Perceptual Learning of Contrast Detection in the Human Lateral Geniculate Nucleus

• Published in: Current biology Vol. 26; no. 23; pp. 3176 - 3182
• Main Authors: Yu, Qinlin, Zhang, Peng, Qiu, Jiang, Fang, Fang
• Format: Journal Article
• Language: English
• Published: England Elsevier Ltd 05.12.2016
• Subjects: contrast; fMRI; Geniculate Bodies - physiology; Humans; lateral geniculate nucleus; Learning - physiology; LGN; Magnetic Resonance Imaging; perceptual learning; psychophysics; Visual Perception - physiology; fMRI; LGN; perceptual learning; psychophysics; lateral geniculate nucleus; contrast
• ISSN: 0960-9822; 1879-0445; 1879-0445
• DOI: 10.1016/j.cub.2016.09.034

The brain is continuously modified by perceptual experience throughout life. Perceptual learning, which refers to the long-term performance improvement resulting from practice, has been widely used as a paradigm to study experience-dependent brain plasticity in adults [1, 2]. In the visual system, adult plasticity is largely believed to be restricted to the cortex, with subcortical structures losing their capacity for change after a critical period of development [3, 4]. Although various cortical mechanisms have been shown to mediate visual perceptual learning [5–12], there has been no reported investigation of perceptual learning in subcortical nuclei. Here, human subjects were trained on a contrast detection task for 30 days, leading to a significant contrast sensitivity improvement that was specific to the trained eye and the trained visual hemifield. Training also resulted in an eye- and hemifield-specific fMRI signal increase to low-contrast patterns in the magnocellular layers of the lateral geniculate nucleus (LGN), even when subjects did not pay attention to the patterns. Such an increase was absent in the parvocellular layers of the LGN and visual cortical areas. Furthermore, the behavioral benefit significantly correlated with the neural enhancement. These findings suggest that LGN signals can be amplified by training to detect faint patterns. Neural plasticity induced by perceptual learning in human adults might not be confined to the cortical level but might occur as early as at the thalamic level. •Contrast learning shows specificity to the trained eye and visual hemifield•Contrast learning boosts the activity of the M layers of the LGN•Perceptual learning in human adults can occur as early as at the thalamic level Yu et al. reveal that perceptual learning of contrast detection leads to an eye- and hemifield-specific neural response increase to low contrast in the M layers of the LGN and suggest that visual training can induce plasticity in subcortical nuclei.