Possibilities offered by implantable miniaturized cuff-electrodes for insect neurophysiology

AbstractRecent advances in microsystems technology led to a miniaturization of cuff-electrodes, which suggests these electrodes not just for long-term neuronal recordings in mammalians, but also in medium-sized insects. In this study we investigated the possibilities offered by cuff-electrodes for neuroethology using insects as a model organism. The implantation in the neck of a tropical bushcricket resulted in high quality extracellular nerve recordings of different units responding to various acoustic, vibratory, optical and mechanical stimuli. In addition, multi-unit nerve activity related to leg movements was recorded in insects walking on a trackball. A drawback of bi-polar nerve recordings obtained during tethered flight was overlay of nerve activity with large amplitude muscle potentials. Interestingly, cuff-electrode recordings were robust to withstand walking and flight activity so that good quality nerve recordings were possible even three days after electrode implantation. Recording multi-unit nerve activity in intact insects required an elaborate spike sorting algorithm in order to discriminate neuronal units responding to external stimuli from background activity. In future, a combination of miniaturized cuff-electrodes and light-weight amplifiers equipped with a wireless transmitter will allow the investigation of neuronal processes underlying natural behavior in freely moving insects. By this means cuff-electrodes may contribute to the development of realistic neuronal models simulating neuronal processes underlying natural insect behavior, such like mate choice and predator avoidance

Locomotion response of airborne, ambulatory and aquatic insects to thermal stimulation using piezoceramic microheaters

This paper reports the locomotion response of airborne, ambulatory and aquatic insects to thermal stimulation. A finite element model has been developed to predict the variation of insect–stimulator interface temperature with input power. Piezothermal stimulators have been fabricated from lead zirconate titanate (PZT) using a batch mode micro ultrasonic machining process. Typical sizes range from 200 µm to 3.2 mm. For PZT stimulators, the temperature and thermal efficiency reach the maximum value around the resonance frequency which is typically in the range of 650 kHz to 47 MHz. Experiments have been conducted on green June beetles (GJBs), Madagascar hissing roaches and green diving beetles (GDBs) in order to show the versatility of the proposed technique. The stimulators have been implanted near the antennae of the GJBs and on either side of the thorax of the Madagascar hissing roaches and GDBs, respectively. In all cases, the insects move away from the direction of the actuated stimulator. The left and right turns are statistically similar. Thermal stimulation achieves an overall success rate of 78.7%, 92.8% and 61.6% in GJBs, roaches and GDBs, respectively. On average, thermal stimulation results in an angle turn of about 13.7°–16.2° on GJBs, 30°–45° on the roaches and 30°–50° on GDBs. The corresponding average input power is 360, 330 and 100 mW for GJBs, roach and GDBs, respectively. Scaling limits of the PZT stimulators for operating these stimulators are also discussed.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/90797/1/0960-1317_21_12_125002.pd

Wireless multi-channel sensor for neurodynamic studies

Journal ArticleThis paper presents the design of a bio-compatible, implantable neural recording device for Aplysia californica, a common sea slug. Low-voltage extracellular neural signals (<100 μV) are recorded using a high-performance, low-power, low-noise preamplifier that is integrated with programmable data acquisition and control, and FSK telemetry that provides 5-kbps wireless neural data through 18 cm of saltwater. The telemetry utilizes an 8-cm electric dipole antenna matched to 50 Ω by exposing the ends of the antenna to the saltwater. A 3-V lithium ion battery (160 mAh) allows 16 hours of recording. Neural data obtained using extracellular nerve electrodes and a wired interface to this device have 2.5-µVrms noise, comparable to commercial neural recording equipment

Gripper Mechanism Utilizing Biological Exoskeleton Structure and Movement : Invention and Embodiment of a Gripping Mechanism using the Opening and Closing Movements of Armadillidiidae

The 11th International Symposium on Adaptive Motion of Animals and Machines. Kobe University, Japan. 2023-06-06/09. Adaptive Motion of Animals and Machines Organizing Committee.Poster Session P6

A Low-Power Wireless Multichannel Microsystem for Reliable Neural Recording.

