Linear response for spiking neuronal networks with unbounded memory

We establish a general linear response relation for spiking neuronal networks, based on chains with unbounded memory. This relation allows us to predict the influence of a weak amplitude time-dependent external stimuli on spatio-temporal spike correlations, from the spontaneous statistics (without stimulus) in a general context where the memory in spike dynamics can extend arbitrarily far in the past. Using this approach, we show how linear response is explicitly related to neuronal dynamics with an example, the gIF model, introduced by M. Rudolph and A. Destexhe. This example illustrates the collective effect of the stimuli, intrinsic neuronal dynamics, and network connectivity on spike statistics. We illustrate our results with numerical simulations.Comment: 60 pages, 8 figure

Memory and information processing in neuromorphic systems

A striking difference between brain-inspired neuromorphic processors and current von Neumann processors architectures is the way in which memory and processing is organized. As Information and Communication Technologies continue to address the need for increased computational power through the increase of cores within a digital processor, neuromorphic engineers and scientists can complement this need by building processor architectures where memory is distributed with the processing. In this paper we present a survey of brain-inspired processor architectures that support models of cortical networks and deep neural networks. These architectures range from serial clocked implementations of multi-neuron systems to massively parallel asynchronous ones and from purely digital systems to mixed analog/digital systems which implement more biological-like models of neurons and synapses together with a suite of adaptation and learning mechanisms analogous to the ones found in biological nervous systems. We describe the advantages of the different approaches being pursued and present the challenges that need to be addressed for building artificial neural processing systems that can display the richness of behaviors seen in biological systems.Comment: Submitted to Proceedings of IEEE, review of recently proposed neuromorphic computing platforms and system

Modelling and analysis of neurons coupled by electrical synapses

The objective of this thesis is to analyze the role of the intrinsic properties of neurons in the communication through electrical synapses. Mesencephalic trigeminal neurons constitute an excellent experimental model to study the communication between neurons, because of its easy experimental access experimental and simple to model and analyze a biological system. Among the contributions of this thesis are: the complete modeling of the sodium currents and other ionic current (and its modulation); the explanation preference subthreshold frequency transfer between neuronfor example and its coupling. Some preliminary results of this work have been presented at international conferences.morphology. However, the analysis of real neurons is limited by experimental constraints that do not allow to explore all aspects of the model. Within the context of this thesis, a mathematical model is built, based on electrophysiological recordings made by Sebastián Curti at the School of Medicine of Universidad de la República. The model consists of a set of differential equations, which can be represented by a nonlinear electrical circuit. Some of the differential equations are obtained from literature and only some minor parameters’ adjustments are made. Moreover, during the thesis we have found that more data was needed in order to explain some of the most important features of the behavior of neurons, such as the duration of the action potential. Therefore, more experimental recordings were made, allowing to refine the model. The model allows to evaluate the response of the neuron to different stimuli (currents or voltages imposed by an electrode), making possible to make new “experiments” that are not possible in a laboratory. Alternatives models are analyzed (varying ionic currents and morphology) using experimental information to validate them. Then the model is used to understand some unusual features of the communication between neurons. First, it is studied the subthreshold transfer function (i.e. without action potentials) between neurons coupled by electrical synapses. A reduced model is used and then linearized, in order to derive an analytical expression of the transfer function, whose behaviour is consistent with experimental results. Moreover, numerical simulations are performed to analyze the rol of the intrinsic properties of neurons in their synchronization. It is shown that the same properties that determine the subthreshold behavior are relevant to improve synchronization between neurons too. Finally, this thesis contributes not only with new models and answers, but with new questions, which should be studied using experimental models as well. This thesis applies several tools used for electrical engineering (frequency response of systems, cable equation, Markov chains, evolutionary algorithms, etc.) to model and analyze a biological system. Among the contributions of this thesis are: the complete modeling of the sodium currents and other ionic current (and its modulation); the explanation preference subthreshold frequency transfer between neuronfor example and its coupling. Some preliminary results of this work have been presented at international conferences.El objetivo de esta tesis es analizar el rol de las propiedades intrínsecas de las neuronas en la comunicación a través de sinapsis eléctricas. Las neuronas del nervio trigeminal del mesencéfalo constituyen un excelente modelo experimental para estudiar la comunicación entre neuronas, debido a su fácil acceso experimental y su sencilla morfología. Sin embargo, el análisis de neuronas reales está limitado por restricciones experimentales que impiden explorar todos los aspectos del modelo. En el marco de esta tesis, se construye un modelo matemático basado en registros electrofisiológicos realizados por Sebastián Curti en la Facultad de Medicina de la Universidad de la República. El modelo consiste en un sistema de ecuaciones diferenciales, que puede ser representado por un circuito eléctrico con componentes no lineales. Algunas de las ecuaciones diferenciales son obtenidas de bibliografía y se realizan algunos ajustes menores de parámetros. Por otro lado, durante la tesis evaluamos que se necesitaba más información para reproducir algunas de las características más importantes del comportamientos de las neuronas, como la duración del potencial de acción. Por eso, se debieron realizar nuevos registros experimentales, que permitieron refinar el modelo. El modelo permite evaluar la respuesta de la neurona ante diferentes estímulos (corrientes o voltajes impuestos por un electrodo), posibilitando nuevos “experimentos” que no son posibles en un laboratorio. Se analizan diversas alternativas de modelado (variando corrientes iónicas y morfología) usando información experimental para validarlos. Luego, el modelo es utilizado para entender algunas características inusuales de la comunicación entre neuronas. En primer lugar, se estudia la transferencia subumbral (i.e.: sin potenciales de acción) entre neuronas acopladas por sinapsis eléctricas. Se utiliza un modelo reducido, que es linealizado para obtener una expresión analítica de la transferencia, cuyo comportamiento es coherente con los resultados experimentales. Asimismo, se realizan simulaciones numéricas para analizar el rol en la sincronización de las propiedades intrínsecas de las neuronas. Se muestra que las mismas propiedades que determinan el comportamiento subumbral son relevantes para mejorar la sincronización entre neuronas. Finalmente, esta tesis no sólo contribuye con nuevos modelos y respuestas, sino con nuevas preguntas, que deberán ser estudiadas usando modelos experimentales también. Esta tesis hace uso de diversas herramientas utilizadas por la ingeniería eléctrica (comportamiento en frecuencia de sistemas, ecuación del cable, cadenas de Markov, algoritmos evolutivos, etc) para modelar y analizar un sistema biológico. Se realizan diversos aportes, por ejemplo: modelado completo de las corrientes de sodio, así como de la modulación de otra corriente; explicación de la preferencia en frecuencia de la transferencia subumbral entre neuronas; estudio de la sincronización en función de las propiedades de los osciladores y de su acople. Algunos resultados preliminares de este trabajo han sido presentados en congresos internacionales

