%0 Journal Article %A Madineh Sedigh-Sarvestani %A Leif Vigeland %A Ivan Fernandez-Lamo %A Morgan Taylor %A Larry A. Palmer %A Diego Contreras %T Intracellular, in vivo, dynamics of thalamocortical synapses in visual cortex. %D 2017 %R 10.1523/JNEUROSCI.3370-16.2017 %J The Journal of Neuroscience %P 3370-16 %X Seminal studies of the thalamocortical (TC) circuit in the visual system of the cat have been central to our understanding of sensory encoding. However, TC synaptic properties remain poorly understood. We used paired recordings, in the lateral geniculate nucleus (LGN) and primary visual cortex (V1), to provide the first in vivo characterization of sensory-driven TC potentials in V1. The amplitudes of EPSPs we characterized were smaller than those previously reported in vitro. Consistent with prior findings, connected LGN-V1 pairs were only found when their receptive fields (RFs) overlapped, and the probability of connection increased steeply with degree of RF overlap and response similarity. However, surprisingly, we found no relationship between EPSP amplitudes and the similarity of RFs or responses, suggesting different connectivity models for intracortical and thalamocortical circuits. Putative excitatory regular-spiking (RS) and inhibitory fast-spiking (FS) V1 cells had similar EPSP characteristics, showing that in the visual system, feedforward excitation and inhibition are driven with equal strength by the thalamus. Similar to observations in the somatosensory cortex, FS V1 cells received less specific input from LGN. Finally, orientation tuning in V1 was not inherited from single pre-synaptic LGN cells, and must therefore emerge exclusively from the combined input of all pre-synaptic LGN cells. Our results help to decipher early visual encoding circuits and have immediate utility in providing physiological constraints to computational models of the visual system.Significance Statement:In order to understand how the brain encodes the visual environment, we must understand the transfer of visual signals between various regions of the brain. Therefor, understanding synaptic dynamics is critical to our understanding of sensory encoding. This study provides the first characterization of visually evoked synaptic potentials between the visual thalamus and visual cortex in an intact animal. To record these potentials, we simultaneously recorded the extracellular potential of pre-synaptic thalamic cells and the intracellular potential of post-synaptic cortical cells in input layers of primary visual cortex. Our characterization of synaptic potentials in vivo disagreed with prior findings in vitro. This study will increase our understanding of thalamocortical circuits and will improve computational models of visual encoding. %U https://www.jneurosci.org/content/jneuro/early/2017/05/02/JNEUROSCI.3370-16.2017.full.pdf