Title :
Predicting Spike Activity in Neuronal Cultures
Author :
Gurel, T. ; Egert, Ulrich ; Kandler, Steffen ; Raedt, Luc De ; Rotter, Stefan
Abstract :
Neuronal cultures are small living networks in a closed system. This paper investigates the question whether it is possible to discover the functional connectivity and to model the dynamics of such neuronal cultures. Doing so may contribute to a better understanding of neural information processing. We employ a machine learning approach, which constructs the functional connectivity map of a neuronal culture based on multiple spike trains of its spontaneous activity recorded with Multi-Electrode-Array (MEA) technology. The spike train of an electrode is modeled as a point process, where the firing probability depends on the finite spike history of all electrodes. To capture potential plasticity of the network, we employ a gradient descent method, which naturally allows for online learning. Several experiments with different cultures show that learned models can predict upcoming spike activity quite well.
Keywords :
bioelectric phenomena; brain; gradient methods; learning (artificial intelligence); medical signal processing; neurophysiology; probability; firing probability; functional connectivity map; gradient descent method; machine learning approach; multielectrode-array technology; neural information processing; neuronal cultures; online learning; small living network; spike activity prediction; Anatomical structure; Biological neural networks; Biological system modeling; Displays; Electrodes; Extracellular; Information processing; Machine learning algorithms; Neurons; Predictive models;
Conference_Titel :
Neural Networks, 2007. IJCNN 2007. International Joint Conference on
Conference_Location :
Orlando, FL
Print_ISBN :
978-1-4244-1379-9
Electronic_ISBN :
1098-7576
DOI :
10.1109/IJCNN.2007.4371428
