Temporal coupling between stimulus-evoked neural activity and hemodynamic responses from individual cortical columns

Michael Bruyns-Haylett, Ying Zheng, Jason Berwick, Myles Jones

Research output: Indexed journal article Articlepeer-review

10 Citations (Scopus)

Abstract

Using previously published data from the whisker barrel cortex of anesthetized rodents (Berwick et al 2008 J. Neurophysiol. 99 787-98) we investigated whether highly spatially localized stimulus-evoked cortical hemodynamics responses displayed a linear time-invariant (LTI) relationship with neural activity. Presentation of stimuli to individual whiskers of 2 s and 16 s durations produced hemodynamics and neural activity spatially localized to individual cortical columns. Two-dimensional optical imaging spectroscopy (2D-OIS) measured hemoglobin responses, while multi-laminar electrophysiology recorded neural activity. Hemoglobin responses to 2 s stimuli were deconvolved with underlying evoked neural activity to estimate impulse response functions which were then convolved with neural activity evoked by 16 s stimuli to generate predictions of hemodynamic responses. An LTI system more adequately described the temporal neuro-hemodynamics coupling relationship for these spatially localized sensory stimuli than in previous studies that activated the entire whisker cortex. An inability to predict the magnitude of an initial 'peak' in the total and oxy- hemoglobin responses was alleviated when excluding responses influenced by overlying arterial components. However, this did not improve estimation of the hemodynamic responses return to baseline post-stimulus cessation.

Original languageEnglish
Pages (from-to)2203-2219
Number of pages17
JournalPhysics in Medicine and Biology
Volume55
Issue number8
DOIs
Publication statusPublished - 21 Apr 2010
Externally publishedYes

Keywords

  • Rat somatosensory cortex
  • Source-density analysis
  • Rodent barrel cortex
  • Cerebral-blood-flow
  • Oxygen-metabolism
  • Brain activation
  • Functional mri
  • Visual-cortex
  • Balloon model
  • Bold response

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