Review Paper
Mapping the primate lateral geniculate nucleus: A review of experiments and methods

https://doi.org/10.1016/j.jphysparis.2013.10.001Get rights and content
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Highlights

  • We review neuronal response mapping studies of the primate LGN.

  • There is a need for further study of the LGN using natural stimuli.

  • Little is known about the extra-classical receptive field in the LGN.

  • Contemporary technology will allow high resolution mapping of LGN receptive fields.

Abstract

Mapping neuronal responses in the lateral geniculate nucleus (LGN) is key to understanding how visual information is processed in the brain. This paper focuses on our current knowledge of the dynamics the receptive field (RF) as broken down into the classical receptive field (CRF) and the extra-classical receptive field (ECRF) in primate LGN. CRFs in the LGN are known to be similar to those in the retinal ganglion cell layer in terms of both spatial and temporal characteristics, leading to the standard interpretation of the LGN as a relay center from retina to primary visual cortex. ECRFs have generally been found to be large and inhibitory, with some differences in magnitude between the magno-, parvo-, and koniocellular pathways. The specific contributions of the retina, thalamus, and visual cortex to LGN ECRF properties are presently unknown. Some reports suggest a retinal origin for extra-classical suppression based on latency arguments and other reports have suggested a thalamic origin for extra-classical suppression. This issue is complicated by the use of anesthetized animals, where cortical activity is likely to be altered. Thus further study of LGN ECRFs is warranted to reconcile these discrepancies. Producing descriptions of RF properties of LGN neurons could be enhanced by employing preferred naturalistic stimuli. Although there has been significant work in cats with natural scene stimuli and noise that statistically imitates natural scenes, we highlight a need for similar data from primates. Obtaining these data may be aided by recent advancements in experimental and analytical techniques that permit the efficient study of nonlinear RF characteristics in addition to traditional linear factors. In light of the reviewed topics, we conclude by suggesting experiments to more clearly elucidate the spatial and temporal structure of ECRFs of primate LGN neurons.

Abbreviations

CRF
classical receptive field
EC
extra-classical
ECI
extra-classical inhibition
ECRF
extra-classical receptive field
K
koniocellular
LGN
lateral geniculate nucleus
M
magnocellular
MID
Maximally Informative Dimensions
P
Parvocellular
RF
receptive field
RGC
retinal ganglion cell
STA
spike-triggered average
STC
spike-triggered covariance
V1
primary visual cortex

Keywords

LGN
Thalamus
Reverse correlation
Early visual system
Extra-classical receptive field

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1

These authors contributed equally to this work.