Layer-specific Loss and Compensation of Parvocellular Response in Subcortical Pathways of Adult Human Amblyopia

Abstract

AbstractAbnormal visual experience in critical period causes amblyopia or lazy eye, reducing visual abilities even with corrected optics. A long-standing question is where in the human visual system does the amblyopic deficit arise. In particular, whether amblyopia induces selective deficits of the magnocellular (M) or the parvocellular (P) geniculostriate pathways, and whether the more ancient retinotectal pathway is also affected. Technical limitations to non-invasively measure layer-specific activity in human lateral geniculate nucleus (LGN) and superior colliculus (SC) hampered efforts in addressing these questions. In the current study, using lamina-resolved 3T and 7T fMRI and visual stimuli selectively activating the M and P pathways, we investigated layer-specific response properties of the LGN and the SC of amblyopia patients and normal controls. With stimuli presented to the amblyopic eye, there was a stronger response loss in the P layers than in the M layers of the LGN. Compared to normal controls, amblyopic eye’s response to the P stimulus was selectively reduced in the superficial SC, while the fellow eye’s response was robustly increased in the deep SC. Selective P response deficits of amblyopia were also observed in the visual pulvinar, early visual cortex, and ventral but not dorsal visual streams. These results provide strong in vivo evidence in adult amblyopic patients for selective deficits of parvocellular functions in the visual thalamus, and additionally reveal response deficits to the amblyopic eye and neural compensation to the fellow eye in the retinotectal pathway.HighlightsParvocellular response loss in the LGN P layers, visual pulvinar and ventral visual streamSelective amblyopic deficits of the parvocellular pathwayAmblyopic eye’s response decreased in the superficial SCFellow eye’s response increased in the deep SCAmblyopic deficits and neural compensation in the retinotectal pathway