Abstract
To perceive self-motion perception, the brain needs to integrate multi-modal sensory signals such as visual, vestibular and proprioceptive cues. Self-motion perception is very complex and involves multi candidate areas. Previous studies related to self-motion perception during passive motion have revealed that some of the areas show selective response to different directions for both visual (optic flow) and vestibular stimuli, such as the dorsal subdivision of the medial superior temporal area (MSTd) and the visual posterior sylvian fissure (VPS), although MSTd is dominated by visual signals and VPS is dominated by vestibular signals. However, none of studies related to self-motion perception have distinguished the different neuron types with distinct neuronal properties in cortical microcircuitry, which limited our understanding of the local circuits for self-motion perception. In the current study, we classified the recorded MSTd and VPS neurons into putative pyramidal neurons and putative interneurons based on the extracellular action potential waveforms and spontaneous firing rates. We found that: (1) the putative interneurons exhibited obviously broader direction tuning than putative pyramidal neurons in response to their dominant (visual for MSTd; vestibular for VPS) stimulation type; (2) either in visual or vestibular condition, the putative interneurons were more responsive but with larger variability than the putative pyramidal neurons for both MSTd and VPS areas; and (3) the timing of vestibular and visual peak directional tuning was earlier in the putative interneurons than that of the putative pyramidal neurons for both MSTd and VPS areas. Based on these findings we speculated that, within the microcircuitry, several adjacent putative interneurons with broad direction tuning receive earlier strong but variable signals, which might act feedforward input to shape the direction tuning of the target putative pyramidal neuron, but each interneuron may participate in several microcircuitries, targeting different output neurons.
Highlights
In everyday life, perception of self-motion is essential for navigation, spatial orientation and motor control
Physiological studies have proved that many neurons in several cortical areas, including dorsal subdivision of the medial superior temporal (MSTd) area (Britten and van Wezel, 1998, 2002; Duffy, 1998; Bremmer et al, 1999; Gu et al, 2006; Britten, 2008; Fetsch et al, 2010; Angelaki et al, 2011) and visual posterior sylvian fissure (VPS) area (Jones and Burton, 1976; Guldin et al, 1992; Guldin and Grüsser, 1998; Dicke et al, 2008; Chen et al, 2011a), show selectivity for heading in response to both visual and vestibular self-motion stimuli, the responses to visual and vestibular stimuli varies across different cortical areas
We recorded MSTd and VPS neurons as monkey was passively translated in physical or simulated motion along 26 motion direction uniformly distributed in 3D space (Figures 1A,B)
Summary
Perception of self-motion is essential for navigation, spatial orientation and motor control. It is vital for our living and survival. MSTd area shows visualdominant heading tuning while VPS area shows vestibulardominant heading tuning (Chen et al, 2011b). These studies have enriched our knowledge about the self-motion perception in passive motion conditions and advanced our understanding of the underlying neural mechanism
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