Communications Biology (Mar 2024)

High-density cortical µECoG arrays concurrently track spreading depolarizations and long-term evolution of stroke in awake rats

  • Kay Palopoli-Trojani,
  • Michael Trumpis,
  • Chia-Han Chiang,
  • Charles Wang,
  • Ashley J. Williams,
  • Cody L. Evans,
  • Dennis A. Turner,
  • Jonathan Viventi,
  • Ulrike Hoffmann

DOI
https://doi.org/10.1038/s42003-024-05932-0
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 15

Abstract

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Abstract Spreading depolarizations (SDs) are widely recognized as a major contributor to the progression of tissue damage from ischemic stroke even if blood flow can be restored. They are characterized by negative intracortical waveforms of up to -20 mV, propagation velocities of 3 - 6 mm/min, and massive disturbance of membrane ion homeostasis. High-density, micro-electrocorticographic (μECoG) epidural electrodes and custom, DC-coupled, multiplexed amplifiers, were used to continuously characterize and monitor SD and µECoG cortical signal evolution in awake, moving rats over days. This highly innovative approach can define these events over a large brain surface area (~ 3.4 × 3.4 mm), extending across the boundaries of the stroke, and offers sufficient electrode density (60 contacts total per array for a density of 5.7 electrodes / mm2) to measure and determine the origin of SDs in relation to the infarct boundaries. In addition, spontaneous ECoG activity can simultaneously be detected to further define cortical infarct regions. This technology allows us to understand dynamic stroke evolution and provides immediate cortical functional activity over days. Further translational development of this approach may facilitate improved treatment options for acute stroke patients.