This thesis reports on the development of a reliable, single-chip, multichannel wireless biotelemetry microsystem intended for extracellular neural recording from awake, mobile, and small animal models. The inherently conflicting requirements of low power and reliability are addressed in the proposed microsystem at architectural and circuit levels. Through employing the preliminary microsystems in various in-vivo experiments, the system requirements for reliable neural recording are identified and addressed at architectural level through the analytical tool: signal path co-optimization. The 2.85mm×3.84mm, mixed-signal ASIC integrates a low-noise front-end, programmable digital controller, an RF modulator, and an RF power amplifier (PA) at the ISM band of 433MHz on a single-chip; and is fabricated using a 0.5µm double-poly triple-metal n-well standard CMOS process. The proposed microsystem, incorporating the ASIC, is a 9-channel (8-neural, 1-audio) user programmable reliable wireless neural telemetry microsystem with a weight of 2.2g (including two 1.5V batteries) and size of 2.2×1.1×0.5cm3. The electrical characteristics of this microsystem are extensively characterized via benchtop tests. The transmitter consumes 5mW and has a measured total input referred voltage noise of 4.74µVrms, 6.47µVrms, and 8.27µVrms at transmission distances of 3m, 10m, and 20m, respectively. The measured inter-channel crosstalk is less than 3.5% and battery life is about an hour. To compare the wireless neural telemetry systems, a figure of merit (FoM) is defined as the reciprocal of the power spent on broadcasting one channel over one meter distance. The proposed microsystem’s FoM is an order of magnitude larger compared to all other research and commercial systems. The proposed biotelemetry system has been successfully used in two in-vivo neural recording experiments: i) from a freely roaming South-American cockroach, and ii) from an awake and mobile rat.PhDElectrical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/91542/1/aborna_1.pd

Development of a Micro Recording Probe for Measurements of Neuronal Activity in Freely Moving Animals

To discover general principles of biological sensorimotor control, insects have become remarkably successful model systems. In contrast to highly complex mammals, the functional organization of the insect nervous system in combination with a well-defined behavioural repertoire turned out to provide ideal conditions for quantitative studies into the neural control of behaviour. In addition, the search for biologically inspired control algorithms has further accelerated research into the neuronal mechanisms underlying flight and gaze stabilization, especially in blowflies. However, recording the neuronal activity in freely behaving insects, in particular in comparatively small insects such as blowflies, still imposes a major technical challenge. To date, electrophysiological recordings in unrestrained flies have never been achieved. This thesis describes the design and testing of a micro recording probe to be used for monitoring extracellular electrical activity in the nervous system of freely moving blowflies. In principle, this probe could also be used to study the neuronal control of behaviour in any other animal species the size of which is bigger than that of a blowfly. The nature of neuronal signals and the objective to record neuronal activity from behaving blowflies puts massive constraints on the specifications of the probe. I designed a differential amplifier with high gain, high linearity, low noise, and low power consumption. To fit the probe in the blowfly‟s head capsule and in direct contact with the animal‟s brain, the amplifier is on an unpackaged die. The neuronal signals are in the order of a few 100s of μV in amplitude. To be able to digitize such small signals >1000 times amplification is desirable. The small signal amplitudes also necessitate minimization of circuit noise. Linearity is necessary to prevent distortion of signal shape. Since connecting wires would impede movement of the animal, the probe would need to be powered by batteries. Therefore, low power is needed for two reasons: (i) to increase battery life, and therefore recording time, and (ii) because heat caused by power expenditure may damage the blowfly‟s brain or change its behaviour. To reduce power consumption I used CMOS transistors biased in the subthreshold region and a 2.2 V low power supply. The amplifier was characterized after fabrication by means of measuring its frequency response, linearity, and noise. I also recorded signals from a blowfly's brain and compared the performance of my recording probe with the performance of a high specification commercial amplifier in the time and frequency domains

Un sistema telemétrico para la captura de potenciales de acción extracelulares, reposicionamiento de los microelectrodos y captura de la actividad motora en ratas