Neuromorphic cross correlation of digital spreading codes

Includes abstract.Includes bibliographical references (leaves 85-88).The study of neural networks is inspired by the mystery of how the brain works. In a quest to solve this mystery, scientists and engineers hope that they will learn how to build more powerful computational systems that are capable of processing information much more efficiently than today’s digital computer systems. This dissertation involves a biologically inspired circuit which can be used as an alternative for a cross correlation engine. Cross correlation engines are widely used in spread spectrum, wireless communication systems that use digital spreading codes to divide a single communication medium into separate channels. This technology is used in many systems such as GPS, ZigBee and GSM mobile communications. The technology is renowned for its robustness and security since it is highly tolerant to signal jamming and spoofing. Digital spreading in wireless communication is also widely used in military systems and has recently been proposed for use in the medical sector for neural prostheses. A limitation of using digital spreading is that the computational demands on the cross correlation engine are normally quite high and is generally considered to be the limiting factor in designing low-power portable devices. In recent developments proposed by Tapson, it was shown that a two-neuron mutual inhibition network can be used to generate a cross correlation like function (Tapson et al., 2008). In this work, the two-neuron cross correlation engine is analysed specifically for application on a particular set of digital spreading codes called Gold codes. Based on the analysis, the neuron’s response to an input signal is optimised in favour of yielding a neural cross correlation that resembles the mathematical cross correlation more closely. The aim is to find a biologically inspired computer that is practically viable in an electrical engineering application involving a digital spread spectrum communication system

A study of synchronization of nonlinear oscillators: Application to epileptic seizures

This dissertation focuses on several problems in neuroscience from the perspective of nonlinear dynamics and stochastic processes. The first part concerns a method to visualize the idea of the power spectrum of spike trains, which has an educational value to introductory students in biophysics. The next part consists of experimental and computational work on drug-induced epileptic seizures in the rat neocortex. In the experimental part, spatiotemporal patterns of electrical activities in the rat neocortex are measured using voltage-sensitive dye imaging. Epileptic regions show well-synchronized, in-phase activity during epileptic seizures. In the computational part, a network of a Hodgkin-Huxley type neocortical neural model is constructed. Phase reduction, which is a dimension reduction technique for a stable limit cycle, is applied to the system. The results propose a possible mechanism for the initiation of the drug-induced seizure as a result of a bifurcation. In the last part, a theoretical framework is developed to obtain the statistics for the period of oscillations of a stable limit cycle under stochastic perturbation. A stochastic version of phase reduction and first passage time analysis are utilized for this purpose. The method presented here shows a good agreement with numerical results for the weak noise regime --Abstract, page iii