Electrical and mechanical activity of the intestine

The intestine is today still an organ whose mechanisms of functions are not fully understood. The diffculty in its understanding comes from the fact that it is regulated by a complex network of signals of different natures. Granting that a multitude of experimental techniques have brought precious information on the electrophysiological processes associated to the intrisic activity of the intestin, there is still shadow covering over the boundary of knowledge. With a view to sharpening the study of the complex spatio-temporal dynamics of the intrinsic electrical and mechanical activity of the intestine, three different numerical models of intestinal tissue were developed. Of particular interest are the networks of coupled oscillators, exhibiting a mass behavior with marked analogy to the intestinal tissue. The conception of these models were conducted by the handling of effective numerical methods and evaluation of numerical instability and errors. A simplified geometrical model of human colon was also developed, so as to allow a realistic visualization of the simulated results. Experimental measures in vitro and in vivo of an animal model, namely the pig, endorsed us the recordings of intrinsic electrical and mechanical activity of different intestinal segments. The recordings of the mechanical activity were obtained by three different tools: visual inspection, manometry, and Magnet Tracking. The first method implies the use of image processing for the evaluation of intestinal movement. The second one provides local pressure measurements. Only the third method enables noninvasive measurements along the digestive tube. In order to automate the extraction of valuable information contained in the signals recorded by the last method, an approch was proposed based on morphological filtering. These three methods of measure were also used in a parallel study to evaluate the electrical stimulation of the colon, with a goal to find an alternative solution to clasical treatments of chronic constipation. We showed that it is possible to induce local contraction in the cecum with electrical stimulation generated by an implantable device. Computer models guarantee at any time the realization of reproducible simulations of technically dicult, and even impossible, experiments. They compel, nonetheless, a simplification of the physiological reality. So as to validate the computer models, the result of simulations must be treated by particular methods. Electrograms and signals representing the mass movement were computed and faced to observations and real measurements. Simulated electrograms revealed a similarity to those recorded on animal intestines. Numerous resemblances are likewise observable between simulated signals of mass movement and the recordings of Magnet Tracking.

Phenomenological and physiological approaches in the study of cardiac alternans: Theoretical background, mathematical modeling and numerical simulations

Marie Dupraz

This project presents the theoretical background in electrophysiology that is used as a basis in the development of numerical methods for the simulation of heart’s electrical activity. We discuss the mathematical models currently used in cardiac electrophysiology research to simulate the propagation of an action potential wave, and then focus on the description of the ionic currents. This study allows us to anticipate the numerical model sensitivity with regard to the discretization, with the aim of recovering the physiological behaviors of the tissue (i.e. conduction velocity, electrical restitution, etc). Thereafter, we introduce the pseudo-ECG signal reconstruction method from the action potential map. This leads us to examine the approximation of such a signal using the finite element basis coming from the discretization of the monodomain equations. We discuss then a particular cardiac rhythm disorder: action potential alternans. In a second step, we perform an extended simulation study in order to validate the previous numerical methods. We carefully check the convergence of the conduction velocity with respect to the mesh size, and we bring out the advantage of phenomenological approach in terms of electrical restitutions and computational cost. We reproduce typical rhythm disorders and show that the pseudo-ECG signal is able to detect them. Finally, we discuss the influence of anisotropy in cardiac wave propagation and alternans development, characterizing the effect of fibers direction and pacing site in the resulting spatio-temporal distribution.

2013

Connecting Artificial Brains to Robots in a Comprehensive Simulation Framework: The Neurorobotics Platform

Ugo Albanese, Alessandro Ambrosano, Nino Cauli, Oliver Denninger, Stefan Deser, Egidio Falotico, Marc-Oliver Gewaltig, Luc Guyot, Georg Hinkel, Murat Kirtay, Paul Levi, Patrick Maier, Daniel Peppicelli, Igor Peric, Eduardo Ros, Stefan Ulbrich, Patrick Van Der Smagt, Lorenzo Vannucci, Axel von Arnim, Sandro Weber

Combined efforts in the fields of neuroscience, computer science, and biology allowed to design biologically realistic models of the brain based on spiking neural networks. For a proper validation of these models, an embodiment in a dynamic and rich sensory environment, where the model is exposed to a realistic sensory-motor task, is needed. Due to the complexity of these brain models that, at the current stage, cannot deal with real-time constraints, it is not possible to embed them into a real-world task. Rather, the embodiment has to be simulated as well. While adequate tools exist to simulate either complex neural networks or robots and their environments, there is so far no tool that allows to easily establish a communication between brain and body models. The Neurorobotics Platform is a new web-based environment that aims to fill this gap by offering scientists and technology developers a software infrastructure allowing them to connect brain models to detailed simulations of robot bodies and environments and to use the resulting neurorobotic systems for in silico experimentation. In order to simplify the workflow and reduce the level of the required programming skills, the platform provides editors for the specification of experimental sequences and conditions, environments, robots, and brain-body connectors. In addition to that, a variety of existing robots and environments are provided. This work presents the architecture of the first release of the Neurorobotics Platform developed in subproject 10 "Neurorobotics" of the Human Brain Project (HBP). 1 At the current state, the Neurorobotics Platform allows researchers to design and run basic experiments in neurorobotics using simulated robots and simulated environments linked to simplified versions of brain models. We illustrate the capabilities of the platform with three example experiments: a Braitenberg task implemented on a mobile robot, a sensory-motor learning task based on a robotic controller, and a visual tracking embedding a retina model on the iCub humanoid robot. These use-cases allow to assess the applicability of the Neurorobotics Platform for robotic tasks as well as in neuroscientific experiments.

2017

Experimental and Computational Study on Motor Control and Recovery After Stroke: Toward a Constructive Loop Between Experimental and Virtual Embodied Neuroscience

Emmanouil Angelidis, Alain Destexhe, Egidio Falotico, Emanuele Formento, Marc-Oliver Gewaltig, Auke Ijspeert, Silvestro Micera, Maria Pasquini, Shravan Tata Ramalingasetty, Lorenzo Vannucci, Axel von Arnim

Being able to replicate real experiments with computational simulations is a unique opportunity to refine and validate models with experimental data and redesign the experiments based on simulations. However, since it is technically demanding to model all components of an experiment, traditional approaches to modeling reduce the experimental setups as much as possible. In this study, our goal is to replicate all the relevant features of an experiment on motor control and motor rehabilitation after stroke. To this aim, we propose an approach that allows continuous integration of new experimental data into a computational modeling framework. First, results show that we could reproduce experimental object displacement with high accuracy via the simulated embodiment in the virtual world by feeding a spinal cord model with experimental registration of the cortical activity. Second, by using computational models of multiple granularities, our preliminary results show the possibility of simulating several features of the brain after stroke, from the local alteration in neuronal activity to long-range connectivity remodeling. Finally, strategies are proposed to merge the two pipelines. We further suggest that additional models could be integrated into the framework thanks to the versatility of the proposed approach, thus allowing many researchers to achieve continuously improved experimental design.

FRONTIERS MEDIA SA2020

Connecting Artificial Brains to Robots in a Comprehensive Simulation Framework: The Neurorobotics Platform

2017