrateur, tels que le gain fini, la bande passante, la vitesse de balayage et le changement rapide de la sortie. Toutes ces imperfections induisent des erreurs et réduisent le rapport signal sur bruit (SNR) total. Nous avons simulé ces imperfections sur Matlab et Simulink pour définir les spécifications de l’OTA requis. Aussi, pour concevoir les circuits analogiques correspondant aux interfaces neuronales requises, tels qu’un amplificateur neuronal, une référence de tension compacte et à faible consommation d’énergie est requise. Nous avons proposé une référence de tension de faible consommation d’énergie sans utiliser le transistor bipolaire parasite de la technologie CMOS pour diminuer la surface de silicium requise. Finalement, nous avons complété l’encodeur de CS et un convertisseur analogique-numérique à approximation successive (SAR ADC) requis pour la chaine d’enregistrement des signaux neuronaux dans ce projet.----------ABSTRACT In this thesis we present the design of a multi-channel neural recording implant with analog compressive sensing (CS) in 65 nm process. Scaling down technology demotes the parameters of AC-coupled neural amplifiers, such as increasing the low-cuto˙ frequency due to the short-channel e˙ects of MOS transistors. We analyze the low-cuto˙ frequency and find that the main reason of this problem in advanced technologies is decreasing the input resistance of the operational transconductance amplifier (OTA) due to the gate oxide static current leakage in the input of the OTA. In advanced technologies, the gate oxide is thin and some electrons can penetrate to the channel and cause DC current leakage. We proposed two solutions to reduce the low-cuto˙ frequency without increasing the value of the feedback capacitors of the front-end neural amplifier. The first solution is called cross-coupled positive feedback, and the second solution is utilizing thick-oxide PMOS transistors in the input di˙erential pair of the OTA. Compress the neural signal, we utilized the CS method in analog domain. For its implementation, a switched-capacitor integrator is required. Non-ideal specifications of OTA of CS integrator such as finite gain, bandwidth, slew rate and output swing induce error and reduce the total signal to noise ratio (SNR). We simulated these non-idealities in Matlab and Simulink and extracted the specification of the required OTA. Also, to design analog circuits such as neural amplifier a low power and compact voltage reference is required. We implemented a low-power band-gap reference without utilizing parasitic bipolar transis-tor to decrease the silicon area. At the end, we completed the CS encoder and successive approximation architecture analog-to-digital converter (SAR ADC)

A Closed-Loop Bidirectional Brain-Machine Interface System For Freely Behaving Animals

A brain-machine interface (BMI) creates an artificial pathway between the brain and the external world. The research and applications of BMI have received enormous attention among the scientific community as well as the public in the past decade. However, most research of BMI relies on experiments with tethered or sedated animals, using rack-mount equipment, which significantly restricts the experimental methods and paradigms. Moreover, most research to date has focused on neural signal recording or decoding in an open-loop method. Although the use of a closed-loop, wireless BMI is critical to the success of an extensive range of neuroscience research, it is an approach yet to be widely used, with the electronics design being one of the major bottlenecks. The key goal of this research is to address the design challenges of a closed-loop, bidirectional BMI by providing innovative solutions from the neuron-electronics interface up to the system level. Circuit design innovations have been proposed in the neural recording front-end, the neural feature extraction module, and the neural stimulator. Practical design issues of the bidirectional neural interface, the closed-loop controller and the overall system integration have been carefully studied and discussed.To the best of our knowledge, this work presents the first reported portable system to provide all required hardware for a closed-loop sensorimotor neural interface, the first wireless sensory encoding experiment conducted in freely swimming animals, and the first bidirectional study of the hippocampal field potentials in freely behaving animals from sedation to sleep. This thesis gives a comprehensive survey of bidirectional BMI designs, reviews the key design trade-offs in neural recorders and stimulators, and summarizes neural features and mechanisms for a successful closed-loop operation. The circuit and system design details are presented with bench testing and animal experimental results. The methods, circuit techniques, system topology, and experimental paradigms proposed in this work can be used in a wide range of relevant neurophysiology research and neuroprosthetic development, especially in experiments using freely behaving animals

Low Power Circuits for Smart Flexible ECG Sensors

Cardiovascular diseases (CVDs) are the world leading cause of death. In-home heart condition monitoring effectively reduced the CVD patient hospitalization rate. Flexible electrocardiogram (ECG) sensor provides an affordable, convenient and comfortable in-home monitoring solution. The three critical building blocks of the ECG sensor i.e., analog frontend (AFE), QRS detector, and cardiac arrhythmia classifier (CAC), are studied in this research. A fully differential difference amplifier (FDDA) based AFE that employs DC-coupled input stage increases the input impedance and improves CMRR. A parasitic capacitor reuse technique is proposed to improve the noise/area efficiency and CMRR. An on-body DC bias scheme is introduced to deal with the input DC offset. Implemented in 0.35m CMOS process with an area of 0.405mm2, the proposed AFE consumes 0.9W at 1.8V and shows excellent noise effective factor of 2.55, and CMRR of 76dB. Experiment shows the proposed AFE not only picks up clean ECG signal with electrodes placed as close as 2cm under both resting and walking conditions, but also obtains the distinct -wave after eye blink from EEG recording. A personalized QRS detection algorithm is proposed to achieve an average positive prediction rate of 99.39% and sensitivity rate of 99.21%. The user-specific template avoids the complicate models and parameters used in existing algorithms while covers most situations for practical applications. The detection is based on the comparison of the correlation coefficient of the user-specific template with the ECG segment under detection. The proposed one-target clustering reduced the required loops. A continuous-in-time discrete-in-amplitude (CTDA) artificial neural network (ANN) based CAC is proposed for the smart ECG sensor. The proposed CAC achieves over 98% classification accuracy for 4 types of beats defined by AAMI (Association for the Advancement of Medical Instrumentation). The CTDA scheme significantly reduces the input sample numbers and simplifies the sample representation to one bit. Thus, the number of arithmetic operations and the ANN structure are greatly simplified. The proposed CAC is verified by FPGA and implemented in 0.18m CMOS process. Simulation results show it can operate at clock frequencies from 10KHz to 50MHz. Average power for the patient with 75bpm heart rate is 13.34W

