Frontiers in Neuroscience (Apr 2020)

Neural Basis of Extremely High Temporal Sensitivity: Insights From a Patient With Autism

  • Masakazu Ide,
  • Takeshi Atsumi,
  • Takeshi Atsumi,
  • Takeshi Atsumi,
  • Mrinmoy Chakrabarty,
  • Mrinmoy Chakrabarty,
  • Ayako Yaguchi,
  • Ayako Yaguchi,
  • Ayako Yaguchi,
  • Yumi Umesawa,
  • Yumi Umesawa,
  • Reiko Fukatsu,
  • Makoto Wada

DOI
https://doi.org/10.3389/fnins.2020.00340
Journal volume & issue
Vol. 14

Abstract

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The human brain is sensitive to incoming sensory information across multiple time scales. Temporal scales of information represented in the brain generally constrain behavior. Despite reports of the neural correlates of millisecond timing, how the human brain processes sensory stimuli in the sub-second range (≤100 ms) and its behavioral implications are areas of active scientific inquiry. An autism spectrum disorder (ASD) patient showed a tactile discrimination threshold of 6.49 ms on a temporal order judgment (TOJ) task which was approximately 10-fold superior than other ASD and healthy controls (59 and 69 ms, respectively). To investigate the brain regions of this extremely high temporal resolution in the patient, we used functional magnetic resonance imaging (fMRI) during TOJ. We observed greater activity notably in the left superior temporal gyrus (STG) and precentral gyrus (PrG) compared to that of controls. Generally, the left superior frontal gyrus (SFG) correlated positively, while the opercular part of right inferior frontal gyrus (IFG) correlated negatively, with the correct TOJ rate across all subjects (the patient + 22 healthy controls). We found that the performance was negatively correlated with the strength of neural responses in the right IFG overall in 30 participants (the patient + 22 healthy and 7 ASD controls). Our data reveal superior ability of this particular case of ASD in the millisecond scale for sensory inputs. We highlight several neural correlates of TOJ underlying the facilitation and/or inhibition of temporal resolution in humans.

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