En el presente trabajo, se presenta una herramienta destinada a proporcionar una solución a un problema metodológico que por varios años no ha sido satisfactoriamente solucionado para algunos grupos de investigación en neurociencias. Estos grupos buscan detectar y medir cambios en la frecuencia de disparo por medio del registro extracelular, de neuronas de núcleos subcorticales envueltos en el control de la actividad motora voluntaria de ratas, mientras capturan la información de dicha actividad motora (cambios en la velocidad de desplazamiento, distancias recorridas, erguimientos, etc.). Todo esto mientras someten a dichas ratas a manipulaciones farmacológicas, para de esa manera obtener mas información cuantitativa sobre las dosis y tipos de fármacos que emplean y los cambios en actividad eléctrica y conducta que detecten. Estos registros de actividad eléctrica y motora resultan mas fidedignos en cuanto que se realicen con el mínimo de restricciones al animal (cables, conexiones) y manipulaciones (tomar al animal con las manos, anestesiarlo), ya que todas estas acciones alteran los patrones de disparo neuronal y en consecuencia las conductas motoras detectadas debido a la introducción de estrés, alteraciones fisiológicas y bioquímicas. La herramienta aquí presentada permite el registro de la actividad neuronal de manera telemétrica inalámbrica, así como reposicionar en profundidad los microelectrodos empleados de la misma manera sin necesidad de manipular al animal. Y permite también detectar y capturar la actividad motora que exhiban las ratas, así como analizar de manera cuantitativa los cambios que estas exhiban

Modulated Backscatter for Low-Power High-Bandwidth Communication

<p>This thesis re-examines the physical layer of a communication link in order to increase the energy efficiency of a remote device or sensor. Backscatter modulation allows a remote device to wirelessly telemeter information without operating a traditional transceiver. Instead, a backscatter device leverages a carrier transmitted by an access point or base station.</p><p>A low-power multi-state vector backscatter modulation technique is presented where quadrature amplitude modulation (QAM) signalling is generated without running a traditional transceiver. Backscatter QAM allows for significant power savings compared to traditional wireless communication schemes. For example, a device presented in this thesis that implements 16-QAM backscatter modulation is capable of streaming data at 96 Mbps with a radio communication efficiency of 15.5 pJ/bit. This is over 100x lower energy per bit than WiFi (IEEE 802.11).</p><p>This work could lead to a new class of high-bandwidth sensors or implantables with power consumption far lower than traditional radios.</p>Dissertatio

Dissection of Affective Catecholamine Circuits Using Traditional and Wireless Optogenetics

Parsing the complexity of the mammalian brain has challenged neuroscientists for thousands of years. In the early 21st century, advances in materials science and neuroscience have enabled unprecedented control of neural circuitry. In particular, cell-type selective manipulations, such as those with optogenetics and chemogenetics, routinely provide answers to previously intractable neurobiological questions in the intact, behaving animal. In this two-part dissertation, I first introduce new minimally invasive, wireless technology to perturb neural activity in the ventral tegmental area dopaminergic system of freely moving animals. I report a series of novel devices for studying and perturbing intact neural systems through optogenetics, microfluidic pharmacology, and electrophysiology. Unlike optogenetic approaches that rely on rigid, glass fiber optics coupled to external light sources, these novel devices utilize flexible substrates to carry microscale, inorganic light emitting diodes (μ-ILEDs), multimodal sensors, and/or microfluidic channels into the brain. Each class of device can be wirelessly controlled, enabling studies in freely behaving mice and achieving previously untenable control of catecholamine neural circuitry. In the second part of this dissertation, I apply existing cell-type selective approaches to dissect the role of the locus coeruleus noradrenergic (LC-NE) system in anxiety-like and aversive behaviors. The LC-NE system is one of the first systems engaged following a stressful event. While LC-NE neurons are known to be activated by many different stressors, the underlying neural circuitry and the role of this activity in generating stress-induced anxiety has not been elucidated until now. I demonstrate that increased tonic activity of LC-NE neurons is both necessary and sufficient for stress-induced anxiety; a behavior which is driven by LC projections to the basolateral amygdala. Furthermore, this activity and behavior is elicited by corticotropin releasing hormone-containing afferent inputs into the LC from the central amygdala. These studies position the LC-NE system as a critical mediator of acute stress-induced anxiety and offer a potential intervention for preventing stress-related affective disorders. Together these two objectives provide a rich technological toolbox for neuroscientists and yield important knowledge of how small catecholamine structures with widespread forebrain innervation can selectively mediate higher order behaviors

