Predicting Spike Occurrence and Neuronal Responsiveness from LFPs in Primary Somatosensory Cortex

A Belitski; A Belitski; A Kuhn; Antonio G. Zippo; B Pesaran; C Gollub; CA Anastassiou; CA Kumar; EE Galindo-Leon; EJ Chichilnisky; EJ Hwang; FS Chance; G Foffani; G Paxinos; Gabriele E. M. Biella; Gian Carlo Caramenti; GK Pedersen; I Nauhaus; J Knowles; JD Victor; K Deb; L Bonacina; L Gabernet; M Besserve; M Denker; M Maravall; M Okun; MA Lebedev; MA Montemurro; Maurizio Valente; Miguel Maravall; MJ Rasch; MN Geffen; MN Shadlen; NK Logothetis; P Delmas; P Fries; R Saravanan; R Saravanan; Riccardo Storchi; RJ Douglas; RS Johansson; RS Petersen; RT Canolty; S Lefort; S Luccioli; S Panzeri; TP Zanos; U Mitzdorf; Y Jin; Y Nir

Predicting Spike Occurrence and Neuronal Responsiveness from LFPs in Primary Somatosensory Cortex

Abstract

Local Field Potentials (LFPs) integrate multiple neuronal events like synaptic inputs and intracellular potentials. LFP spatiotemporal features are particularly relevant in view of their applications both in research (e.g. for understanding brain rhythms, inter-areal neural communication and neronal coding) and in the clinics (e.g. for improving invasive Brain-Machine Interface devices). However the relation between LFPs and spikes is complex and not fully understood. As spikes represent the fundamental currency of neuronal communication this gap in knowledge strongly limits our comprehension of neuronal phenomena underlying LFPs. We investigated the LFP-spike relation during tactile stimulation in primary somatosensory (S-I) cortex in the rat. First we quantified how reliably LFPs and spikes code for a stimulus occurrence. Then we used the information obtained from our analyses to design a predictive model for spike occurrence based on LFP inputs. The model was endowed with a flexible meta-structure whose exact form, both in parameters and structure, was estimated by using a multi-objective optimization strategy. Our method provided a set of nonlinear simple equations that maximized the match between models and true neurons in terms of spike timings and Peri Stimulus Time Histograms. We found that both LFPs and spikes can code for stimulus occurrence with millisecond precision, showing, however, high variability. Spike patterns were predicted significantly above chance for 75% of the neurons analysed. Crucially, the level of prediction accuracy depended on the reliability in coding for the stimulus occurrence. The best predictions were obtained when both spikes and LFPs were highly responsive to the stimuli. Spike reliability is known to depend on neuron intrinsic properties (i.e. on channel noise) and on spontaneous local network fluctuations. Our results suggest that the latter, measured through the LFP response variability, play a dominant role