Abstract
The localization and measurement of neuronal activity magnitude at high spatial and temporal resolution are essential for mapping and better understanding neuronal systems and mechanisms. One such example is the generation of retinotopic maps, which correlates localized retinal stimulation with the corresponding specific visual cortex responses. Here we evaluated and compared seven different methods for extracting and localizing cortical responses from voltage-sensitive dye imaging recordings, elicited by visual stimuli projected directly on the rat retina by a customized projection system. The performance of these methods was evaluated both qualitatively and quantitatively by means of two cluster separation metrics, namely, the (adjusted) Silhouette Index (SI) and the (adjusted) Davies-Bouldin Index (DBI). These metrics were validated using simulated data, which showed that Temporally Structured Component Analysis (TSCA) outperformed all other analysis methods for localizing cortical responses and generating high-resolution retinotopic maps. The analysis methods, as well as the use of cluster separation metrics proposed here, can facilitate future research aiming to localize specific activity at high resolution in the visual cortex or other brain areas.
Highlights
Recording activity from a large population of neurons serves as an important tool for studying numerous neural systems in general, and for exploring the basic mechanisms underlying the visual process in particular
Temporally Structured Component Analysis (TSCA) and the combined (TSCA&Generalized Linear Model (GLM)) methods significantly outperformed the other methods in extracting the response in all metrics except the Contrast-to-Noise Ratio (CNR)
In agreement with the statistical evaluation metrics, the TSCA and the combined TSCA&GLM methods achieved a significantly better clustering performance with significantly higher Silhouette Index (SI) compared to all the other methods, and a significantly lower Davies-Bouldin Index (DBI) compared with Tmax GLM and Correlation to delayed responses (Corr)
Summary
Recording activity from a large population of neurons serves as an important tool for studying numerous neural systems in general, and for exploring the basic mechanisms underlying the visual process in particular. Various techniques exist that attempt to estimate and classify the cortical responses from a noisy signal (Blumenfeld, 2010; Chemla and Chavane, 2010; Reynaud et al, 2011), each method has its own advantages and limitations. Electrophysiological studies have revealed that in mammals the localized stimulation of a specific retinal region (corresponding to specific locations in the field of view) induces a localized response in V1 and that there is an orderly representation of the visual field of view in the V1, the so-called retinotopic mapping
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