Time Synchronization in Multimodal Wireless Cyber-Physical Systems: A Wearable Biopotential Acquisition and Collaborative Brain-Computer Interface Paradigm

Die Forschung zu Brain-Computer Interface (BCI) hat in den letzten drei Jahren riesige Fortschritte gemacht, nicht nur im Bereich der menschlich gesteuerten Roboter, der Steuerung von Prothesen, des Interpretierens von Wörtern, der Kommunikation in einer Virtual Reality Umgebung oder der Computerspiele, sondern auch in der kognitiven Neurologie. Patienten, die unter enormen motorischen Dysfunktionen leiden (letztes Stadium Amyotrophe Lateralsklerose) könnten solch ein BCI System als alternatives Medium zur Kommunikation durch die eigene Gehirnaktivität nutzen. Neuste Studien zeigen, dass die Verwendung dieses BCI Systems in einem Gruppenexperiment helfen kann die menschliche Entscheidungstreffung deutlich zu verbessern. Dies ist ein neues Feld des BCI, nämlich das Collaborative BCI. Einerseits erfordert die Durchführung solch eines Gruppenexperiments drahtlose Hochleistungs-EEG Systeme, basierend auf BCI, welches kostengünstig und tragbar sein sollte und Langzeit-Monitoring hochwertiger EEG Daten sicherstellt. Andererseits ist es erforderlich, eine Zeitsynchronisierung zwischen den einzelnen BCI Systemen einzusetzen, damit diese für ein Gruppenexperiment zum Einsatz kommen können. Diese Herausforderungen setzten die Grundlage dieser Doktorarbeit. In dieser Arbeit wurde ein neuartiges, nicht invasives, modulares, biopotentiales Messsystem entwickelt: Dieses kann Breitband (0.5 Hz–150 Hz) Biopotentiale ableiten, bestehend aus Elektromyographie (EMG), Elektrokardiografie (EKG), Elektroencephalografie (EEG), wurde insgesamt bezeichnet als ExG bzw. das Messsystem als ExG-System benannt. Die Modularität des ExG-Systems erlaubt 8 bis hin zu 256 Kanäle zu konfigurieren, je nach Anforderung, ob in einen textilen Schlauch eingekapselt zur Erfassung von EMG Signalen, in eine textilen Weste zur Erfassung von ECG Signalen oder in eine textilen Kappe zur Erfassung von EEG Signalen. Der Einbau des ExG-Systems in eine Kappe wurde ebenfalls im Rahmen der Arbeit entwickelt. Der letzte Schritt des ExG-Systems zeigt niedriges Eingangsrauschen von 7 µVvon-Spitze-zu-Spitze und benötigt 41 mW/Kanal der Datenaufnahme im aktiven Zustand. Ein WiFi-Modul wurde für eine drahtlose Datenübertragung an einen ferngesteuerten PC in das ExG-System eingebaut. Um mit dem entwickelte System BCI Anwendungen zu ermöglichen, wurde ein akustisch und visuell evozierter Potenzialstimulator (SSVEP/AEP Stimulator) entwickelt. In eben diesem wurde ein Rasperry Pi als Zentralrechner benutzt und ein Bash basiertes Player-Skript iii einprogrammiert, das Mediadaten (Video, Audio, Ton) aus der Angabe einer Lookup Tabelle (LUT) in ihr Linux Betriebssystem spielt. Im Rahmen der Arbeit wurde eine Zeitsynchronisierung an einigen dieser ExG-Systeme mit Hilfe von einer eingebetteten Hardware/Softwarelösung durchgeführt. Die Hardwareteile bestehen aus einigen Leiterplatten, nämlich Sync Modulen mit einem Quarzoszillator, einem Mikrocontroller und einem Funkmodul (Hierbei Bluetooth 4.0). Eines von diesen ist das Sync-Addon, das mit jedem Messsystem (z.B. ExG-System) das zu synchronisieren ist, angeschlossen wird. Das andere bezeichnet man als Sync-Center, das an die Datenverarbeitungsrechner angehängt wird. Das Softwareteil übernimmt den Zeitsynchronisierungsmechanismus mit Hilfe eines funkbasierten Protokolls. Im Rahmen der Arbeit wurde ein neues energieeffizientes pairwise broadcast Zeitsynchronisationsprotokoll (PBS), welches nur theoretisch vorgestellt wurde, experimentell verifiziert. Außerdem wurde es mit anderen bestehenden Zeitsynchronisationsprotokollen auf dem aktuellen Stand der Technik evaluiert, basierend auf den Ergebnissen der gleichen Hardwareebene. In der letzten Iteration der Sync-Module wurde ein durchschnittlicher Synchronisationsfehler von 2 ms, den Konfidenzintervall von 95% berücksichtigend, erlangt. Da für Collaborative BCI, P300, ein