Optimization of near-infrared spectroscopy-based neurofeedback for use in the treatment of attention-deficit hyperactivity disorder

Die Aufmerksamkeitsdefizit-Hyperaktivitätsstörung (ADHS) zählt zu den am häufigsten vorkommenden psychischen Störungen im Kindes- und Jugend-, aber auch im Erwachsenenalter, ca. 2,5-5% der Weltbevölkerung sind davon betroffen. Die Erkrankung wirkt sich in drei Kernbereichen aus: Hyperaktivität, Impulsivität und Unaufmerksamkeit, mit tiefgreifenden Beeinträchtigungen in verschiedenen Bereichen des Lebens, am deutlichsten in der Schule, bei der Arbeit und in interpersonellen Beziehungen. Es existieren verschiedene Behandlungsansätze, welche die vielseitige Symptomatologie der ADHS anzugehen versuchen. Die Medikation stellt dabei die gängigste Behandlungsmethode dar, ist jedoch nicht selten mit Nebenwirkungen verbunden. Die Methode des Neurofeedbacks (NF) ist zwar unlängst kein neuartiges Verfahren mehr, ist aber eine Behandlungsmethode, welche, aufgrund der fraglichen Wirksamkeit, in den letzten Jahren viele Diskussionen anregt hat. Da die Methode jedoch an der Schnittstelle zur Verhaltenstherapie und der neusten neurophysiologischen Forschung liegt, bietet sie die Möglichkeit fortwährend um die aktuellsten wissenschaftlichen Erkenntnisse erweitert zu werden. Die vorliegende Dissertation strebt die Optimierung des NIRS-basierten NF Paradigmas zur Behandlung von ADHS durch die Untersuchung folgender Punkte an: 1) Wie können NIRS-basierte Paradigmen in VR implementiert werden? 2) Welche sind die zugrundeliegenden Mechanismen, die für einen erfolgreichen NF Trial und Paradigma verantwortlich sind? 3) Wie können Methoden kombiniert werden um NF Paradigmen weiter zu entwickeln? Die Dissertation umfasst vier Studien. In Studie 1 untersuchten wir die Effektivität eines Nahinfrarotspektroskopie-(NIRS)-basierten NF Paradigmas, realisiert im virtuellen Klassenzimmer, zur Behandlung hoch-impulsiver Universitätsstudenten. In Studie 2 wurde ein ’Standard’- NIRS-basiertes NF Paradigma für ADHS in seinen Einzelteilen überprüft und Empfehlungen für die Weiterentwicklung eines NF Studiendesigns diskutiert sowie Netzwerke, welche mit Erfolg und Misserfolg bei NF Trials assoziiert sind, untersucht. In Studie 3 untersuchten wir das post-Fehlerverhalten bei ADHS-Patienten im Vergleich zu gesunden Kontrollpersonen (healthy controls, HC). Im Einzelnen betrachteten wir die ’P300-informed’ NIRS-Analyse um die Unterschiede zwischen ADHS-Patienten und HC genauer zu untersuchen. Zusätzlich wurde die Studie konzipiert um die Effektivität von EEG/NIRS für den zukünftigen Einsatz in einem multimodalen NF Studiendesign für ADHS zu überprüfen. In Studie 4 wird das Studiendesign für eine großangelegte und momentan laufende Studie mit Schulkindern mit ADHS beschrieben, in welcher das Paradigma aus Studie 1 zum Einsatz kommt. Dies liefert eine erste Zusammenfassung über die umfangreiche Datenerhebung, welche zu neuen Erkenntnissen bei NIRS-NF bei ADHS führen soll

Biomedical Engineering

Biomedical engineering is currently relatively wide scientific area which has been constantly bringing innovations with an objective to support and improve all areas of medicine such as therapy, diagnostics and rehabilitation. It holds a strong position also in natural and biological sciences. In the terms of application, biomedical engineering is present at almost all technical universities where some of them are targeted for the research and development in this area. The presented book brings chosen outputs and results of research and development tasks, often supported by important world or European framework programs or grant agencies. The knowledge and findings from the area of biomaterials, bioelectronics, bioinformatics, biomedical devices and tools or computer support in the processes of diagnostics and therapy are defined in a way that they bring both basic information to a reader and also specific outputs with a possible further use in research and development