Abstract
Spiking information of individual neurons is essential for functional and behavioral analysis in neuroscience research. Calcium imaging techniques are generally employed to obtain activities of neuronal populations. However, these techniques result in slowly-varying fluorescence signals with low temporal resolution. Estimating the temporal positions of the neuronal action potentials from these signals is a challenging problem. In the literature, several generative model-based and data-driven algorithms have been studied with varied levels of success. This article proposes a neural network-based signal-to-signal conversion approach, where it takes as input raw-fluorescence signal and learns to estimate the spike information in an end-to-end fashion. Theoretically, the proposed approach formulates the spike estimation as a single channel source separation problem with unknown mixing conditions. The source corresponding to the action potentials at a lower resolution is estimated at the output. Experimental studies on the spikefinder challenge dataset show that the proposed signal-to-signal conversion approach significantly outperforms state-of-the-art-methods in terms of Pearson’s correlation coefficient, Spearman’s rank correlation coefficient and yields comparable performance for the area under the receiver operating characteristics measure. We also show that the resulting system: (a) has low complexity with respect to existing supervised approaches and is reproducible; (b) is layer-wise interpretable, and (c) has the capability to generalize across different calcium indicators.
Highlights
Analyzing the brain’s responses to several types of stimuli enables an understanding of brain behavior and cognition
Approaches capable of obtaining the spike positions from the calcium fluorescence signals are of utmost interest to computational neuroscience community
The hidden layers were implemented in a time-distributed manner, i.e., the output of the first convolution layer for every segment of the calcium fluorescence signal was independently processed by the hidden layer (s) and synthesized by the output convolution layer
Summary
Analyzing the brain’s responses to several types of stimuli enables an understanding of brain behavior and cognition. The responses of the neurons manifest as a spike train, which encodes the information present in the stimulus. State-of-the-art scanning methods track the activity of a population of neurons by using fluorescence emitting capability of calcium indicator proteins/dye [1,2,3,4]. The calcium fluorescence recording of each neuron is only an indirect indicator of the actual spiking process. The presence of fluorescence level fluctuations, slow dynamics of the calcium fluorescence signal, and unknown noise-levels make it hard to identify the exact underlying spike information [5,6,7]. Approaches capable of obtaining the spike positions from the calcium fluorescence signals are of utmost interest to computational neuroscience community
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