Ereignis bezogenes Potenzial mit dem Auslöseimpuls, der 300−500 ms nach dem Vorgang eintritt, eingestellt wurde, ist die erreichte Synchronisationsgenauigkeit genügend, um solch ein Experiment durchzuführen.Brain-computer interface (BCI) has experienced the last three decades tremendous technological advances not only in the field of human controller robotics, or in controlling prosthesis, or in spelling words, or in interacting with a virtual reality environment, or in gaming but also in cognitive neuroscience. Patients suffering from severe motoric dysfunction (e.g. late stage of Amyotrophic Lateral Sclerosis) may utilise such a BCI system as an alternative medium of communication by mental activity. Recently studies have shown that usage of such BCI in a group experiment can help to improve human decision making. This is a new field of BCI, namely collaborative BCI. On one hand, performing such group experiments require wireless, high density EEG system based BCI which should be low-cost, wearable and provide long time monitoring of good quality EEG data. On the other hand time synchronization is required to be established among a group of BCI systems if they are employed for such a group experiments. These drawbacks set the foundation of this thesis work. In this work a novel non-invasive modular biopotential measurement system which can acquire wideband (0.15 Hz–200 Hz) biopotential signals consisting Electromyography (EMG), Electrocardiography (ECG), Electroencephalography (EEG) together called ExG, following ExG-system was designed. The modularity of the ExG-system allows it to be configured from 8 up to 256 channels according to the requirement if it’s to be encapsulated in a textile sleeve for recording of EMG signals, or in a textile vest for recording of ECG signals, or in a textile cap for recording of EEG signals. The assembly of the ExG-system in cap was also developed during the scope of the work. The final iteration of the ExG-system exhibits low input noise of 7 µVpeak-to-peak and require 41 mW/channel of data recording in active state. A WiFi module was embedded into the ExG-system for wireless data transmission to a remote PC. To enable the developed system for BCI applications a steady-state visually/auditory evoked potential stimulator (SSVEP/AEP stimulator) incorporating a Raspberry Pi as a main computer and a bash based player script which plays media data (video, pictures, sound) as defined in a lookup table in the Linux operating system of it. Within the scope of the work time synchronization among a group of such ExG-systems was further realized with the help of an embedded hardware/software solution. The hardware part consists of two different PCB sync modules that are incorporated with a crystal oscillator a microcontroller, a radio module (in this case Bluetooth 4.0). One of them is called the v sync-addon which is to be attached to each of the measurement systems (e.g. ExG-system) that are to be synchronized and the sync-center which is to be attached to the remote PC. On the software part, a wireless time synchronization protocol exchanging timing information among the sync-center and sync-addons must establish tight time synchronization between the ExG-system. Within the framework of this work, a novel time synchronization protocol energy efficient pairwise broadcast synchronization protocol (PBS) that was only theoretically proposed before but not evaluated on real hardware was experimentally evaluated with the developed sync modules. Moreover a benchmarking with other state-of-the-art existing time synchronization protocols based on the results from same hardware platform were drawn. In the final iteration of sync modules an average synchronization error of 2 ms was achieved considering the 95% of confidence interval. Since for collaborative BCI, P300, an event related potential was triggered with the stimuli that occur 300−500 ms after the event, the achieved synchronization accuracy is sufficient to conduct such experiments